key: cord-0019413-2tnd7yhr
authors: Martínez‐Romero, Esperanza; Aguirre‐Noyola, José Luis; Bustamante‐Brito, Rafael; González‐Román, Pilar; Hernández‐Oaxaca, Diana; Higareda‐Alvear, Víctor; Montes‐Carreto, Leslie M.; Martínez‐Romero, Julio César; Rosenblueth, Mónica; Servín‐Garcidueñas, Luis Eduardo
title: We and herbivores eat endophytes
date: 2020-12-15
journal: Microb Biotechnol
DOI: 10.1111/1751-7915.13688
sha: 464b44e20a67f169fdd111e2a9660ffab1becafc
doc_id: 19413
cord_uid: 2tnd7yhr

Health depends on the diet and a vegetal diet promotes health by providing fibres, vitamins and diverse metabolites. Remarkably, plants may also provide microbes. Fungi and bacteria that reside inside plant tissues (endophytes) seem better protected to survive digestion; thus, we investigated the reported evidence on the endophytic origin of some members of the gut microbiota in animals such as panda, koala, rabbits and tortoises and several herbivore insects. Data examined here showed that some members of the herbivore gut microbiota are common plant microbes, which derived to become stable microbiota in some cases. Endophytes may contribute to plant fibre or antimetabolite degradation and synthesis of metabolites with the plethora of enzymatic activities that they display; some may have practical applications, for example, Lactobacillus plantarum found in the intestinal tract, plants and in fermented food is used as a probiotic that may defend animals against bacterial and viral infections as other endophytic‐enteric bacteria do. Clostridium that is an endophyte and a gut bacterium has remarkable capabilities to degrade cellulose by having cellulosomes that may be considered the most efficient nanomachines. Cellulose degradation is a challenge in animal digestion and for biofuel production. Other endophytic‐enteric bacteria may have cellulases, pectinases, xylanases, tannases, proteases, nitrogenases and other enzymatic capabilities that may be attractive for biotechnological developments, indeed many endophytes are used to promote plant growth. Here, a cycle of endophytic‐enteric‐soil‐endophytic microbes is proposed which has relevance for health and comprises the fate of animal faeces as natural microbial inoculants for plants that constitute bacterial sources for animal guts.

Health depends on the diet and a vegetal diet promotes health by providing fibres, vitamins and diverse metabolites. Remarkably, plants may also provide microbes. Fungi and bacteria that reside inside plant tissues (endophytes) seem better protected to survive digestion; thus, we investigated the reported evidence on the endophytic origin of some members of the gut microbiota in animals such as panda, koala, rabbits and tortoises and several herbivore insects. Data examined here showed that some members of the herbivore gut microbiota are common plant microbes, which derived to become stable microbiota in some cases. Endophytes may contribute to plant fibre or antimetabolite degradation and synthesis of metabolites with the plethora of enzymatic activities that they display; some may have practical applications, for example, Lactobacillus plantarum found in the intestinal tract, plants and in fermented food is used as a probiotic that may defend animals against bacterial and viral infections as other endophytic-enteric bacteria do. Clostridium that is an endophyte and a gut bacterium has remarkable capabilities to degrade cellulose by having cellulosomes that may be considered the most efficient nanomachines. Cellulose degradation is a challenge in animal digestion and for biofuel production. Other endophytic-enteric bacteria may have cellulases, pectinases, xylanases, tannases, proteases, nitrogenases and other enzymatic capabilities that may be attractive for biotechnological developments, indeed many endophytes are used to promote plant growth. Here, a cycle of endophytic-enteric-soil-endophytic microbes is proposed which has relevance for health and comprises the fate of animal faeces as natural microbial inoculants for plants that constitute bacterial sources for animal guts.

Vegetables provide fibres, vitamins and metabolites that promote health (Cardona et al, 2013; Klinder et al, 2016; Makki et al, 2018) , but their role as microbe providers is less known, unless these microbes are pathogens. When animals consume raw plants, they eat their associated bacteria. Eating an apple may provide hundred millions of bacteria (Wassermann et al, 2019) , as does eating bananas, lettuce (Berg et al, 2014a) or other raw vegetables and non-pasteurized juices. Even if vegetables are washed, peeled or disinfected, they still provide microbes because the endophytic bacteria or fungi reside in the plant interior protected from disinfectants. Herbivore guts had the largest diversity of bacteria, containing 14 phyla, while only six phyla were found in carnivores (Ley et al, 2008) . Different species of Bifidobacterium and Lactobacillus were found in herbivores compared with carnivore or omnivore animals (Endo et al, 2010) . The gut human microbiota has been extensively studied (reviewed in Thursby and Jurge, 2017; Rothschild et al, 2018) and depends on the diet (Muegge et al, 2011; David et al, 2014) . Transient microbiota (called foreign microorganisms by David et al, 2014) may derive from food. Notably, the gut microbiome in humans is determined by the number of vegetables consumed (McDonald et al, 2018) . Ingested bacteria may be metabolically active in human guts as revealed by gene transcripts from food-bacteria in guts (David et al, 2014) . Furthermore, plant-borne pathogens provide an unfortunate example of human ingestion of plant bacteria (Berg et al, 2014a (Berg et al, , 2014b Rosenblueth and Martinez-Romero, 2006) . Certainly, plant bacteria have been in our diet for a long time (Berg et al, 2014a (Berg et al, , 2014b and for the whole evolutionary history of herbivores. The evolutionary history of insects is tightly dependent on plants as food (McKenna and Farell, 2006) and large radiations in insects followed plant diversification (Futuyma and Agrawal, 2009) .

Besides containing bacteria, plants may modify gut bacterial composition and diversity due to their content of fibres, flavonoids, carotenoids, alkaloids, bioactive metabolites, antimetabolites or toxins (Cardona et al, 2013; Klinder et al, 2016; Makki et al, 2018; Baxter et al., 2019) . Japanese that eat seaweeds have a peculiar microbiota (Hehemann et al, 2010) .

All plants in nature and crops have associated microbes (Friesen et al, 2011) in apparently all organs and tissues. Microbes that colonize inner plant tissues are designated endophytes (Rosenblueth and Martinez-Romero, 2006; Harrison and Griffin, 2020; Berg et al, 2014a Berg et al, , 2014b , as the Greek-prefix 'endo' means inside or within and 'phyton' means plant. Endophytes are a selected group of plant-associated microbes (Rosenblueth et al, 2004; Rosenblueth and Martinez-Romero, 2006; Hardoim et al, 2015; Busby et al, 2016) in the sense that only particular microbial genotypes are capable of internally colonizing specific plants. Endophytes promote plant growth by different strategies, such as suppressing or out-competing pathogens, fixing nitrogen, producing hormones that stimulate plant growth, protecting from stress or enhancing the availability of minerals (Rosenblueth and Mart ınez-Romero, 2006) .

Gut microbiota may contain hundreds to thousands of bacterial species (McDonald et al, 2018; Rothschild et al, 2018) that may be acquired from or selected by the diet. Bacterial cultures from herbivore faeces showed bacteria that are evidently derived from plants, for example methylobacteria isolated in cultures from rhino (Rhinoceros sondaicus) and alpaca faeces (Jiang et al, 2013) and detected in cabbage white butterfly (Robinson et al, 2010b) . Methylobacteria (commonly found in plants) use methanol, a sub-product of plant cell wall biosynthesis and produce the plant hormones cytokinins (Lidstrom and Chistoserdova, 2002) . Furthermore, cultured actinobacteria from herbivores showed that Streptomyces, Rhodococcus and Microbacterium were the dominant isolates from all six animal faeces tested, including an elephant (Jiang et al, 2013) . These bacteria are common plant endophytes, for example, Microbacterium was isolated from legume nodules in arid regions (Zakhia et al, 2006) and from a halophyte in a salt-marsh (Alves et al, 2014), Streptomyces was found as a seed endophyte in a Phaseolus vulgaris (common bean) cultivar with outstanding characteristics (L opez-L opez et al 2010) and a Rhodococcus leaf endophyte enhanced resistance to pathogenic fungi in potato (Hong et al, 2016) .

Endophytes that feed on plants would have fibre degrading capabilities that would help animals degrade plant polysaccharides in guts. Plant fibres containing cellulose and hemicellulose are not easily digested, and sets of large numbers and diverse degrading enzymes are needed, including glycoside hydrolases and polysaccharide lyases, which are not produced or rarely produced by mammals (El Kaoutari et al, 2013) . Clostridium is found as an endophyte and in many animal guts (Figs 1 and 2) . Clostridial cellulolytic activity is remarkable because these bacteria may contain cellulosomes (Bayer and Lamed, 1986; Schwarz, 2001) , which are considered the most efficient natural nanomachines (Nunes, 2018 ) that degrade both cellulose and hemicellulose. Cellulosomes are protuberances on the bacterial cell wall (Bayer and Lamed, 1986) containing complex enzymatic systems. Enterobacter that is found in herbivore guts or faeces and in plants ( Fig. 1 ) has diverse polysaccharide degrading enzymes such as cellobiosidase, endoglucanase, polygalacturonase, xylanase, bglucuronidase, pectinases and cellulases (Prem Anand et al, 2010; Naveed et al, 2014; Xia et al, 2017) . Cellulases are found in many Proteobacteria, Firmicutes and Actinobacteria (Berlemont and Martiny, 2013) .

In contrast to fibre or wood-chewing insects, sap-sucking insects such as stinkbugs or cochineals may have bacteria with less fibre degrading capabilities. In sapsucking insects, protease activity was found in guts and it was suggested that 'digestive proteolysis may be widespread in homoptera' (Foissac et al, 2002) . In the carmine cochineal, Dactylopiibacterium showed increased expression of protease and peptidase genes in a gut metatranscriptomic analysis suggesting a bacterial origin of proteases in guts (Bustamante-Brito et al, 2019).

Some herbivores have a specialized diet, for example koalas eat eucalyptus, pandas eat bamboos, tortoises eat cactus, Monarch butterfly pupas eat Asclepias and maguey red worms eat Agave cactuses and their microbiota serves to digest some of the particular substances or antimetabolites in their host plants. Some of the antimetabolites may be degraded in guts by endophytes such as Pseudomonas, burkholderias and Enterobacter (Shanmuganandam et al, 2019) . Tannins are the fourth more abundant plant molecules after cellulose, hemicellulose and lignin, with tannic acid as the most abundant reserve in plants (de Las Rivas et al, 2019) . Tannases that degrade tannins found in eucalyptus, quercus and other tree leaves ingested by herbivores, are produced by many bacterial genera found in guts and plants, including Enterobacter, Weissella and Lactobacillus (de Las Rivas et al, 2019). Pinene, from pine trees that are ingested by different beetles, is degraded by some Pseudomonas using monooxygenases, lyases and aldehyde dehydrogenases (Linares et al, 2009) .

The importance of endophytic fungi in plants and ecosystems is well appreciated (Harrison and Griffin, 2020) . In turn, fungi may harbour bacterial communities that would also have an impact in plants (Bonfante et al, 2019) . We suppose that from the outstanding diversity of fungi in plants (Harrison and Griffin, 2020 ) only a few fungi colonize animal guts. Some fungi are commonly found inside insects and plants (Pa zoutov a et al, 2013; Chen et al, 2018; Biederman and Vega, 2020) and may have cellulases and tannases (Martin, 1992; de Las Rivas et al, 2019) . The most common contribution from fungi to their insect symbiont is the catalytic capacity to break down plant polysaccharides such as cellulose and pectin from their diet (Martin, 1992) . Herrera et al (2011) found sequences 97% similar to root-associated fungi in coprophilous fungal communities obtained from the dung of four species of mammalian herbivores. The effects of eating endophytic fungi were observed with sheep. Sheep were fed ryegrass with or without distinct fungal endophytes, and later sheep faeces were studied for their degradation rate. Faeces from animals that ate grass with fungal endophytes had the lowest faecal degradation rates (Cripps et al, 2013) . This nice example showed that fungal endophytes from grasses that were consumed by sheep arrived into guts and exerted effects on faeces.

Insects among animals seem to have had unique associations with fungi for around 420 million years. These associations range from pathogenic with Cordyceps for example, to obligate mutualisms found in beetles, wasps and ants (Boucias et al, 2012a (Boucias et al, , 2012b Gibson and Hunter, 2010) . Remarkably, some of the insect-associated fungal groups are well-known endophytes within the Sordariomycetes and Agaromycetes (Naranjo-Ortiz and Gabald on, 2019). Interestingly, some protists may inhibit cellulolytic activities in guts (Ray et al, 2012) . Protists and archaea though they are associated with plants and guts, will not be revised here, neither the rumen or bee microbiota ( Taxis 

The koala (Phascolarctos cinereus) has a diet based almost exclusively on Eucalyptus leaves (Moore and Foley, 2000) . Secondary metabolites contained in Eucalyptus plants act as toxins and antimicrobial agents that could affect the koala and its microbiota (Moore et al, 2004; Brice et al, 2019) . The koala gut microbiota is highly conserved and specialized in the digestion and detoxification of dietary components (Brice et al, 2019). Blyton et al (2019) demonstrated that oral-faecal inoculation between wild koalas with different feeding habits allows them to feed on Eucalyptus species that were previously inedible. Similarly, gut microbiota are acquired by juvenile koalas when they feed on special maternal faeces called 'pap' (Osawa et al, 1993a (Osawa et al, , 1993b . The strict vegetarian diet of koalas leads to a constant supply of endophytic microbes, which may become resident or transitory inhabitants of their guts. The koala rectum is mainly colonized by Bacteroidetes, Firmicutes and Proteobacteria (Barker et al, 2013; Alfano et al, 2015) . Staphylococcus, Bradyrhizobium and Acinetobacter have been found in koala guts and as Eucalyptus endophytes (Proc opio et al, 2009; da Silva Fonseca et al, 2018) . Likewise, tannin-degrading strains of Streptococcus, Enterobacter and other Enterobacteriaceae have been isolated from koala faeces (Osawa, 1992) , 'pap' (Osawa et al, 1993a (Osawa et al, , 1993b and Eucalyptus leaves (Miguel et al, 2016) . Cellulose-degrading Pseudomonas and spore-forming bacilli are other examples of microbiota shared between koala faeces and Eucalyptus tissues (Singh et al, 2015; Miguel et al, 2016) .

The giant panda (Ailuropoda melanoleuca) consumes about 15 kg of leaves, stems and shoots of bamboo every day (Dierenfeld et al, 1982) . Due to their carnivorous origin, pandas have a straight short gastrointestinal tract (Ley et al, 2008 ) whose microbiota is rich in Proteobacteria and Firmicutes ( Fig. 1) (Tun et al, 2014; Xue et al, 2015; Guo et al, 2019) . However, the gut microbiota is affected depending on the part and species of bamboo consumed. For instance, a high leaf consumption leads to an increase in Bacteroides and a decrease in Lactobacillus, but it does not affect Streptococcus and Clostridium populations (Williams et al, 2013) . A phylogenetic tree showed Clostridium from plants and gut intermingled indicating that gut bacteria were recently acquired or constantly exchanged ( Fig. 2A) . Recent work by Jin et al (2020) showed that bacteria and fungi colonizing different bamboo species appeared as gut colonizers after consumed by giant pandas. Interestingly, the greater the microbial diversity of bamboo, the greater the diversity found in faecal samples.

The cellulolytic activity of Clostridium as well as the presence of bacterial genes that encode plant cell wall degrading enzymes (endocellulase, b-glucosidase, xylan 1,4-b-xylosidase and endo-1,4-b-xylanase) in panda guts highlight the microbial degradation of bamboo (Zhu et al, 2011; Guo et al, 2020 ) that could perhaps help to release endophytes during digestion.

Among the Proteobacteria that inhabit panda faeces, Pseudomonas, Klebsiella, Enterobacter and Pantoea are frequent endophytes of grasses and bamboo (Han et al, 2009b; Han et al, 2010; Liu et al, 2017) . Most genes related to pathways for the plant secondary metabolite degradation have been associated with Pseudomonas from panda gut metagenomes (Zhu et al, 2018; Yao et al, 2019) . Klebsiella and Enterobacter strains isolated from panda faeces carry genes involved in microbe-plant interactions and cellulose degradation indicating their endophytic origin (Lu et al, 2015a (Lu et al, , 2015b .

Weissellas from panda faeces are intermingled with plant weissellas in 16S rRNA gene phylogenetic trees, and this is the case with weissellas from human and bat faeces and from fish guts (Fig. 2B) . Weissellas may contain tannases that would help to degrade tannins from plants (de Las Rivas et al, 2019) .-Similarly, Cryptococcus, Ramichloridium, Shiraia, Ceramothyrium, Rhinocladiella and Cephalosporium are bamboo-associated fungi detected in panda's faeces (Jin et al, 2020) .

The gut microbiota of the giant panda resembles that of carnivorous and omnivorous bears because it has a different and lower diversity than other herbivores (Xue et al, 2015) , but it also shows bacterial signatures that could result from being a bamboo specialist.

Rabbits (Oryctolagus cuniculus) eat grasses, tree leaves and faeces. They are considered caecotrophagic animals because they ingest their soft faecal pellets produced by digestion in the caecum. Within herbivorous mammals, rabbits have the shortest mean retention time to digest their food, while the ruminants have the longest (Uden, et al, 1982; Kararli, 1995; Crowley et al, 2017) . The rabbit digestive tract is adapted to process large amounts of fibre-rich feed. Microbial fermentation of the food takes place in the caecum (Mackie, 2002; Harcourt-Brown, 2004) . Bacteroidetes dominate the caecal population and may be associated with the high fibre content in the diet (Crowley et al, 2017) .

Like koalas, newborn rabbits in wild habitats ingest faecal pellets excreted by their mothers (Kovacs et al, 2006) . When rabbits have access to the faecal excreta, bacteria colonize the caeca and rabbits have a reduced mortality after weaning in comparison to rabbits not consuming faeces (Combes et al., 2014) .

Clostridium, Anaerofustis, Blautia, Akkermansia and Bacteroides are abundantly found in caecal samples, and in faeces Oscillospira and Coprococcus (Velasco-Galilea et al, 2018). Clostridium as well as Roseburia, Sutterella, Enterobacter and Desulfovibrio have been reported as endophytes and in rabbit faeces (Velasco-Galilea et al, 2018; Shanmuganandam et al, 2019) . Interestingly, the genome of a gut Enterobacter cloacae strain has genes for plant colonization revealing characteristics of an endophyte (Shastry et al, 2020) . Roseburia can produce butyrate, which is a nutrient for enterocytes (Tamanai-Shacoori et al, 2017) . Butyrate was identified as a promotor of gut barrier formation (Beaumont et al 2020).

Herbivory is not frequently found among reptiles (Yuan et al, 2015) . However, there are herbivorous tortoises such as Gopherus berlandieri that is found in arid regions in Northeast Mexico and Southern United States (Judd and Rose, 1983) . From the faeces of G. berlandieri healthy tortoises, we isolated Klebsiella variicola (Montes-Grajales et al, 2019). K. variicola may be found as endophyte in maize, banana and rice plants (Rosenblueth et al, 2004) and was found as well in newborn baby faeces (Rosales-Bravo et al, 2017) . K. variicola has been proposed to be used as probiotic (Rosales-Bravo et al, 2017) or crop inoculant. This bacterium is found in humans as an opportunistic pathogen (Martinez-Romero et al, 2018) .

From different G. berlandieri tortoises, distinct K. variicola isolates showed limited genetic diversity, suggesting that they are clones selected from a larger pool of these bacteria. Nitrogen-fixing activity was detected by the acetylene-reduction assay, both from faeces and K. variicola isolates. As tortoises are coprophagous, it seems possible that they acquire K. variicola tortoiseborne strains directly from their mother or from the faeces of other tortoises. We surmise that K. variicola in tortoises were plant-borne but we did not find them in their vegetal food; thus, they are not continuously ingested. Some K. variicola clones seem to have become stable microbiota, selectively maintained in tortoises by coprophagy. Clostridium was abundantly found in Gopherus flavormarginatus (Garcia-De la Peña et al., 2019), Gopherus polyphemus (Yuan et al, 2015) and G. berlandieri faeces.

Some stinkbugs from the superfamilies Coreoidea, Lygaeoidea and Pyrrhocoroidea feed on sap of diverse plants that have burkholderia endophytes. Burkholderia were found in insect guts in specialized compartments with crypts that have restricted entry and high burkholderial densities (Kikuchi et al, 2007 (Kikuchi et al, , 2011 Kim and Lee, 2015) . Recently, two novel genera were named for burkholderia subclades, Paraburkholderia and Caballeronia (Sawana et al, 2014; Dobritsa and Samadpour, 2016) , and these are differentially encountered in stinkbug families that have specialized diets (Takeshita et al, 2015; Takeshita and Kikuchi, 2020) . The symbiosis of phytophagous stinkbugs with these bacteria seems to be ancient (Kikuchi et al, 2011; Takeshita et al, 2015) . Symbionts are beneficial to the insects, as stinkbugs without them displayed developmental delays, impaired survival or reduced size (Kikuchi et al, 2007; Boucias et al, 2012a; Xu et al, 2016a) . Bacteria may confer stinkbugs resistance to the insecticide fenitrothion (Kikuchi et al, 2012; Tago et al, 2015) . A transcriptome analysis of midgut-colonizing Burkholderia insecticola from the beanbug Riptortus pedestris showed that bacteria recycle the host nitrogen wastes allantoin and urea, provide B vitamins, especially B12 and supply methionine and tryptophan to the host (Ohbayashi et al, 2019) . Burkholderias constitute nice examples of plant bacteria that become gut colonizers, which are acquired by each new insect generation (Kikuchi et al, 2007; Kikuchi et al, 2011) . Consequently, reported phylogenies showed that insectgut and plant burkholderias are intermingled (Itoh et al, 2014; Tago et al, 2015; Xu et al, 2016b) .

Carmine cochineals (Dactylopius spp.) are a group of hemipteran insects that have cultural and economic importance, as they produce a pigment called carminic In the carmine cochineal guts, we found one species of endophytic fungi belonging to the genus Coniochaeta. Coniochaeta species are main endophytes of trees and grasses with some species well known for their production of a broad spectrum of antimycotics (Xie et al, 2015) .

Wood-eating Dendroctonus beetle guts contain nitrogenfixing bacteria, for example Raoultella terrigena that is a common endophyte (Morales-Jim enez et al, 2013). Endophytes that have been used as plant growth-promoting bacteria were also isolated from Dendroctonus beetles. Among these, Serratia, Pseudomonas and Rhanella species were able to recycle uric acid (Morales-Jim enez et al, 2013). An additional study using 16S rRNA gene identification of gut bacteria from the pinepest Monochamus alternatus (Coleoptera) showed Enterobacter, Raoultella, Serratia, Lactococcus and Pseudomonas, which are commonly found in plant tissues as well. Enterobacter was the most common in larval and Serratia in pupal intestines. These bacteria may help to degrade the terpene pinene found in pines .

Weevils are important beetle pests of stored grain legumes that feed and reproduce on dried seeds (Tuda, 2007) . The neotropical genus Acanthoscelides comprises a diverse group of weevils some specialized on Phaseolus seeds (Alvarez et al, 2005) . We studied the gut microbiota of bean weevils, Acanthoscelides obtectus (Coleoptera: Chrysomelidae, Bruchinae). Weevils were collected from inside wild P. vulgaris seeds from vines growing in mountain fields in the state of Morelos, Mexico. 16S ribosomal RNA genes from midgut DNA or from isolates were sequenced to generate a census of bacterial communities. We identified bacteria related to Agrobacterium, Bacillus, Massilia, Gluconacetobacter, Propionibacterium, Asaia and Bradyrhizobium. Bacillus isolates were frequently identified in bean seeds (Lopez-Lopez et al, 2010) and leaves as endophytes (de Oliveira Costa et al, 2012). We suppose that P. vulgaris endophytes are transferred to the guts of A. obtectus weevils when they feed on bean seeds. Weevil insects in turn may transfer these bacteria to other plants and seeds. Cellulosimicrobium found in cactus has an outstanding capability to degrade the plant cell wall using cellulases, xylanases and pectinases (Han et al, 2009a) . Cellulosimicrobium was isolated from elephant and alpaca faeces (Jiang et al, 2013) . We identified this bacterium from maguey worm microbiomes. Isolated strains from the larva guts of another lepidoptera, Plutella xylostella were capable of degrading plant phenolic compounds (Xia et al, 2017) .

Monarch butterflies have a specialized plant diet. Milkweeds of the genus Asclepias are the preferred food of monarch caterpillars and adult monarchs feed on the nectar and pollen of flowers that provide sugars and other nutrients. We analysed the overwintering microbiota from guts of adult monarch butterflies, Danaus plexippus (Lepidoptera: Nymphalidae, Danainae) by sequencing metagenomes and 16S rRNA genes from bacterial isolates. We identified 16S rRNA gene sequences for Asaia, Pseudomonas, Serratia, Enterococcus, Carnobacterium, Kinetoplastibacterium, Xylophilus, Polaromonas, Herbaspirillum and Lactococcus bacteria. Some of these bacteria such as Pseudomonas, Serratia, Enterococcus, and Herbaspirillum are well known endophytes of plants. In guts of adult monarch butterflies, the acetic acid bacterium Commensalibacter was the most abundant Servin-Garcidueñas and Mart ınez-Romero, 2014) .

The adult cabbage white butterflies (Pieris rapae) contain Enterobacter as well as Flavobacterium in their guts (Steinhaus, 1941) ; in the larvae, species from the genera Asaia, Acinetobacter, Methylobacterium, Enterobacter and Pantoea have been found (Robinson et al, 2010a (Robinson et al, , 2010b . Bacteria from these genera are common plant endophytes. Sinigrin, a glucosinolate found in Brussels sprouts, affects the bacterial community composition when fed to the cabbage white butterfly larvae. The bacteria found in the midgut may participate in sinigrin degradation (Robinson et al, 2010a (Robinson et al, , 2010b .

Lactobacillus plantarum is found in plants as endophyte (Minervini et al., 2018) and commonly in Drosophila gastrointestinal tracts (Siezen et al, 2010) . L. plantarum from Drosophila is related to strains from the same species from human faeces and plants (Fig. 2C) . Drosophila in natural habitats may feed on plants but mainly on yeast from fermented fruits (Becher et al, 2012) . L. plantarum, considered a facultative symbiont, is continuously ingested and excreted by Drosophila (Storelli et al, 2018) . It provides acetyl-glutamine to the host, produces a hormone-signalling control (Storelli et al, 2011) and stimulates the production of intestinal peptidases (Matos et al, 2017) . Notably, an improvement of host beneficial effects was obtained by an experimental evolution assay of L. plantarum across 20 Drosophila generations (Martino et al, 2018) .

Similarly, from the Mediterranean fruit fly several enterobacteria were isolated including Klebsiella that was found in all samples; nitrogen fixation was detected in the enterobacterial cultures (Behar et al, 2005 ). An additional study from our laboratory (using 16S rRNA gene identification of cultured gut bacteria) from wild larvae from the Mexican fruit fly Anastrepha ludens showed Bacillus, Lactobacillus, Pseudomonas, Enterobacter, Klebsiella, Acinetobacter, Leuconostoc and Weissella. All of them are reported endophytes. Nitrogen-fixing activity was detected by the acetylene-reduction assay with Klebsiella and Enterobacter. Pectinolytic activity was observed in Pseudomonas and Bacillus and uricolytic activity in Pseudomonas. Additionally, we isolated in culture Pichia and Hanseniaspora yeasts (that are known fungal endophytes) from A. ludens larvae. Pichia was present in the oranges where larvae were feeding. Both yeasts were found in Drosophila suzukii (Hamby et al, 2012) . A. ludens is an important pest in Mexico and Central America that attacks several fruit species especially citrus and mangos. Larvae feed on the fruits causing great losses, and biological control with sterile males has been used to control this pest (Barker et al., 2013 ).

We showed data to support the endophytic origin of some gut bacteria, and we propose here the natural existence of an endophytic-enteric-soil-endophytic microbiota cycle, designated hereafter as endophytic-enteric cycle (Fig. 3) in which plant tissues could act as enteric 'fibre capsules' to protect plant endophytes from being digested in the stomach and allowing their later release in the intestine. If plant-borne microbes from guts pass to the environment, then they may become soil bacteria and a natural biological inoculant of plants. By colonizing plants, these bacteria would complete a microbe cycle. Common ecological features in roots and gut (Ram ırez-Puebla et al, 2013) support their sharing bacteria. A shortcut in the endophytic-enteric cycle would be faecal ingestion (coprophagy), which is a common practice among many animals, we surmise that animals were pioneers on faecal transplants. Fecal transplants are successfully used in modern Medicine by donating processed faeces from healthy humans to human patients with chronic gut diseases (Petrof and Khoruts, 2014).

Endophytes, which may or may not reproduce in the gut, could pass in faeces to soil and water. Tracing bacteria from animal guts to the soil was made possible by identifying antibiotic-resistant bacteria in soil that derived from manure obtained from chicken or cow faeces (Wichmann et al, 2014) . Spread of enteric bacteria could lead to a flow of antibiotic resistance genes from sewage, manure or slurry to humans (Linton, 1986) . Farmland soils that were fertilized with chicken manure had high levels of antibioticresistant bacteria (Zhao et al, 2017) , and the impact of the use of antibiotics in farm animals has been studied (Qian et al, 2018; Heuer et al., 2011) . Manure would constitute not only a way to recycle large amounts of N to plants but a source of bacteria for plants, and this has been shown when plants got contaminated with pathogens from animal manures (Guan and Holley, 2003) . It was reported that human health depends on plant health, which in turn is determined by soils (Hirt, 2020) .

As soils are rich in bacteria, insect microbiota may derive directly from soil (Fig. 3) and indeed soils were the main source and not host plants for the leaf-eating caterpillar microbiota (Hannula et al, 2019) . This may be considered as another shortcut in the cycle and remains to be tested with other insects. Certainly, there is a very dynamic flux of microbes to the gut. In the reverse direction, phytophagous insects that harbour multiple gut bacteria in oral secretions may transfer microbes to plants during feeding (Fig. 3 ) (Chung et al, 2013) and this is how many insects are vectors of plant pathogens. Endophytes normally feed on plant products, and their degradative capabilities could be of use in catabolizing plant-derived nutrients or suppress pathogens and fix nitrogen in the gut, as they do in plants. Gut Not all plant bacteria would survive digestion and participate in the endophytic-enteric cycle. Therein, sporeproducing bacteria may be particularly successful, as spores are resistant forms which could even become activated inside guts. Notably, spores may be an important constituent of gut microbiomes (Browne et al, 2016) .

Even though there is clear evidence of plant-derived bacteria in guts, a major question remains, are all small fragments of plant tissues effectively removed before macerating faecal samples? If not, they could be a source of DNA that would not reflect true gut bacteria. Work with panda faeces (Wei et al, 2007; Xue et al, 2015; Jin et al, 2020) addressed this issue, but it is not the case in all studies with faeces microbiota. Caution should be taken with metagenomic data, and microbial cultures from guts not to erroneously consider bacteria or fungi in plant fragments as bona fide gut microbiota. It is remarkable that most studies of gut microbiota are from faeces that may not well reflect gut bacteria (Zmora et al, 2018) . Diet bacteria should be analysed concomitantly with gut microbiota and a comparison of the survival in the digestive tract of plant-surface bacteria (Leff and Fierer, 2013) in relation to endophytes would be highly informative.

Seemingly, carnivores have endophytes in their guts as well. For example, Prevotella, which is known to be able to degrade plant derived carbohydrates, was the most abundant bacterium in the feline gut (Alessandri et al, 2020b) . Endophytes in carnivore guts may derive from ingesting herbivore guts or faeces or soil-contaminated meat. Notably, the gut microbiota of cats and dogs is determined as in humans by the diet and modified by overweight or inflammatory diseases (Alessandri et al, 2020a) .

We suppose that plants may protect themselves from herbivory by possessing not only antimetabolites and toxins (in many cases produced by microbes) but also microbes that may cause disease or death to herbivorous animals when ingested. In contrast, plant bacteria may be useful, for example, Lactobacillus plantarum that is found in human and in omnivore gastrointestinal tracts (Siezen et al, 2010; Endo et al, 2010) is used as a probiotic (Panigrahi et al, 2017; Raveschot et al, 2020) , which may help animals to better resist viral infections (Kumar Fig. 3 . Schematic representation of the endophytic-enteric microbiota cycle. Inside plant-tissue endophytes may gain access to animal guts when animals eat plants, in turn animals produce faeces that may carry the ingested plant bacteria that would be available to colonize plants again. Coprophagy (faeces ingestion) is a shortcut in the cycle, as well as the transfer of insect bacteria to the plant during feeding or direct acquisition of bacteria from soil. (Chai et al, 2013; Mahooti et al 2020; Baud et al, 2020) . However, probiotics constitute only transient members of the gut microbiota, remaining short periods in the gastrointestinal tract (Zmora et al, 2018) as we suppose some endophytes would do. Additionally, L. plantarum and Weissella are used in fermented food from plant products (Wacher-Rodarte et al., 2015 , Kavitake et al, 2016 . Curiously, a metabolomic study showed that fermented food and stools were similar (Quinn et al, 2016) .

Herbivores have most probably picked up their stable microbiota from plant-associated bacteria. Particularly, the evolutionary history of insects is tightly dependent on plants as food (McKenna and Farell, 2006) . When an herbivore has recently ingested an endophyte, gut strains would be identical or very similar to the plant isolates, as can be observed in phylogenies from Weissella from panda faeces, in L. plantarum and clostridia phylogenies (Fig. 2 ) or in burkholderias from the stinkbugs (Itoh et al, 2014; Tago et al, 2015; Xu et al, 2016b) . On the other hand, when the endophytes coevolved with their animal hosts which maintain them by vertical transfer, then these bacteria would be divergent from plant bacteria, as observed in some insect symbionts such as Commensalibacter and Dactylopiibacterium (Serv ın-Garcidueñas et al., 2014; Vera-Ponce de Le on et al, 2017). Specialized insect endosymbionts in abdominal bacteriomes could have derived from gut bacteria, which in turn derived from endophytes that were found in plants that may not exist today. Flavobacterial endosymbionts of scale insects (Rosenblueth et al, 2012 (Rosenblueth et al, , 2018 , which are around 200 million years old and provide essential amino acids to the insect, perhaps derived from plant flavobacteria which are found mainly in wild but not in domesticated plants (P erez-Jaramillo et al., 2018) .

If we eat endophytes, we may excrete endophytes; this occurs with mealybug insects that eat and excrete honeydew containing Gluconacetobacter spp. (Ashbolt and Inkerman, 1990) , a common nitrogen-fixing endophyte from sugarcane (Caballero-Mellado and Martinez-Romero, 1994) . Notably, the numbers of Gluconacetobacter bacteria diminish drastically in plants with nitrogen chemical fertilization (Fuentes-Ram ırez et al., 1999) . Similarly, other agrochemicals may have strong effects on plant microbiota and thus on the endophytes which we ingest. Remarkably, fungal endophytes may vary depending on the habitat (Harrison and Griffin, 2020) . Finally, inoculants used on plants should be considered not only in terms of their plant growth-promoting capabilities but for their effects on human health as well. The use of cyanobacteria in plants should be carefully evaluated and avoided if possible. Cyanobacteria produce very harmful neurotoxins and hepatotoxins (Codd et al, 2005) .

Certainly all herbivores eat endophytes, some of them may be digested or not liberated from plant tissues but others may be active in the gut and contribute to fibre or tannin digestion or to the synthesis of essential amino acids or vitamins, fix nitrogen or provide defence against pathogens. When studying herbivore gut microbiota, plant fragments in guts should be independently analysed.

While stable members of the gut microbiota may have derived from the vegetal diet, newly ingested endophytes may be quite variable. It would be desirable to eat the ones that contribute most to human health either as probiotics or with food. There is still lots to explore on this considering the variable responses in human individuals to probiotics, and the large effects of crop management on plant microbes. Ideally, plant microbial inoculants should benefit both plants and humans. Clearly, the endophyte-enteric cycle has relevance to animal health. So, which endophytes would you like to eat? 

Catching a glimpse of the bacterial gut community of companion animals

Comadia redtenbacheri (Lepidoptera: Cossidae)

Benefits of polyphenols on gut microbiota and implications in human health

Antiviral effects of a probiotic Enterococcus faecium strain against transmissible gastroenteritis coronavirus

The Opuntia (Cactaceae) and Dactylopius (Hemiptera: Dactylopiidae) in Mexico: a historical perspective of use, interaction and distribution

Gut bacterial and fungal communities of the domesticated silkworm (Bombyx mori) and wild mulberry-feeding relatives

Bacterial communities associated with the pine wilt disease insect vector Monochamus alternatus (Coleoptera: Cerambycidae) during the larvae and pupae stages

Herbivore exploits orally secreted bacteria to suppress plant defenses

Cyanobacterial toxins: risk management for health protection

Plant compartment and biogeography affect microbiome composition in cultivated and native Agave species

Coprophagous behavior of rabbit pups affects implantation of cecal microbiota and health status

Grass species and their fungal symbionts affect subsequent forage growth

Comparison of the microbial population in rabbits and guinea pigs by next generation sequencing

Diet rapidly and reproducibly alters the human gut microbiome

The functional microbiome of arthropods

Utilization of bamboo by the giant panda

Transfer of eleven species of the genus Burkholderia to the genus Paraburkholderia and proposal of Caballeronia gen. nov. to accommodate twelve species of the genera Burkholderia and Paraburkholderia

Diversity of Lactobacillus and Bifidobacterium in feces of herbivores, omnivores and carnivores

Functional diversity within the simple gut microbiota of the honey bee

Functional signatures of the epiphytic prokaryotic microbiome of agaves and cacti

Putative protein digestion in a sap-sucking homopteran plant pest (rice brown plant hopper; Nilaparvata lugens: Delphacidae) -identification of trypsin-like and cathepsin B-like proteases

Microbially mediated plant functional traits

Colonization of sugarcane by Acetobacter diazotrophicus is inhibited by high N-fertilization

Macroevolution and the biological diversity of plants and herbivores

Comparison of the fecal bacterial microbiota composition between wild and captive bolson tortoises (Gopherus flavomarginatus)

Extraordinarily widespread and fantastically complex: comparative biology of endosymbiotic bacterial and fungal mutualists of insects

Inherent bacterial DNA contamination of extraction and sequencing reagents may affect interpretation of microbiota in low bacterial biomass samples

Pathogen survival in swine manure environments and transmission of human ª 2020 The Authors

enteric illness-a review

The carnivorous digestive system and bamboo diet of giant pandas may shape their low gut bacterial diversity

Comparative study of gut microbiota in wild and captive giant pandas (Ailuropoda melanoleuca)

Associations of yeasts with spotted-wing Drosophila (Drosophila suzukii; Diptera: Drosophilidae) in cherries and raspberries

Isolation and characterization of a cellulase-free endo-b-1, 4-xylanase produced by an invertebrate-symbiotic bacterium, Cellulosimicrobium sp. HY-13

Diversity of the phosphate solubilizing bacteria isolated from the root of Phyllostachys pubescens

Diversity of culturable bacteria isolated from root domains of moso bamboo (Phyllostachys edulis)

Foliar-feeding insects acquire microbiomes from the soil rather than the host plant

Biological characteristic of domestic rabbit/ Digestive physiology

The hidden world within plants: ecological and evolutionary considerations for defining functioning of microbial endophytes

The diversity and distribution of endophytes across biomes, plant phylogeny and host tissues: how far have we come and where do we go from here

Transfer of carbohydrate-active enzymes from marine bacteria to Japanese gut microbiota

Bacteria present in Comadia redtenbacheri larvae (Lepidoptera: Cossidae)

Revealing the gut bacteriome of Dendroctonus bark beetles (Curculionidae: Scolytinae): diversity, core members and co-evolutionary patterns

Molecular characterization of coprophilous fungal communities reveals sequences related to root-associated fungal endophytes

Antibiotic resistance gene spread due to manure application on agricultural fields

Healthy soils for healthy plants for healthy humans: How beneficial microbes in the soil, food and gut are interconnected and how agriculture can contribute to human health

A leaf-inhabiting endophytic bacterium, Rhodococcus sp. KB6, enhances sweet potato resistance to black rot disease caused by Ceratocystis fimbriata

Evidence of environmental and vertical transmission of Burkholderia symbionts in the oriental chinch bug, Cavelerius saccharivorus (Heteroptera: Blissidae)

Diversity of cultivable actinomycetes in 6 species of herbivore feces

Bamboo nutrients and microbiome affect gut microbiome of giant panda

Population structure, density and movements of the Texas tortoise Gopherus berlandieri

Development and validation of a microarray for the investigation of the CAZymes encoded by the human gut microbiome

Comparison of the gastrointestinal anatomy, physiology, and biochemistry of humans and commonly used laboratory animals

Characterization of a novel galactan produced by Weissella confusa KR780676 from an acidic fermented food

Symbiont mediated insecticide resistance

Insect-microbe mutualism without vertical transmission

An ancient but promiscuous host-symbiont association between Burkholderia gut symbionts and their heteropteran hosts

Oral administration of Lactobacillus plantarum strain AYA enhances IgA secretion and provides survival protection against influenza virus infection in mice

Symbiotic factors in Burkholderia essential for establishing an association with the bean bug, Riptortus pedestris

Impact of increasing fruit and vegetables and flavonoid intake on the human gut microbiota

Effect of nursing methods and faeces consumption on the development of the bacteroides, lactobacillus and coliform flora in the caecum of the newborn rabbits

Putative probiotic Lactobacillus spp. from porcine gastrointestinal tract inhibit transmissible gastroenteritis coronavirus and enteric bacterial pathogens

Bacterial tannases: classification and biochemical properties

Bacterial communities associated with the surfaces of fresh fruits and vegetables

Engineered symbionts activate honey bee immunity and limit pathogens

Evolution of mammals and their gut microbes

Plants in the pink: cytokinin production by Methylobacterium

Exploration of a-pinene degradation pathway of Pseudomonas rhodesiae CIP 107491. Application to novalic acid production in a bioreactor

Flow of resistance genes in the environment and from animals to man

Characteristics and diversity of endophytic bacteria in moso bamboo (Phyllostachys edulis) based on 16S rDNA sequencing

Phaseolus vulgaris seed-borne endophytic community with novel bacterial species such as Rhizobium endophyticum sp

Complete genome Ssquence of Klebsiella variicola strain HKUOPLA, a cellulose-degrading bacterium isolated from giant panda feces

Complete genome sequence of Klebsiella pneumoniae Strain HKUOPLC, a cellulose-degrading bacterium isolated from giant panda feces

Mutualistic fermentative digestion in the gastrointestinal tract: diversity and evolution

The immunomodulatory effects of probiotics on respiratory viral infections: a hint for COVID-19 treatment? Microbial Pathogenesis 148: 104452

The impact of dietary fiber on gut microbiota in host health and disease

The evolution of insect-fungus associations: from contact to stable symbiosis

Agave seed endophytes: Ecology and impacts on root architecture, nutrient acquisition, and cold stress tolerance

Klebsiella variicola and Klebsiella quasipneumoniae with capacity to adapt to clinical and plant settings

Bacterial adaptation to the host's diet is a key evolutionary force shaping Drosophila-Lactobacillus symbiosis

D-Alanylation of teichoic acids contributes to Lactobacillus plantarum-mediated Drosophila growth during chronic undernutrition

Tropical forests are both evolutionary cradles and museums of leaf beetle diversity

Diversity and distribution of the endophytic bacterial community at different stages of Eucalyptus growth

Wheat endophytic lactobacilli drive the microbial and biochemical features of sourdoughs

Nitrogenfixing Klebsiella variicola in feces from herbivorous tortoises

A review of feeding and diet selection in koalas

Antiherbivore chemistry of Eucalyptus-cues and deterrents for marsupial folivores

Nitrogen-fixing and uricolytic bacteria associated with the gut of Dendroctonus rhizophagus and Dendroctonus valens

Glyphosate perturbs the gut microbiota of honey bees

Diet drives convergence in gut microbiome functions across mammalian phylogeny and within humans

Fungal evolution: major ecological adaptations and evolutionary transitions

The endophyte Enterobacter sp. FD17: a maize growth enhancer selected based on rigorous testing of plant beneficial traits and colonization characteristics

Depolymerizating enzymes-cellulases

Comparative cytology, physiology and transcriptomics of Burkholderia insecticola in symbiosis with the bean bug Riptortus pedestris and in culture

Isolation and characterization of endophytic bacteria isolated from the leaves of the common bean

Tannin-protein complex-degrading enterobacteria isolated from the alimentary tracts of koalas and a selective medium for their enumeration

Microbiological studies of the intestinal microflora of the koala, Phascolarctos-cinereus. 1. Colonization of the cecal wall by tannin-protein-complex-degrading enterobacteria

Microbiological studies of the intestinal microflora of the koala, Phascolarctos-cinereus. 2. Pap, a special maternal feces consumed by juvenile koalas

A randomized synbiotic trial to prevent sepsis among infants in rural India

A new endophytic insect-associated Daldinia species, recognised from a comparison of secondary metabolite profiles and molecular phylogeny

Modulation of the honey bee queen microbiota: effects of early social contact

Isolation and characterization of bacteria from the gut of Bombyx mori that degrade cellulose, xylan, pectin and starch and their impact on digestion

Diversity, abundance, and persistence of antibiotic resistance genes in various types of animal manure following industrial composting

From sample to Multi-Omics conclusions in under 48 hours

Molecular phylogeny of the genus Dactylopius (Hemiptera: Dactylopiidae) and identification of the symbiotic bacteria

Gut and root microbiota commonalities

Probiotic Lactobacillus strains from Mongolia improve calcium transport and uptake by intestinal cells in vitro

Enzyme-producing bacteria isolated from fish gut: a review

Pathogenicity of Serratia marcescens strains in honey bees

The role of the gut microbiome in health and disease of adult honey bee workers

Intestinal short chain fatty acids and their link with diet and human health

From structure to function: the ecology of host-associated microbial communities

Robustness of the bacterial community in the cabbage white butterfly larval midgut

Novel consortium of Klebsiella variicola and Lactobacillus species enhances the functional potential of fermented dairy products by increasing the availability of branched-chain amino acids and the amount of distinctive volatiles

Endosymbiotic microorganisms of scale insects

Klebsiella variicola, a novel species with clinical and plant-associated isolates

Bacterial endophytes and their interactions with hosts

Evolutionary relationships of flavobacterial and enterobacterial endosymbionts with their scale insect hosts (Hemiptera: Coccoidea)

Environment dominates over host genetics in shaping human gut microbiota

Molecular signatures and phylogenomic analysis of the genus Burkholderia: Proposal for division of this genus into the emended genus Burkholderia containing pathogenic organisms and a new genus Paraburkholderia gen. nov. harboring environmental species

The cellulosome and cellulose degradation by anaerobic bacteria

Complete mitochondrial genome recovered from the gut metagenome of overwintering monarch butterflies, Danaus plexippus (L.) (Lepidoptera: Nymphalidae, Danainae)

Draft genome sequence of Commensalibacter papalotli MX01, a symbiont identified from the guts of overwintering monarch butterflies

The internal bacterial diversity of stored product pests

Uncovering the microbiome of invasive sympatric European brown hares and European rabbits in Australia

Symbiont-derived antimicrobials contribute to the control of the Lepidopteran gut microbiota

The whole-genome sequence analysis of Enterobacter cloacae strain Ghats1: insights into endophytic lifestyle-associated genomic adaptations

The microbiome of Eucalyptus roots under different management conditions and its potential for biological nitrogen fixation

Multifarious activities of cellulose degrading bacteria from Koala (Phascolarctos cinereus) faeces

A study of the bacteria associated with thirty species of insects

Lactobacillus plantarum promotes Drosophila systemic growth by modulating hormonal signals through TOR-dependent nutrient sensing

Drosophila perpetuates nutritional mutualism by promoting the fitness of its intestinal symbiont Lactobacillus plantarum

Evolutionary transition in symbiotic syndromes enabled diversification of phytophagous insects on an imbalanced diet

Insecticide-degrading Burkholderia symbionts of the stinkbug naturally occupy various environments of sugarcane fields in a

Genomic comparison of insect gut symbionts from divergent Burkholderia Subclades

Burkholderia of plant-beneficial group are symbiotically associated with bordered plant bugs (Heteroptera: Pyrrhocoroidea: Largidae)

Roseburia spp.: a marker of health

The players may change but the game remains: network analyses of ruminal microbiomes suggest taxonomic differences mask functional similarity

Introduction to the human gut microbiota

Applied evolutionary ecology of insects of the subfamily Bruchinae (Coleoptera: Chrysomelidae)

Microbial diversity and evidence of novel homoacetogens in the gut of both geriatric and adult giant pandas (Ailuropoda melanoleuca)

The measurement of liquid and solid digesta retention in ruminants, equines and rabbits given timothy (Phleum pratense) hay

Rabbit microbiota changes throughout the intestinal tract

Comparative analysis of the gut bacterial community of four Anastrepha fruit flies (Diptera: Tephritidae) based on pyrosequencing

Candidatus Dactylopiibacterium carminicum, a nitrogen-fixing symbiont of Dactylopius Cochineal insects (Hemiptera: Coccoidea: Dactylopiidae)

Antibiotic resistance and multidrug-resistant efflux pumps expression in lactic acid bacteria isolated from pozol, a nonalcoholic Mayan maize fermented beverage

In vitro colonic fermentation of dietary fibers: Fermentation rate, short-chain fatty acid production and changes in microbiota

An apple a day: which bacteria do we eat with organic and conventional apples? Front Microbiol 10: 1629

The microbial community in the feces of the giant panda (Ailuropoda melanoleuca) as determined by PCR-TGGE profiling and clone library analysis

Diverse antibiotic resistance genes in dairy cow manure

Dietary shifts affect the gastrointestinal microflora of the giant panda (Ailuropoda melanoleuca)

Metagenomic sequencing of diamondback moth gut microbiome unveils key holobiont adaptations for herbivory

An endophytic Coniochaeta velutina producing broad spectrum antimycotics

Environmental transmission of the gut symbiont Burkholderia to phloem-feeding Blissus insularis

Impacts of antibiotic and bacteriophage treatments on the gut-symbiont-associated Blissus insularis (Hemiptera: Blissidae)

The bamboo-eating giant panda harbors a carnivore-like gut microbiota, with excessive seasonal variations

Are the gut microbial systems of giant pandas unstable? Heliyon

Kinship, inbreeding and fine-scale spatial structure influence gut microbiota in a hindgut-fermenting tortoise

Diverse bacteria associated with root nodules of spontaneous legumes in Tunisia and first report for nifH-like gene within the genera Microbacterium and Starkeya

Environmental analysis of typical antibiotic-resistant bacteria and ARGs in farmland soil chronically fertilized with chicken manure

Division of labor in honey bee gut microbiota for plant polysaccharide digestion

Evidence of cellulose metabolism by the giant panda gut microbiome

Potential mechanism of detoxification of cyanide compounds by gut microbiomes of bamboo-eating pandas

Personalized gut mucosal colonization resistance to empiric probiotics is associated with unique host and microbiome features

This work was supported by grants from the National University of Mexico to EMR IN210021 and to LES-G (PAPIIT-DGAPA IA208019) to study the monarch microbiota. We thank Rosendo Antonio Caro Gomez and Felipe Martinez at the Monarch Butterfly Biosphere Reserve (MBBR) in Mexico and Ministry of Environment and Natural Resources of Mexico for the permits for monarch samplings. We thank M. Dunn for critically reading the manuscript.