key: cord-1019570-5ad6lyb3
authors: Sherwood, Karen R.; Nicholl, David D. M.; Fenninger, Franz; Wu, Vivian; Wong, Paaksum; Benedicto, Vince; Cina, Davide P.; Wang, Meng; Pobran, Taylor D.; De Marco, Mari L.; Márquez, Anna Citlali; Jassem, Agatha N.; Sekirov, Inna; Morshed, Muhammad G.; Bardi, Mohammad; Sekhon, Mypinder; Keown, Paul; Kadatz, Matthew; Lan, James H.
title: Comprehensive Immune Profiling of a Kidney Transplant Recipient With Peri-Operative SARS-CoV-2 Infection: A Case Report
date: 2021-09-22
journal: Front Immunol
DOI: 10.3389/fimmu.2021.753558
sha: 68f56208c4993f5611c82b55f606a74012812a08
doc_id: 1019570
cord_uid: 5ad6lyb3

To date there is limited data on the immune profile and outcomes of solid organ transplant recipients who encounter COVID-19 infection early post-transplant. Here we present a unique case where the kidney recipient’s transplant surgery coincided with a positive SARS-CoV-2 test and the patient subsequently developed symptomatic COVID-19 perioperatively. We performed comprehensive immunological monitoring of cellular, proteomic, and serological changes during the first 4 critical months post-infection. We showed that continuation of basiliximab induction and maintenance of triple immunosuppression did not significantly impair the host’s ability to mount a robust immune response against symptomatic COVID-19 infection diagnosed within the first week post-transplant.

A robust immune response is critical to achieving full recovery from COVID-19 infection. Kidney transplant recipients undergo T cell depleting induction therapy followed by maintenance immunosuppression which alters the viral response. There is limited data on the immune response and outcomes of kidney transplant recipients who develop COVID-19 in the early post-transplant period after having undergone induction therapy. Here we present a comprehensive longitudinal assessment of the immune response in a renal transplant recipient who developed symptomatic COVID-19 perioperatively. Our evaluation includes SARS-CoV-2 serology, serum antibody levels, immunoglobulin isotype quantification, T cell receptor sequencing, serum cytokine profiling, and cytometric immune cell profiling (Figure 1 ).

A 30-year-old male with IgA nephropathy received a livingdonor kidney transplant at Vancouver General Hospital, Canada. Pre-transplant flow-cytometric crossmatch and donorspecific antibody testing were both negative. Prior to surgery, both recipient and donor self-isolated for 2 weeks. Nasopharyngeal swabs for COVID-19 were performed on both donor and recipient at the beginning and end of their selfisolation with all results were negative. The patient received basiliximab on day 0 and 4, and was maintained on prednisone, tacrolimus, and mycophenolate mofetil thereafter. Some hours after the surgery, the patient was informed of a COVID-19 exposure and tested positive on postoperative day 2. He became symptomatic with cough, dyspnea on exertion, fevers, and night sweats. He remained clinically well enough however to be discharged on post-operative day 7. During his hospitalization, serial inflammatory markers were measured and showed an elevation in ferritin (peak 1565 ug/L), Creactive protein (peak 133 mg/mL), d-dimer (peaked 960 ug/ L), and fibrinogen (peak 7.9 g/L). His COVID-19 symptoms fully resolved after 1 month. His post-transplant course was also complicated by borderline acute cellular rejection at week 10 that was treated with pulse methylprednisolone, and CMV viremia between weeks 14 and 20 post-transplant. Written informed consent was obtained from the patient for this report.

SARS-CoV-2 Serology, Antibody Reactivities and Immunoglobulin Subclass Dynamics Were Consistent With Mild Infection Even in the Context of Induction Therapy Evaluation of serum antibodies was performed using a semiquantitative multiplexed Luminex bead-based assay, which detects IgG antibodies to SARS-CoV-2 proteins: full spike, spike 1 (S1), spike 2 (S2), RBD, and NC protein. This assay also detects antibodies to proteins from endemic human (CoV-229E-S1, HCoV-HKU1-S1, HCoV-NL63-S1, HCoV-OC43-S1) and novel coronaviruses (MERS-S1 and SARS-S1). Anti-SARS-CoV-2 serologies were further evaluated using MesoScale Discovery V-Plex, a multiplex chemiluminescent immunoassay targeting both SARS-CoV-2 and endemic human coronavirus targets that have been validated against platforms in clinical use (data not shown). No SARS-CoV-2 specific antibodies were detected in samples prior to day 49 by either assay (Figure 2A ). Low levels of serum IgG antibodies (MFI <4,000) to community coronaviruses were detected prior to the first positive SARS-CoV-2 test, suggesting previous exposure to other coronaviruses ( Figure 2A) . From day 49 onwards, MFI values for antibodies specific to CoV-2 spike and RBD proteins increased significantly (MFI > 10,000); MFI values for nucleocapsid and S2 protein were also increased (MFI >3,500). To further characterize the humoral response, we performed an in-house ImmunIQ assay which quantitatively detects anti-SARS-CoV-2 IgG, IgA, and IgM isotypes by using the RBD domain from the spike protein as the capture antigen. The concentration of IgM, IgG and IgA were below detectable limits in post-op day 5 samples. Increasing levels of all three isotypes were detected from day 49, with peak concentrations in day 68 samples (IgG 13.1, IgM 9.1, IgA 2.9 mg/L) ( Figure 2B ). The patient's post-transplant anti-HLA antibody testing showed no de novo donor-specific antibodies.

Cytokine Profiling Shows Limited Evidence of an Inflammatory Phenotype 21 cytokines commonly associated with the previously described COVID-19 'cytokine storm' phenomenon (1-4) were evaluated using the ProCartaPlex Luminex panel. Of these, 12 were below the limits of detection. Only 8 cytokines were detected consistently across all tested longitudinal samples, and of these, levels of IL-18, IP-10, MCP-1, and MIP-1b were all below normal reference values (Supplementary Table 1 ) (5, 6).

Peripheral T cell repertoire profiling was performed for human TCRb genes on a baseline sample taken prior to the SARS-CoV-2 epidemic, and multiple time points post COVID-19 infection. Differential abundance analysis using beta-binomial modelling to account for variability over time, showed limited differences in overall clonal expansion between the baseline sample, and either day 2 or day 5 samples (7). By day 111 however, there were a number of public clonotypes which increased in frequency compared to baseline ( Figure 3A ). Mapping these clonotypes against the ImmuneCODE database, which contains reference data for SARS-CoV-2-associated TCRs, revealed the presence of multiple public TCRs targeting different regions of the SARS-CoV-2 genome ( Figure 3B ). The evidence of such clonotypes in the baseline sample suggests previous exposure to community coronaviruses, with multiple targets mapping to the ORF1 and surface glycoprotein, both regions of which are conserved across various coronaviridae genomes ( Figure 3B ). The top 15 occurring clonotypes across all samples did not show demonstrable changes in the repertoire over the course of infection ( Figure 3C ).

Immune cell phenotyping from whole blood was performed for T regulatory, T memory and B cells. The patient was T cell lymphopenic post-transplant and during the early phase of infection as evident in the immunophenotypic profile on day 2 and 5 (0.37 and 0.43 x 10 9 cells/L) post-infection ( Figure 4A ). By day 49 (1.72 x 10 9 cells/L), T cell counts had returned to within normal range, however the patient was again lymphopenic by day 111 (0.26 x 10 9 cells/L) ( Figure 4A ). CD4 (50.5 -58.4%) and CD8 T cell frequencies (33.7 -38.8%) remained unchanged during the study period ( Figure 4B ) with only minor changes observed in CD4 T cell subsets ( Figure 4C ). Alterations in CD8 T cell compartments were more pronounced compared to CD4 compartments as would be expected in the context of viral infection. The frequency of CD8 EMRA T cells was greatest

FIGURE 2 | SARS-CoV2 and non-CoV-2 antibody profiling using Luminex based assays and immunoglobulin subclass assays. (A) Reactivity of serum IgG antibody to CoV-2 proteins (Full Spike, S1, S2, RBD and NC) and non-SARS-CoV-2 proteins from community coronaviruses (CoV-229E-S1, HCoV-HKU1-S1, HCoV-NL63-S1, HCoV-OC43-S1), and novel coronaviruses (MERS-S1 and SARS-S1). X-axis represents days relative to first positive SARS-CoV-2 test in chronological serum dates. Y-axis represents the Mean Florescence Intensity (MFI) value of the reactivity. (B) Anti-SARS-CoV-2 IgG, IgA and IgM serum concentrations measured using the immunIQ assay (mg/L).

during the acute phase of infection on day 2 (37.4%) and day 5 (30.1%), then decreased on day 49 (21.5%). By day 111 the frequency of CD8 EMRA T cells rose again to day 2 levels (43.1%). In contrast, naïve CD8 T cells frequencies were decreased on day 2 and 5 (36.8 and 52.4% respectively), expanded on day 49 (61.1%), then contracted by day 111 (39.5%) ( Figure 4D ). The frequency of activated non-naïve CD8 T cells (CD38+ HLA-DR+) was significantly increased on day 111 (62.7%), compared to the earlier time points (1.92 -12.8%) ( Figure 4E ). Like T cell subsets, B cell absolute counts were generally low on day 2 and 5 (0.07 and 0.13 x 10 9 cells/L respectively), recovered to normal by day 49 (0.24 x 10 9 cells/L), then diminished again by day 111 (0.03 x 10 9 cells/L blood) ( Figure 4F ). The frequency of B cells, as a proportion of lymphocytes, on the other hand dropped steadily (12.1, 11.8, 9.3 and 3%) over the observation period ( Figure 4G) . The absolute counts of B cell subsets were low in the early phase of infection and the frequency of these subsets including naïve, class-switched, and non-class switched memory B cells changed only slightly ( Figure 4H ). The frequency of plasmablasts was elevated on days 2 and 5 (1.41 and 1.65% respectively), then declined at day 49 (0.25%), and increased again by day 111 (0.72%) ( Figure 4I) . Finally, the Non-T-and Non-B-cell frequency of lymphocytes increased from 29.4 on day 2 to 51.8% on day 5. Subsequently it declined to 27.9 (day 49) before reaching 80% on day 111 ( Figure 4J ).

The concern for allograft rejection must be balanced with permissive immunocompetence to allow for patients to generate a robust antiviral immune response. In this report, we present the unique case of a kidney transplant recipient who contracted COVID-19 in the perioperative window during which he received induction therapy. SARS-CoV-2 antibodies and immunoglobulin subclass dynamics were in keeping with prior reports in which most patients infected with SARS-CoV-2 seroconverted within 14 days of exposure to de novo viral infection (8) . Based on previously reported values, this patient's IgG, IgM, and IgA response was more consistent with a mild response to infection (9, 10) . Antibody isotype kinetics revealed a prolonged profile when compared to non-transplant COVID patients (11) , which may be expected as shedding is often prolonged in kidney transplant patients (12) . The observed humoral response was evident even in the context of induction therapy and immunosuppression. In contrast, there were limited cytokine changes over the course of infection. This noninflammatory phenotype, whilst surprising, could be attributed to the highly dynamic nature of cytokine production which varies significantly depending on pre-existing medical conditions, demographic and environmental factors such as age or prior herpesvirus exposure (13) . In addition, the demonstrable cytokine levels in this patient may be confounded by the use of immunosuppression. Cytokine levels have also been challenging to correlate with mild disease as only a subset of COVID-19 patients exhibit dramatic 'cytokine storm' phenotypes (2) . Immunophenotyping showed changes in lymphocyte subsets throughout the patient's illness and convalescence that were consistent with the findings of other groups in both the non-transplant and transplant setting (2, 14, 15) , including the observed T cell lymphopenia. Subcompartment analysis showed an increased frequency of CD8 TEMRA and activated (CD38+ HLA-DR+) non-naive CD8 T cells during early infection, which is consistent with observations in a non-immune supressed cohort (16, 17) . While only moderately altered, our observed T cell profile is consistent with a larger study of over 100 COVID-19 patients who had a mild course of their illness and recovered without requiring hospitalization (16) . We also report an increased frequency of plasmablasts consistent with a B cell activation signature, consistent with other reports (3, 9, 10, 16) . The appearance of this B cell signature correlates with detectable serum anti-SARS-CoV-2 immunoglobulin and the resolution of the patient's symptoms. One finding of interest is the late-stage re-expansion of CD8 EMRA, activated (CD38+ HLA-DR+) non-naive T cells, and plasmablasts on day 111. Our patient however tested positive for CMV viremia at week 14 which would be a more plausible explanation for this phenomenon, rather than the original COVID-19 infection, although 'second wave' responses have been reported (18) . Whether immunosuppression should be empirically reduced in transplant patients with a COVID-19 infection remains controversial (19, 20) . In this instance, we chose to proceed with standard induction and maintenance immunosuppression due to the patient's favourable clinical characteristics and his relatively mild COVID-19 course. Indeed, even with our effort to maintain standard immunosuppression, this patient developed borderline T In summary, in this unique case report, we showed that basiliximab induction therapy and maintenance of triple immunosuppression did not lsignificantly impair the recipient's ability to mount a protective immune response against symptomatic COVID-19 infection occurring within the first week post-transplant. These results may not however be generalized to depleting induction agents such as anti-thymocyte globulin, which may have a different clinical impact. Longitudinal evaluation of immune parameters, together with recipient risk stratification for rejection, could represent a novel approach to guide optimal management of immunosuppressive agents in transplant patients with a COVID-19 infection.

The flow cytometric data presented in the study are deposited in the flowrepository database, accession number FR-FCM-Z4GA. The TCRSeq data presented in the study are deposited in the BioSample database (https://ncbi.nlm.nih.gov/biosample) repository, accession number SAMN21338671 and SAMN21338972.

The studies involving human participants were reviewed and approved by University of British Columbia Clinical Research Ethics Committee. The patients/participants provided their written informed consent to participate in this study. Written informed consent was obtained from the individual(s) for the publication of any potentially identifiable images or data included in this article. 

In-Depth Virological Assessment of Kidney Transplant Recipients With COVID-19

Longitudinal Characteristics of Lymphocyte Responses and Cytokine Profiles in the Peripheral Blood of SARS-CoV-2 Infected Patients

Distinct Inflammatory Profiles Distinguish COVID-19 From Influenza With Limited Contributions From Cytokine Storm

SARS-CoV-2-Specific T Cell Immunity in Cases of COVID-19 and SARS, and Uninfected Controls

COVID-19: Consider Cytokine Storm Syndromes and Immunosuppression

A Novel IL-18bp ELISA Shows Elevated Serum IL-18BP in Sepsis and Extensive Decrease of Free IL-18

Model to Improve Specificity for Identification of Clinically-Relevant Expanded T Cells Sherwood et al. Peri-Operative COVID-19 in a Kidney Recipient Frontiers in Immunology | www

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SARS-CoV-2 Seroconversion and Viral Clearance in Patients Hospitalized With COVID-19: Viral Load Predicts Antibody Response

Next-Generation Sequencing of T and B Cell Receptor Repertoires From COVID-19 Patients Showed Signatures Associated With Severity of Disease

IgA Dominates the Early Neutralizing Antibody Response to SARS-CoV-2

Targets of T Cell Responses to SARS-CoV-2 Coronavirus in Humans With COVID-19 Disease and Unexposed Individuals

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Immune Cell Profiling of COVID-19 Patients in the Recovery Stage by Single-Cell Sequencing

Longitudinal High-Throughput TCR Repertoire Profiling Reveals the Dynamics of T-Cell Memory Formation After Mild COVID-19 Infection

Transplantation in the Era of the Covid-19 Pandemic: How Should Transplant Patients and Programs be Handled

Post-Transplant Immunosuppression and COVID-19: From a Double Whammy to a Mixed Blessing

We are indebted to the patient whose samples were used for this study. We thank Krishna Dwarka, Cameron Houchmand, Gurvir Thind, and the members of the BC Provincial Immunology laboratory for their assistance. We also thank BCCDC Public Health Laboratory staff involved in SARS CoV-2 antibody testing.

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fimmu.2021.

Conflict of Interest: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.