key: cord-0696371-g1extz63
authors: Espi, Maxime; Koppe, Laetitia; Fouque, Denis; Thaunat, Olivier
title: Chronic Kidney Disease-Associated Immune Dysfunctions: Impact of Protein-Bound Uremic Retention Solutes on Immune Cells
date: 2020-05-06
journal: Toxins (Basel)
DOI: 10.3390/toxins12050300
sha: 2044e631dce2e05881bac9fde9d9b566c8fa7ef8
doc_id: 696371
cord_uid: g1extz63

Regardless of the primary disease responsible for kidney failure, patients suffering from chronic kidney disease (CKD) have in common multiple impairments of both the innate and adaptive immune systems, the pathophysiology of which has long remained enigmatic. CKD-associated immune dysfunction includes chronic low-grade activation of monocytes and neutrophils, which induces endothelial damage and increases cardiovascular risk. Although innate immune effectors are activated during CKD, their anti-bacterial capacity is impaired, leading to increased susceptibility to extracellular bacterial infections. Finally, CKD patients are also characterized by profound alterations of cellular and humoral adaptive immune responses, which account for an increased risk for malignancies and viral infections. This review summarizes the recent emerging data that link the pathophysiology of CKD-associated immune dysfunctions with the accumulation of microbiota-derived metabolites, including indoxyl sulfate and p-cresyl sulfate, the two best characterized protein-bound uremic retention solutes.

Chronic kidney disease (CKD) is defined by abnormalities of kidney function or structure present for more than 3 months. The definition of CKD includes all individuals with markers of kidney damage or those with an estimated glomerular filtration rate (eGFR) of less than 60 mL/min/1.73 m 2 on at least two occasions 90 days apart [1] . CKD severity is classified into five stages according to the level of GFR. Patients at the last (end) stage of CKD require renal replacement therapy: either chronic hemodialysis or renal transplantation.

Affecting more than 10% of the global population in developed countries, CKD has changed from a subspecialty issue to a global health concern. All stages of CKD are indeed associated with increased Table 1 . Current classification of major uremic retention solutes. Free-water soluble low molecules and middle molecules are mainly endogenous molecules, participating in normal biologic functions. For example, urea and phosphate are considered as free-water soluble uremic toxins, because of their known toxicity on glucose homeostasis [11] and on cardiovascular system [12] . Likewise, parathyroid hormone and β2-microglobulin are two middle molecules with essential biological functions, the toxicity of which is due to their accumulation during CKD [3] .

In contrast, the third class of uremic retention solutes essentially gathers exogenous molecules, which derive from dietary intake, and bind to proteins (hence their name: protein-bound uremic retention solutes, PBURS). Only a small portion of PBURS (approximately 5% [13] ) circulate as a free fraction and may exert a biological effect [14] . Many observational studies have demonstrated the association between serum levels of PBURS and mortality/complications in CKD [15] . 

Phenols are derived from tyrosine and phenylalanine metabolism. Theses aromatic amino acids are converted into phenolic compounds (such as phenol and p-cresol) through a series of transamination, deamination, and decarboxylation reactions by bacterial fermentation in the distal part of the colon. Detoxification of phenols occurs in the mucosa of the colon and in the liver, where p-cresol is sulfated into p-cresyl sulfate (pCS) by an aryl-sulfotransferase.

Preliminary studies of the functional characteristics of intestinal microbiota of CKD patients have reported a higher prevalence of phenol-producing bacteria (Enterobacteriaceae and Enterococcaceae families) and of p-cresol-producing bacteria (including Clostridium perfringens). As for tryptophan catabolites, accumulation of pCS during CKD results not only from the dysbiosis [34] but also from decreased renal elimination [35] . The free fraction of pCS is two to five fold higher in CKD patients stage three to five [13] .

In contrast with IS, the biological effects of pCS cannot be explained by a unique molecular pathway. For instance, pCS impairs insulin signaling through activation of kinases (ERK1/2) in muscular skeletal cells [36] , while in tubular epithelial cells [37, 38] and leukocytes [39] pCS activates the nicotinamide adenine dinucleotide phosphate (NADPH) oxidase, leading to local reactive oxygen species (ROS) production.

Over the past decades, clinical and experimental data have linked the accumulation of PBURS, and most notably pCS and IS, with the pathophysiology of CKD-associated complications [15, 40] , including vascular calcification and atherosclerosis [41] [42] [43] , anemia [44] , insulin-resistance [36] , and mineral-bone disorders [45] . Whether IS and pCS are also involved in CKD-associated immune dysfunctions is less well established, but accumulating evidence, systematically reviewed below, supports this theory.

Of note, although the highest serum PBURS levels are found in patients on hemodialysis, the present review will focus on studies dealing with previous stages of CKD. Indeed, it is well known that hemodialysis therapy itself, through the mechanical stimulation from blood pumping, the pollution of dialysate by bacterial metabolites [such as endotoxin or lipopolysaccharide (LPS)), and the limited biocompatibility of the dialysis membrane, can perturbate the immune system independently from PBURS [46] . 

Over the past decades, clinical and experimental data have linked the accumulation of PBURS, and most notably pCS and IS, with the pathophysiology of CKD-associated complications [15, 40] , including vascular calcification and atherosclerosis [41] [42] [43] , anemia [44] , insulin-resistance [36] , and mineral-bone disorders [45] . Whether IS and pCS are also involved in CKD-associated immune dysfunctions is less well established, but accumulating evidence, systematically reviewed below, supports this theory.

Of note, although the highest serum PBURS levels are found in patients on hemodialysis, the present review will focus on studies dealing with previous stages of CKD. Indeed, it is well known that hemodialysis therapy itself, through the mechanical stimulation from blood pumping, the pollution of dialysate by bacterial metabolites [such as endotoxin or lipopolysaccharide (LPS)), and the limited biocompatibility of the dialysis membrane, can perturbate the immune system independently from PBURS [46] .

The innate immune system, which forms the most ancestral and first line of defense of the organism, consists of different cell subsets and the soluble proteins of the complement system. The innate immune system provides an immediate (although non-specific) response to pathogens [47] . Innate effectors, including neutrophils and monocytes, are classically activated via pattern recognition receptors (including toll-like receptors, TLRs), which bind molecular motives broadly shared by pathogens and endogenous molecules released following cell stress/injury. Activation of innate immune cells leads to the release of pro-inflammatory cytokines, which have an important protective role but can turn deleterious in cases of chronic exposure [48] .

CKD is characterized by a remarkable increase in pro-inflammatory cytokine levels, in particular tumor necrosis factor α (TNFα) and interleukin 6 (IL-6) [49, 50] , which are inversely correlated with the decline in GFR [51, 52] . Neutrophils and monocytes from CKD patients display an exaggerated response Toxins 2020, 12, 300 5 of 16 to stimulation with lipopolysaccharide (LPS) [53] , which could be due to the fact that the uremic environment induces an increased expression of TLR2 and 4 [49, 54, 55] . The permanent activation of monocytes during CKD could also be the direct consequence of PBURS. IS indeed activates the aryl hydrocarbon receptor [56] of monocytes, thereby promoting the generation of pro-inflammatory cytokines [57] , which in turn provokes endothelial damage [58] and increases the risk of cardiovascular complications [59] . This problem is worsened by an amplification loop due to the direct effects of PBURS on endothelial cells. Several studies have indeed documented that pCS impairs vascular remodeling and induce vascular contraction [60] , while IS alters endothelial cell functions [61] [62] [63] . In particular, the uremic milieu alters the ability of endothelial cells to control the alternative complement pathways, which in turn amplifies the endothelial injuries [64] . In line with these data, decreasing IS rate with adsorbent carbon particles has been proven efficient to reduce the levels of endothelial dysfunction markers [65] .

Finally, the demonstration of the involvement of PBURS in triggering the deleterious crosstalk between endothelial cells and innate immune effectors during CKD has been provided by experimental data showing that the mere administration of IS or pCS in rats induced leukocytes adhesion and extravasation, leading to interrupted blood flow [66] .

Constant activation of the innate immune effectors during CKD does not imply that patients are better protected against pathogens. Instead, CKD is characterized by a dramatic increase in the incidence and the severity of infectious episodes [7] ; the risk of death from infectious disease of CKD patients is indeed estimated 10 to 1000 fold higher than that of healthy age-matched controls [6, 8] .

The first line of defense against extracellular bacteria is provided by neutrophils, which are the most abundant type of white blood cells in mammals. Neutrophils provide protection by migrating fast (within minutes) to the site of infection, and by attacking micro-organisms through phagocytosis (ingestion and destruction of bacteria). Although uremic milieu has been shown to trigger apoptosis of neutrophils in culture [67] , there is no clear evidence that the number of neutrophils is reduced in CKD patients [68, 69] . In contrast, there is a wide consensus that the neutrophils of CKD patients display defective functions. First, some reports indicate that certain uremic toxins can inhibit neutrophils chemotaxis [70, 71] . Second, there is a wide consensus that phagocytic functions are defective in the neutrophils of CKD patients [67, 72] . The fact that: (i) in vitro phagocytic capacities of neutrophils from CKD patients were improved when the cells were cultured in a non-uremic medium, and that (ii) conversely, the phagocytic capacities of neutrophils from healthy patients were altered when the cells were cultured in an uremic milieu, suggests that uremic toxins are directly responsible for the problem ( Table 2) .

A central role in the destruction of ingested bacteria by neutrophils is played by the nicotinamide adenine dinucleotide phosphate (NADPH) oxidase, an enzyme that converts oxygen to superoxide free radicals. Many uremic retention solutes are able to inhibit NADPH oxidase activity [73, 74] , including IS [73] and pCS [73, 75] . The molecular mechanism by which these uremic toxins impair the NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] .

If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. Table 2 . Impact of CKD, and PBURS on immune cell functions.

Indoxyl Sulfate Innate Immune Cells Neutrophils ↗ response to stimulation [53] ↗ expression of TLR 2 and 4 [49, 54] ↗ apoptosis [67] ↘ phagocytic functions [72, 76, 77] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] [74] [75] ↘ phagocytic functions [39] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] Monocytes and macrophages ↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] Adaptive immune cells Naïve T cells ↗ apoptosis [88] ↘ number [89] [90] [91] ↘ thymic output [90] Unknown Unknown 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic response to stimulation [53] Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. Table 2 . Impact of CKD, and PBURS on immune cell functions.

Indoxyl Sulfate Innate Immune Cells Neutrophils ↗ response to stimulation [53] ↗ expression of TLR 2 and 4 [49, 54] ↗ apoptosis [67] ↘ phagocytic functions [72, 76, 77] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] [74] [75] ↘ phagocytic functions [39] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] Monocytes and macrophages ↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] Adaptive immune cells Naïve T cells ↗ apoptosis [88] ↘ number [89] [90] [91] ↘ thymic output [90] Unknown Unknown 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic expression of TLR 2 and 4 [49, 54] Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. Table 2 . Impact of CKD, and PBURS on immune cell functions.

Indoxyl Sulfate Innate Immune Cells Neutrophils ↗ response to stimulation [53] ↗ expression of TLR 2 and 4 [49, 54] ↗ apoptosis [67] ↘ phagocytic functions [72, 76, 77] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] [74] [75] ↘ phagocytic functions [39] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] Monocytes and macrophages ↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] Adaptive immune cells Naïve T cells ↗ apoptosis [88] ↘ number [89] [90] [91] ↘ thymic output [90] Unknown Unknown 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic apoptosis [67] Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. Table 2 . Impact of CKD, and PBURS on immune cell functions.

Indoxyl Sulfate Innate Immune Cells Neutrophils ↗ response to stimulation [53] ↗ expression of TLR 2 and 4 [49, 54] ↗ apoptosis [67] ↘ phagocytic functions [72, 76, 77] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] [74] [75] ↘ phagocytic functions [39] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] Monocytes and macrophages ↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] Adaptive immune cells Naïve T cells ↗ apoptosis [88] ↘ number [89] [90] [91] ↘ thymic output [90] Unknown Unknown 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic phagocytic functions [72, 76, 77] Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. Table 2 . Impact of CKD, and PBURS on immune cell functions.

Indoxyl Sulfate Innate Immune Cells Neutrophils ↗ response to stimulation [53] ↗ expression of TLR 2 and 4 [49, 54] ↗ apoptosis [67] ↘ phagocytic functions [72, 76, 77] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] [74] [75] ↘ phagocytic functions [39] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] Monocytes and macrophages ↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] Adaptive immune cells Naïve T cells ↗ apoptosis [88] ↘ number [89] [90] [91] ↘ thymic output [90] Unknown Unknown 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic adhesion to endothelial cells and extravasation [66] Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. Table 2 . Impact of CKD, and PBURS on immune cell functions.

Indoxyl Sulfate Innate Immune Cells Neutrophils ↗ response to stimulation [53] ↗ expression of TLR 2 and 4 [49, 54] ↗ apoptosis [67] ↘ phagocytic functions [72, 76, 77] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] [74] [75] ↘ phagocytic functions [39] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] Monocytes and macrophages ↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] Adaptive immune cells Naïve T cells ↗ apoptosis [88] ↘ number [89] [90] [91] ↘ thymic output [90] Unknown Unknown 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic NADPH oxidase activity [73] [74] [75] Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. Table 2 . Impact of CKD, and PBURS on immune cell functions.

Indoxyl Sulfate Innate Immune Cells Neutrophils ↗ response to stimulation [53] ↗ expression of TLR 2 and 4 [49, 54] ↗ apoptosis [67] ↘ phagocytic functions [72, 76, 77] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] [74] [75] ↘ phagocytic functions [39] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] Monocytes and macrophages ↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic phagocytic functions [39] Toxins 2020, 12, x FOR PEER REVIEW NADPH oxidase activity is not entirely clear but seems to involve an inhibition metabolism, leading to a state of depressed cell energy production [74, 76, 77] .

If the defects in neutrophils functions provide a likely explanation for the inc bacterial infectious complications observed in CKD patients, this mere mechanism can its own for many other typical features of CKD-associated immune dysfunctions. 

The first evidence that CKD is associated with a defect in adaptive T cell respon the observation made in the mid-1950s' that survival of skin homografts is prolon patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated r Given the critical role of T cells both in cancer immunosurveillance [101] and the elimin cellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell respo responsible for the increased risk for malignancies [5, 102, 103] and severe viral infecti COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two ty effector responses following exposure to an antigen: humoral (i.e., consisting of a cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive respons activation of T cells by antigen presenting cells (APC), the main type of which is dendri to be initiated [47] . An important feature of adaptive immunity is the generation of which respond more rapidly and more efficiently upon exposure to the same antigen DCs are found in reduced number in the circulation of CKD patients [80, 81] and has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patien major histocompatibility complex (MHC) class I and class II, and costimulatory mol baseline [83] , and following in vitro stimulation [104] . As expected from thes adhesion to endothelial cells and extravasation [66] Toxins 2020, 12, x FOR PEER REVIEW NADPH oxidase activity is not entirely clear but seems to involve an inhibitio metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the bacterial infectious complications observed in CKD patients, this mere mechanism c its own for many other typical features of CKD-associated immune dysfunctions. ↘ number of B cells [98] Abbreviations are; CKD: chronic kidney disease; PBURS: protein-bound uremic rete TLR: toll-like receptor; NADPH: nicotinamide adenine dinucleotide phosphate; TCR: T INF: interferon; Th1: T helper phenotype 1; ↗: increase; ↘: decrease.

The first evidence that CKD is associated with a defect in adaptive T cell resp the observation made in the mid-1950s' that survival of skin homografts is prol patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated Given the critical role of T cells both in cancer immunosurveillance [101] and the elim cellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell res responsible for the increased risk for malignancies [5, 102, 103] and severe viral infe COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two effector responses following exposure to an antigen: humoral (i.e., consisting o cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive respo activation of T cells by antigen presenting cells (APC), the main type of which is den to be initiated [47] . An important feature of adaptive immunity is the generation which respond more rapidly and more efficiently upon exposure to the same antige DCs are found in reduced number in the circulation of CKD patients [80, 81] a has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD pat major histocompatibility complex (MHC) class I and class II, and costimulatory m baseline [83] , and following in vitro stimulation [104] . As expected from t NADPH oxidase activity [73] 

Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic expression of TLR2 and 4 [49, 54] Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] Monocytes and macrophages ↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] Adaptive immune cells 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic phagocytic functions [75, 77] Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] Monocytes and macrophages ↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] Adaptive immune cells 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic phagocytic functions [78, 79] Toxins 2020, 12, x FOR PEER REVIEW NADPH oxidase activity is not entirely clear but seems to involve an inhibition metabolism, leading to a state of depressed cell energy production [74, 76, 77] .

If the defects in neutrophils functions provide a likely explanation for the in bacterial infectious complications observed in CKD patients, this mere mechanism can its own for many other typical features of CKD-associated immune dysfunctions. ↘ number of B cells [98] Abbreviations are; CKD: chronic kidney disease; PBURS: protein-bound uremic retent TLR: toll-like receptor; NADPH: nicotinamide adenine dinucleotide phosphate; TCR: T-c INF: interferon; Th1: T helper phenotype 1; ↗: increase; ↘: decrease.

The first evidence that CKD is associated with a defect in adaptive T cell respo the observation made in the mid-1950s' that survival of skin homografts is prolon patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated Given the critical role of T cells both in cancer immunosurveillance [101] and the elim cellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell resp responsible for the increased risk for malignancies [5, 102, 103] and severe viral infect COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two t effector responses following exposure to an antigen: humoral (i.e., consisting of cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive respon activation of T cells by antigen presenting cells (APC), the main type of which is dend to be initiated [47] . An important feature of adaptive immunity is the generation o which respond more rapidly and more efficiently upon exposure to the same antigen DCs are found in reduced number in the circulation of CKD patients [80, 81] an has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patie major histocompatibility complex (MHC) class I and class II, and costimulatory mo baseline [83] , and following in vitro stimulation [104] . As expected from the secretion of pro-inflammatory cytokines [57, 58] 

Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic number [80] [81] [82] Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic expression of costimulatory molecules [83, 84] Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic capacity to activate T cells [83, 85] Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic phagocytic function and presentation of antigen [78, 79] Toxins 2020, 12, x FOR PEER REVIEW NADPH oxidase activity is not entirely clear but seems to involve an inhibition metabolism, leading to a state of depressed cell energy production [74, 76, 77] .

If the defects in neutrophils functions provide a likely explanation for the i bacterial infectious complications observed in CKD patients, this mere mechanism ca its own for many other typical features of CKD-associated immune dysfunctions. ↘ number of B cells [98] Abbreviations are; CKD: chronic kidney disease; PBURS: protein-bound uremic reten TLR: toll-like receptor; NADPH: nicotinamide adenine dinucleotide phosphate; TCR: T-INF: interferon; Th1: T helper phenotype 1; ↗: increase; ↘: decrease.

The first evidence that CKD is associated with a defect in adaptive T cell respo the observation made in the mid-1950s' that survival of skin homografts is prolo patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated Given the critical role of T cells both in cancer immunosurveillance [101] and the elim cellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell res responsible for the increased risk for malignancies [5, 102, 103] and severe viral infec COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two effector responses following exposure to an antigen: humoral (i.e., consisting o cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive respo activation of T cells by antigen presenting cells (APC), the main type of which is dend to be initiated [47] . An important feature of adaptive immunity is the generation o which respond more rapidly and more efficiently upon exposure to the same antige DCs are found in reduced number in the circulation of CKD patients [80, 81] a has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD pati major histocompatibility complex (MHC) class I and class II, and costimulatory m baseline [83] , and following in vitro stimulation [104] . As expected from th proliferationand expression of costimulatory molecules [86, 87] Adaptive immune cells

Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. 

↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] Adaptive immune cells Naïve T cells ↗ apoptosis [88] ↘ number [89] [90] [91] ↘ thymic output [90] Unknown Unknown 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic apoptosis [88] Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. 

↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] Adaptive immune cells Naïve T cells ↗ apoptosis [88] ↘ number [89] [90] [91] ↘ thymic output [90] Unknown Unknown 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic number [89] [90] [91] Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. 

↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] Adaptive immune cells Naïve T cells ↗ apoptosis [88] ↘ number [89] [90] [91] ↘ thymic output [90] Unknown Unknown 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic thymic output [90] Unknown Unknown

Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. 

↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] Adaptive immune cells Naïve T cells ↗ apoptosis [88] ↘ number [89] [90] [91] ↘ thymic output [90] Unknown Unknown 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic number of terminally differentiated [92, 93] Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. 

↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] Adaptive immune cells Naïve T cells ↗ apoptosis [88] ↘ number [89] [90] [91] ↘ thymic output [90] Unknown Unknown 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic TCR repertoire diversity [94] Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. 

↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] Adaptive immune cells Naïve T cells ↗ apoptosis [88] ↘ number [89] [90] [91] ↘ thymic output [90] Unknown Unknown 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic production of INFγ (Th1 cells) [95] Unknown

Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. Table 2 . Impact of CKD, and PBURS on immune cell functions.

Indoxyl Sulfate Innate Immune Cells Neutrophils ↗ response to stimulation [53] ↗ expression of TLR 2 and 4 [49, 54] ↗ apoptosis [67] ↘ phagocytic functions [72, 76, 77] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] [74] [75] ↘ phagocytic functions [39] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] Monocytes and macrophages ↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] Adaptive immune cells Naïve T cells ↗ apoptosis [88] ↘ number [89] [90] [91] ↘ thymic output [90] Unknown Unknown 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic number of naïve and memory B cells [68, 96, 97] Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. Table 2 . Impact of CKD, and PBURS on immune cell functions.

Indoxyl Sulfate Innate Immune Cells Neutrophils ↗ response to stimulation [53] ↗ expression of TLR 2 and 4 [49, 54] ↗ apoptosis [67] ↘ phagocytic functions [72, 76, 77] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] [74] [75] ↘ phagocytic functions [39] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] Monocytes and macrophages ↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] Adaptive immune cells Naïve T cells ↗ apoptosis [88] ↘ number [89] [90] [91] ↘ thymic output [90] Unknown Unknown 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic apoptosis [68, 96, 97] by decreased prosurvival signals [68, 96, 97] Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. Table 2 . Impact of CKD, and PBURS on immune cell functions.

Indoxyl Sulfate Innate Immune Cells Neutrophils ↗ response to stimulation [53] ↗ expression of TLR 2 and 4 [49, 54] ↗ apoptosis [67] ↘ phagocytic functions [72, 76, 77] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] [74] [75] ↘ phagocytic functions [39] ↗ adhesion to endothelial cells and extravasation [66] ↘ NADPH oxidase activity [73] Monocytes and macrophages ↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. 

↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific : increase;

Toxins 2020, 12, x FOR PEER REVIEW 6 of 16 NADPH oxidase activity is not entirely clear but seems to involve an inhibition of neutrophils metabolism, leading to a state of depressed cell energy production [74, 76, 77] . If the defects in neutrophils functions provide a likely explanation for the increased risk of bacterial infectious complications observed in CKD patients, this mere mechanism cannot account on its own for many other typical features of CKD-associated immune dysfunctions. 

↗ expression of TLR2 and 4 [49, 54] ↘ phagocytic functions [75, 77] ↘ phagocytic functions [78, 79] ↗ secretion of proinflammatory cytokines [57, 58] Dendritic cells ↘ number [80] [81] [82] ↘ expression of costimulatory molecules [83, 84] ↘ capacity to activate T cells [83, 85] ↘ phagocytic function and presentation of antigen [78, 79] ↘ proliferation and expression of costimulatory molecules [86, 87] 

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intracellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), : decrease.

The first evidence that CKD is associated with a defect in adaptive T cell responses came from the observation made in the mid-1950s' that survival of skin homografts is prolonged in uremic patients [99] (rejection of skin graft, is indeed strictly dependent on T cell-mediated rejection [100] ). Given the critical role of T cells both in cancer immunosurveillance [101] and the elimination of intra-cellular pathogens (in particular viruses), CKD-induced defects in adaptive T cell responses are likely responsible for the increased risk for malignancies [5, 102, 103] and severe viral infections (including COVID-19 [9] ) observed in uremic patients.

Jawed vertebrates, have sophisticated adaptive immunity that can mount two types of specific effector responses following exposure to an antigen: humoral (i.e., consisting of antibodies), or cellular (depending on CD8+ cytotoxic T cells) [47] . Both types of adaptive responses require the activation of T cells by antigen presenting cells (APC), the main type of which is dendritic cells (DCs), to be initiated [47] . An important feature of adaptive immunity is the generation of memory cells, which respond more rapidly and more efficiently upon exposure to the same antigen [47] .

DCs are found in reduced number in the circulation of CKD patients [80, 81] and this decrease has been shown to parallel the decline in GFR [82] . Furthermore, DCs from CKD patients express less major histocompatibility complex (MHC) class I and class II, and costimulatory molecules both at baseline [83] , and following in vitro stimulation [104] . As expected from these phenotypic abnormalities, DCs from CKD patients showed reduced capacity to activate T cells in vitro [85] . The fact that: (i) DCs from CKD patients exposed to non-uremic milieu partially recover a normal phenotype [84] , and (ii) conversely DCs from healthy controls cultured in uremic milieu display a decreased expression of costimulatory molecules, suggests an important role for uremic toxins (Table 2 ). In line with this proposal, high pCS concentrations induce remarkable alteration of DCs functions, including reduced phagocytosis and antigen processing and presentation [78, 79] (Table 2 ). In vitro IS exposure also has an impact on DCs, leading to a decrease in proliferation and expression of costimulatory molecules [86] , likely through Toxins 2020, 12, 300 7 of 16 activation of AhR [87] (Table 2 ). In line with this theory is the fact that synthetic agonists of AhR have been shown to reduce DC proliferation and to promote the acquisition of a tolerogenic phenotype [105] in vitro, which translates into decreased allergic lung inflammation [106] and the prevention of rejection of pancreatic islet allografts [107] in murine models.

There are conflicting data regarding whether or not CKD induces a (moderate) reduction in the number of circulating T cells [68, 88, 108] . In contrast, it is widely accepted that CKD has a profound impact on T cell subset distribution. CKD patients are indeed characterized by a decreased number of naïve T cells [89] due to both reduced thymic output [90] and increased apoptosis [88] . In contrast, effector memory T cells remain in normal numbers in CKD patients [89] , who are also characterized by an expansion in terminally differentiated CD4+ CD28 null T cells [92, 93] (Table 2 ). These abnormalities, together with the observation that CKD patients have a less diverse T-cell receptor (TCR) repertoire than healthy controls [94] , are evocative of a compensation by an increased peripheral proliferation of memory T cells. This hypothesis has been confirmed by the demonstration that peripheral T cells of CKD patients have reduced relative telomere length [90] . Altogether these data demonstrate that CKD is associated with premature ageing of the T cell compartment [68, 91] , a process that may be induced/accelerated by uremic milieu-induced chronic-low grade inflammation (see paragraph 3 above).

Several lines of experimental evidence directly link accumulation of PBURS with defective T cell responses. First, increasing the rate of pCS in mice correlates with decreased production of IFNγ by T helper type 1 (Th1) cells [95] . Furthermore, CD4+ T cells are particularly sensitive targets for AhR regulation. Activation of AhR by exogenous ligands promotes the development of regulatory T cells while suppressing effector T cell responses both in vitro [109] and in various murine transplantation models, including graft-versus-host disease [110] , cardiac allograft [111] , and pancreatic islet allograft [107] . Furthermore, treatment of mice with AhR ligands has also been shown to ameliorate the development of several T-cell dependent auto-immune diseases [112, 113] .

In addition to their inability to mount efficient T cell responses, CKD patients also exhibit impaired adaptive humoral responses. For instance, the proportion of patients with end stage kidney disease able to develop protective titers of anti-HBs antibodies following vaccination was only 60% in the 1980s' (versus 95% for healthy controls) [114] . Despite intensification of the administration of the vaccine in the new protocols, the rate of responders is still stagnating below 80% today [115, 116] .

Generation of antibodies against a protein antigen starts, within secondary lymphoid organs, with the binding of the antigen to the surface B cell receptor (BCR). This delivers the first signal of activation to cognate B cells and promotes the internalization of the antigen, which is then processed and presented on the cell surface within MHC molecules. The second signal of activation is delivered by a specific subset of CD4+ T cells, named T follicular helper (Tfh) cells. The latter recognize the antigen/MHC complexes on B cell surface through their TCR and in return deliver soluble (interleukin 21) and membrane-bound (CD40 ligand, inducible costimulator ICOS, etc.) costimulatory signals. Activated B cells then enter the germinal center reaction leading to the generation of high affinity memory B cells and antibody-producing plasma cells [47] .

From the paragraph above, it is intuitive that the alterations of helper T cell responses induced by uremic milieu can indirectly explain the defect in antibody responses observed in CKD patients. In line with this hypothesis, a study has reported that patients on hemodialysis generate less antigen-specific memory CD4+ T cells after vaccination with HBV antigen [117] . Regarding the impact of uremic milieu on the specific Tfh subset, there is scarce, conflicting evidence [115, 118] that CKD could be associated with a reduction in their number (in the circulation), however, data that would document the impact on Tfh functions are currently lacking.

Another (non-exclusive) explanation for the defect in antibody response of CKD patients is the direct impact of uremic milieu on B cells. Decrease in GFR correlates with a decrease in total B cell Toxins 2020, 12, 300 8 of 16 number [68, 96] , a problem that seems to affect both naïve (CD19+ CD27−) and memory (CD19+ CD27+) populations [97] and that could be related to a reduced expression in receptor for the survival factor BAFF (for B-cell activating factor) [97] . In line with this theory, it has been shown that B cells from CKD patients have an increased susceptibility to apoptosis in vitro [96] , which was associated with a decreased expression of B-cell lymphoma 2 gene (Bcl-2) [96] , a prosurvival factor induced by BAFF [119] .

PBURS appear as major factors for CKD-induced B cell alterations. In a mice model, chronic administration of pCS induced a strong decrease in B cell count [98] . Additionally, although the effect of uremic levels of tryptophan-derived URS (including IS) on B cells has not been studied yet, it is worth mentioning that a growing number of studies suggests that the AhR pathway is an important regulator of several aspect of B cell biology. First, B cells express AhR and its activation inhibits B cell lymphopoiesis [120] . Second, it has long been observed that mice treated with AhR agonists are unable to mount a humoral response following immunization [121] . B-cell proliferation following BCR stimulation requires AhR [122] , which serves a critical role in regulating activation-induced cell fate outcomes. AhR indeed negatively regulates class-switch recombination, represses differentiation of B cells into antibody-secreting plasma cells [123] , and promotes the acquisition of a regulatory and anti-inflammatory profile (IL-10 producing Breg) [124] .

CKD is associated with a complex defect of almost all components of the immune system (summarized in Figure 2 and Table 2 ), resulting in a peculiar state of "chronic inflammatory immune depression" named CKD-associated immune dysfunctions. It is now widely accepted that the accumulation of PBURS is a critical factor explaining the dysfunction of innate immunity (Table 2) , which accounts for both the increased risk for bacterial infections and the damage to endothelial cells. However, CKD-associated immune dysfunctions also include impaired adaptive cellular and humoral responses, which are critical for the protection against intra-cellular pathogens and cancer. Indirect evidence also suggests that PBURS could also be responsible for these defects ( Table 2) but additional mechanistic studies are required to formally demonstrate this link.

Admitting that PBURS indeed represent the common pathophysiologic factor triggering the various CKD-associated immune dysfunctions, how can we take advantage of this information to improve the immune status of patients? In this regard, hemodialysis appears to be of little help. First it cannot be used in early stages of CKD. Second, even at a later stage, PBURS are not removed efficiently with this technique because most of the toxins are, by definition, bound to protein (while only the free fraction can diffuse across the dialysis membrane). Since PBURS are derived from diet protein, adaptation of intakes (i.e., reduction of tryptophan) could be beneficial by restoring the catabolites balance. Given the importance of CKD-associated dysbiosis in PBURS generation, it is also tempting to target the gut microbiota through pre/probiotics [18] or tryptophanase inhibitors [125] . Preventing PBURS absorption by chelating the toxins in the intestinal tract has also been proposed, with AST-120 for instance [126] . Finally, another theoretical therapeutic possibility would be to act later in the cascade by blocking the AhR pathway, which seems pivotal to mediate IS effects on the immune effectors. Beyond their interest as therapeutic targets, PBURS could also be interesting biomarkers to stratify the risk of immune-mediated complications in CKD. Until recently, the quantification of PBURS was not available in routine clinical practice due to its cost and the need of specific technologies (such as mass spectrometry [127] ). However, the recent development of cheap assays that allow measuring non-invasively the levels of PBURS in the saliva, has the potential to rapidly change this situation [128, 129] ). 

Evolving importance of kidney disease: From subspecialty to global health burden

Biochemical and Clinical Impact of Organic Uremic Retention Solutes: A Comprehensive Update

Diagnosis and management of atherosclerotic cardiovascular disease in chronic kidney disease: A review

Estimated Glomerular Filtration Rate and the Risk of Cancer

Mortality caused by sepsis in patients with end-stage renal disease compared with the general population

Evolving importance of kidney disease: From subspecialty to global health burden

Biochemical and Clinical Impact of Organic Uremic Retention Solutes: A Comprehensive Update

Diagnosis and management of atherosclerotic cardiovascular disease in chronic kidney disease: A review

Estimated Glomerular Filtration Rate and the Risk of Cancer

Mortality caused by sepsis in patients with end-stage renal disease compared with the general population

Risk for Hospitalization with Infection: The Atherosclerosis Risk in Communities (ARIC) Study

Cause of Death in Patients with Reduced Kidney Function

Review on uraemic solutes II-Variability in reported concentrations: Causes and consequences

Urea impairs β cell glycolysis and insulin secretion in chronic kidney disease

Working Group on Chronic Kidney Disease-Mineral and Bone Disorders and the European Renal Nutrition Working Group. The role of phosphate in kidney disease

Normal and Pathologic Concentrations of Uremic Toxins

The uremic toxicity of indoxyl sulfate and p-cresyl sulfate: A systematic review

Functional interactions between the gut microbiota and host metabolism

Chronic kidney disease alters intestinal microbial flora

Probiotics and chronic kidney disease

Chronic Kidney Disease Causes Disruption of Gastric and Small Intestinal Epithelial Tight Junction

Evaluation of the impact of gut microbiota on uremic solute accumulation by a CE-TOFMS-based metabolomics approach

Colonic contribution to uremic solutes

Microbial tryptophan catabolites in health and disease

Enumeration of human colonic bacteria producing phenolic and indolic compounds: Effects of pH, carbohydrate availability and retention time on dissimilatory aromatic amino acid metabolism

The end products of the metabolism of aromatic amino acids by clostridia

The bacterial signal indole increases epithelial-cell tight-junction resistance and attenuates indicators of inflammation

Commensal Bacteria-Dependent Indole Production Enhances Epithelial Barrier Function in the Colon

Linking the Human Gut Microbiome to Inflammatory Cytokine Production Capacity

Indoleacrylic Acid Produced by Commensal Peptostreptococcus Species Suppresses Inflammation

Indole-3-propionic acid attenuates neuronal damage and oxidative stress in the ischemic hippocampus

Indoles from commensal bacteria extend healthspan

Adaptation of the human aryl hydrocarbon receptor to sense microbiota-derived indoles

The aryl hydrocarbon receptor: An environmental sensor integrating immune responses in health and disease

Serum Trimethylamine-N-Oxide Is Strongly Related to Renal Function and Predicts Outcome in Chronic Kidney Disease

The Role of Gut Microbiota and Diet on Uremic Retention Solutes Production in the Context of Chronic Kidney Disease

Tubular Secretion in CKD

Cresyl Sulfate Promotes Insulin Resistance Associated with CKD

p-Cresyl sulfate causes renal tubular cell damage by inducing oxidative stress by activation of NADPH oxidase

A. p-cresyl sulphate has pro-inflammatory and cytotoxic actions on human proximal tubular epithelial cells

P-cresylsulphate, the main In Vivo metabolite of p-cresol, activates leucocyte free radical production

Altered microbiome in chronic kidney disease: Systemic effects of gut-derived uremic toxins

Indoxyl Sulfate and p-Cresyl Sulfate Promote Vascular Calcification and Associate with Glucose Intolerance

Association of Indoxyl Sulfate with Heart Failure among Patients on Hemodialysis

Serum Indoxyl Sulfate is Associated with Vascular Disease and Mortality in Chronic Kidney Disease Patients

Indoxyl sulfate, a representative uremic toxin, suppresses erythropoietin production in a HIF-dependent manner

Indoxyl sulfate exacerbates low bone turnover induced by parathyroidectomy in young adult rats

Hemodialysis membranes: Interleukins, biocompatibility, and middle molecules

Origin and physiological roles of inflammation

Chronic kidney disease induces inflammation by increasing Toll-like receptor-4, cytokine and cathelicidin expression in neutrophils and monocytes

Inflammation-Related Mechanisms in Chronic Kidney Disease Prediction, Progression, and Outcome

Inflammation and Progression of CKD: The CRIC Study

Ni Son Todos Los Que Estan, Ni Estan Todos Los Que Son

Primed peripheral polymorphonuclear leukocyte: A culprit underlying chronic low-grade inflammation and systemic oxidative stress in chronic kidney disease

Toll-like receptor expression in monocytes in patients with chronic kidney disease and haemodialysis: Relation with inflammation

Leukocyte Toll-Like Receptor Expression in End-Stage Kidney Disease

Indolic uremic solutes increase tissue factor production in endothelial cells by the aryl hydrocarbon receptor pathway

Indoxyl sulfate-induced TNF-α is regulated by crosstalk between the aryl hydrocarbon receptor, NF-κB, and SOCS2 in human macrophages

Indoxyl sulfate (IS)-mediated immune dysfunction provokes endothelial damage in patients with end-stage renal disease (ESRD)

Inflammation enhances cardiovascular risk and mortality in hemodialysis patients

Six, I. Para-cresyl sulfate acutely impairs vascular reactivity and induces vascular remodeling

The uremic toxin hippurate promotes endothelial dysfunction via the activation of Drp1-mediated mitochondrial fission

The aryl hydrocarbon receptor-activating effect of uremic toxins from tryptophan metabolism: A new concept to understand cardiovascular complications of chronic kidney disease

Tryptophan-Derived Uremic Toxins and Thrombosis in Chronic Kidney Disease

Endothelial Microparticles and Systemic Complement Activation in Patients With Chronic Kidney Disease

Indoxyl Sulfate-Induced Endothelial Dysfunction in Patients with Chronic Kidney Disease via an Induction of Oxidative Stress

Protein-Bound Uremic Toxins Stimulate Crosstalk between Leukocytes and Vessel Wall

Neutrophil apoptosis and dysfunction in uremia

Lymphocyte depletion and subset alteration correlate to renal function in chronic kidney disease patients

Uremia Effect on White Blood Cell Count in Patients with Renal Failure

Inhibition of the respiratory burst of human neutrophils by the polyamine oxidase-polyamine system

Leptin as a Uremic Toxin Interferes with Neutrophil Chemotaxis

Phagocytic polymorphonuclear function in patients with progressive uremia and the effect of acute hemodialysis

Modulation of NADPH oxidase activity by known uraemic retention solutes

Inhibition of Neutrophil Superoxide Production by Uremic Concentrations of Guanidino Compounds

Mechanisms of uremic inhibition of phagocyte reactive species production: Characterization of the role of p-cresol

Phagocytosis in uremic and hemodialysis patients: A prospective and cross-sectional study

Uremia impairs monocyte and monocyte-derived dendritic cell function in hemodialysis patients

Cresyl sulfate affects the oxidative burst, phagocytosis process, and antigen presentation of monocyte-derived macrophages

Association of cancer with moderately impaired renal function at baseline in a large, representative, population-based cohort followed for up to 30 years

Dendritic Cell Dysfunction in Patients with End-stage Renal Disease

The effects of chronic kidney disease and renal replacement therapy on circulating dendritic cells

Circulating dendritic cell precursors in chronic kidney disease: A cross-sectional study

Decreased antigen-specific T-cell proliferation by moDC among hepatitis B vaccine non-responders on haemodialysis

Renal transplantation reverses functional deficiencies in circulating dendritic cell subsets in chronic renal failure patients

p-Cresyl sulfate suppresses lipopolysaccharide-induced anti-bacterial immune responses in murine macrophages In Vitro

Indoxyl 3-sulfate inhibits maturation and activation of human monocyte-derived dendritic cells

Impaired cellular immune responses in chronic renal failure: Evidence for a T cell defect

Early T Cell Activation Correlates with Expression of Apoptosis Markers in Patients with End-Stage Renal Disease

Naïve and central memory T-cell lymphopenia in end-stage renal disease

End-Stage Renal Disease Causes Skewing in the TCR Vβ-Repertoire Primarily within CD8+ T Cell Subsets

Premature aging of circulating T cells in patients with end-stage renal disease

CD4+CD28null cells are expanded and exhibit a cytolytic profile in end-stage renal disease patients on peritoneal dialysis

Expansion of cytolytic CD4+CD28-T cells in end-stage renal disease

Progressive loss of renal function is associated with activation and depletion of naive T lymphocytes

Longitudinal profile of circulating T follicular helper lymphocytes parallels anti-HLA sensitization in renal transplant recipients

B lymphopenia in uremia is related to an accelerated In Vitro apoptosis and dysregulation of Bcl-2

BAFF activation of the ERK5 MAP kinase pathway regulates B cell survival

Infectious morbidity and defects of phagocytic function in end-stage renal disease: A review

Prolonged survival of skin homografts in uremic patients

Endothelial chimerism and vascular sequestration protect pancreatic islet grafts from antibody-mediated rejection

CKD and the risk of incident cancer

Functional impairment of monocyte-derived dendritic cells in patients with severe chronic kidney disease

Activation of the aryl hydrocarbon receptor affects activation and function of human monocyte-derived dendritic cells

Aryl hydrocarbon receptor activation inhibits In Vitro differentiation of human monocytes and Langerhans dendritic cells

Activation of the aryl hydrocarbon receptor is essential for mediating the anti-inflammatory effects of a novel low-molecular-weight compound

Activation of the aryl hydrocarbon receptor promotes allograft-specific tolerance through direct and dendritic cell-mediated effects on regulatory T cells

Effects of intestinal bacteria-derived p-cresyl sulfate on Th1-type immune response In Vivo and In Vitro

Activation of the aryl hydrocarbon receptor induces human type 1 regulatory T cell-like and Foxp3+ regulatory T cells

Cutting edge: Activation of the aryl hydrocarbon receptor by 2,3,7,8-tetrachlorodibenzo-p-dioxin generates a population of CD4+CD25+ cells with characteristics of regulatory T cells

Activation of aryl hydrocarbon receptor prolongs survival of fully mismatched cardiac allografts

Activation of the Aryl Hydrocarbon Receptor by 10-Cl-BBQ Prevents Insulitis and Effector T Cell Development Independently of Foxp3+ Regulatory T Cells in Nonobese Diabetic Mice

Control of T(reg) and T(H)17 cell differentiation by the aryl hydrocarbon receptor

Randomised placebo-controlled trial of hepatitis B surface antigen vaccine in french haemodialysis units: II, Haemodialysis patients

A randomized trial of serological and cellular responses to hepatitis B vaccination in chronic kidney disease

Hepatitis B virus vaccine immune response and mortality in dialysis patients: A meta-analysis

Impaired Immune Responses and Antigen-Specific Memory CD4+ T Cells in Hemodialysis Patients

Effect of end-stage renal disease on B-lymphocyte subpopulations, IL-7, BAFF and BAFF receptor expression

p-Cresyl sulfate decreases peripheral B cells in mice with adenine-induced renal dysfunction

Aryl Hydrocarbon Receptor Activation Suppresses EBF1 and PAX5 and Impairs Human B Lymphopoiesis

Elucidation of cellular targets responsible for tetrachlorodibenzo-p-dioxin (TCDD)-induced suppression of antibody responses: I. The role of the B lymphocyte

Aryl hydrocarbon receptor is required for optimal B-cell proliferation

The aryl hydrocarbon receptor controls cell-fate decisions in B cells

Salivary Biomarkers in Kidney Diseases. In Saliva in Health and Disease: The Present and Future of a Unique Sample for Diagnosis

Discovery of IDO1 Inhibitors: From Bench to Bedside

Aryl Hydrocarbon Receptor Contributes to the Transcriptional Program of IL-10-Producing Regulatory B Cells

Mass spectrometry in the search for uremic toxins

The utility of saliva testing in the estimation of uremic toxin levels in serum

Randomized Placebo-Controlled EPPIC Trials of AST-120 in CKD

All the authors declared no competing interests.