Abstract
Wild animals may encounter multiple challenges especially food shortage and altered diet composition in their suboptimal ranges. Yet, how the gut microbiome responds to dietary changes remains poorly understood. Prior studies on wild animal microbiomes have typically leaned upon relatively coarse dietary records and individually unresolved fecal samples. Here, we conducted a longitudinal study integrating 514 time-series individually recognized fecal samples with parallel fine-grained dietary data from two Skywalker hoolock gibbon (Hoolock tianxing) groups populating high-altitude mountainous forests in western Yunnan Province, China. 16S rRNA gene amplicon sequencing showed a remarkable seasonal fluctuation in the gibbons’ gut microbial community structure both across individuals and between the social groups, especially driven by the relative abundances of Lanchnospiraceae and Oscillospiraceae associated with fluctuating consumption of leaf. Metagenomic functional profiling revealed that diverse metabolisms associated with cellulose degradation and short-chain fatty acids (SCFAs) production were enriched in the high-leaf periods possibly to compensate for energy intake. Genome-resolved metagenomics further enabled the resolving metabolic capacities associated with carbohydrate breakdown among community members which exhibited a high degree of functional redundancy. Our results highlight a taxonomically and functionally sensitive gut microbiome actively responding to the seasonally shifting diet, facilitating the survival and reproduction of the endangered gibbon species in their suboptimal habitats.
Similar content being viewed by others
Introduction
Human activities significantly affected the survival and reproduction of wild animals1,2,3,4. In particular, human activities may lead to the shrinking back of wildlife habitats, with many of the populations being constrained in the margins of their original natural ranges5,6,7. In these suboptimal habitats, wild animals face more challenges for survival, including especially food shortage and low-temperature conditions. To cope with these challenges, wild animals may evolve to have behavioral8,9 and physiological adaptations including dietary alterations10. Importantly, as the digestive system could not catch up to the fast-changing environment, the rapid response of gut microbiota and associated metabolic activities may represent a key mechanism enabling the adaptation of their hosts to suboptimal habitats11,12. While recent surveys have suggested that plasticity in gut microbiota may provide dietary and metabolic flexibility to animals13,14,15, longitudinal studies were lacking to systematically investigate how gut microbiome responds to seasonally fluctuating diets for wild animals in their new, non-native ranges.
The investigation of temporal gut microbiome dynamics in wild animals faced multiple difficulties, especially in habituation and individual recognization of animals, long-term monitoring of dietary composition, and collection of fresh fecal samples resolved at the individual level. These aspects were even more challenging when studying tree-dwelling animals in natural settings. Here, we overcame these challenges by adopting a pioneering strategy in which full-day dietary data were recorded and parallel fresh feces were collected for six habituated and individually recognizable wild skywalker hoolock gibbons the newly described and endangered species Hoolock tianxing16,17, from two family groups for over a year. As typical frugivorous animals originally mainly residing in the tropics, skywalker hoolock gibbons have less developed cecum and relatively round molar crowns that are not adapted to ground and digest fibrous plant materials (e.g., leaves)16,18. However, as affected by human activities, the distribution area of wild gibbons has been shrinking back, with some of the remaining populations restricted in high-altitude mountainous forests in western Yunnan Province, China, and eastern Myanmar, which represent the northernmost margin of global gibbon species distribution16.
Consequently, these gibbons experienced drastic seasonal fluctuations in dietary composition and were forced to shift to a diet mainly of leaves when fruits were not available during the coldest months of the year19. This feature renders them an ideal target for exploring the potential linkage and underlying mechanisms between seasonal diet variations and gut microbial communities of wild animals. We generated an exceptionally massive longitudinal dataset, containing 16S rRNA gene amplicon and metagenomic sequences, to comprehensively investigate the potential adaptive strategies of the gut microbiome to the seasonally fluctuating food resources in two gibbon groups. Our analyses revealed dynamic microbiomes sensitive to drastic diet changes, stressing the individual-specific responses of the microbial community at both the taxonomic and metabolic functional levels. Such insights are crucial for understanding how these wild animals survive and adapt to new and stressful environments.
Results
The gibbon gut microbiota profile
To investigate the potential longitudinal relationship between diet and gut microbiota, we collected dietary data and 514 fresh fecal samples from six individual gibbons (two social groups) over the course of 15 months. Deep 16S rRNA gene V4 amplicon sequencing identified a total of 6750 zero-radius operational taxonomic units (ZOTUs), which were assigned to 943 genera and 42 phyla. 299 ZOTUs (4.6% of the total) were present in at least 90% of the samples, constituting the “core microbiota” of the gibbon gut microbial community (Supplementary Table 1). At the phylum level, the overwhelming majority (70–90%; Fig. 1b and c) of microbes were affiliated with the Firmicutes and Bacteroidota, with the remainder largely belonging to the Actinobacteriota and Proteobacteria. At the family level (Fig. 1d and e), the most abundant families included Prevotellaceae (27.2 ± 9.9%), Acholeplasmataceae (20.0 ± 10.2%), Erysipelatoclostridiaceae (13.5 ± 6.5%), and Lachnospiraceae (11.1 ± 4.3%). Strikingly, nearly all Acholeplasmataceae sequences were assigned to a single ZOTU (ZOTU1), accounting for 19.8% of the total community. Additionally, the most abundant archaeal species (from the phylum Crenarchaeota) exhibited a high level of prevalence (detected in all samples), although at a low relative abundance.
a Home ranges of two social groups Nankang (orange, NK) and Banchang (purple, BC) during sample collection. b–e Relative abundances of phyla (b NK; c BC) families (d NK; e BC). Samples were sorted by the sampling time. Each column represented one sample and samples from different months were separated by the blank space. Significance was calculated by the Wilcoxon rank-sum test with samples classified by social groups.
Influence of social group on the microbiota structure
While the overall taxonomic composition of the gut microbiota in both social groups was generally similar, relative abundances of some specific taxa (phylum, family, and genus levels) showed significant differences (Fig. 1 and Supplementary Fig. 1, Wilcoxon rank-sum test, p < 0.05). Notably, alpha diversity indexes (Shannon diversity, evenness, observed richness, and Faith’s phylogenetic diversity) were significantly higher in the NK group (Wilcoxon rank-sum test, p < 0.001; Supplementary Fig. 2a–d), indicating a more diversified microbiota. The clear separation of gut microbiota by social groups was confirmed by the Bray–Curtis dissimilatory (Supplementary Fig. 2e, ANOSIM; R2 = 0.67, p = 0.001).
SIMPER (similarity percentages procedure) analysis was conducted to identify the specific taxa that contributed to the differentiation of microbial communities in the two gibbon groups (Supplementary Table 2). Characteristic ZOTUs presented at an explicitly higher relative abundance in the NK group included ZOTU5 (family Prevotellaceae, with a contribution of 3.4%), ZOTU3 (Rikenellaceae, 1.8%), and ZOTU7 (Lachnospiraceae, 1.4%), whereas other ZOTUs (including the Anaeroplasma ZOTU1 with the highest abundance) were apparently more abundant in the BC gibbons.
Covariation of diet and gut microbiota across social groups and individuals
Fine-grained observational dietary data were applied to investigate how seasonal diet variation may affect gibbon gut microbiota. Hierarchical cluster analysis showed a clear separation of dietary composition into the high-fruit (HF) period and high-leaf (HL) periods (Fig. 2a and b). Notably, a consistent response of gut microbiota to dietary changes across social groups was observed albeit with significant differences in microbial community structure (Fig. 2). Specifically, Shannon diversity and evenness were significantly increased with the proportion of leaves and decreased with that of fruits (Supplementary Fig. 3a–d, p < 0.001, Linear regression analysis) in two gibbon groups, while the significance for the observed richness and Faith’s phylogenetic diversity was only detected in the NK group (Supplementary Fig. 3e–h). Besides, microbial community dissimilarity increased with dietary dissimilarity within each social group (Supplementary Fig. 4). Meanwhile, the first principal component of beta diversity which was largely related to diet composition, accounted for 14.0% and 15.6% of the variation in the two social groups (Fig. 2c). All ZOTUs that loaded negatively on PC1 (more abundant during the HL periods) were assigned as Lachnospiraceae in both gibbon groups (Fig. 2e and f). In contrast, the ZOTUs that loaded positively on PC1 (more abundant during the HF periods) belonged to the family Prevotellaceae in the NK group, and primarily the families Ruminococcaceas and Lachnospiraceae in the BC group (Fig. 2e and f). SPIEC-EASI co-occurrence networks were further constructed to explore how diet impacted species interactions and the structure of the gut microbial community. The results showed that the gut microbial networks varied considerably over diet. Both gibbon groups exhibited similar increases in the size of networks with more nodes and links along the amount of fiber consumed, albeit only statistically significant in the BC group (Fig. 3). Meanwhile, increasing average degree and edge connectivity were also associated with increased fiber consumption, indicating that the microbial networks became more complex and connective during periods of high fiber availability. Additionally, average path length showed a significantly decreasing trend from the fruit-dominated diet to the leaf-dominated diet for both social groups.
a and b Hierarchical clustering with the dietary composition of the social groups (a NK; b BC). Detailed information was provided in Supplementary Table 7. c The correlation between the first principal component (PC1) of between-sample dissimilarity and the proportion of leaf in the diet with colors representing different subjects (orange, NK; purple, BC). The p-values were obtained from linear regression analysis. d Gut microbial composition of NK and BC social groups in the high-fruit and high-leaf periods (the dominant families were shown). e and f Loading PC1 scores of each ZOTU within social groups (e, NK; f, BC) with a loading score of >0.05 and <0.05 highlighted.
The separation of microbial communities of the six gibbons along the first NMDS axis (Fig. 4a) indicated gut microbiota varied widely across individuals. To gain deeper insight into this pattern, Procrustes analysis was performed to explore microbiota variation and dietary variation across individuals. The results showed that an individual’s daily dietary composition generally corresponded with its microbiota composition (Supplementary Fig. 5, Monte Carlo p-value = 0.001). Consistently, a significant positive correlation between the degree of seasonal turnover in diet and microbiota composition across individuals was observed. Overall, the variance in microbiota turnover could be primarily (49–62% of variance) explained by diet turnover (Supplementary Fig. 6). Furthermore, the Spearman correlation was conducted to determine which taxa varied monotonically with an increasing proportion of leaves or fruits in diet across individuals (Supplementary Table 3). The result showed that ZOTUs with significant correlations (false discovery rate < 0.05) with diet types (fruit or leaf) were relatively personalized, indicating that the diet-sensitive ZOTUs were not always conserved across individuals (Fig. 4b; but see Supplementary Fig. 7 for the seven examples with common response). Notably, the ZOTUs of leaf response had an obvious richness and phylogenetic diversity than those of fruit response (Fig. 4b and c) and, when adopting more strict thresholds (Spearman’s correlation r > 0.6; FDR-corrected p-value < 0.01), they were always conserved at the family level. Specifically, Lachnospiraceae and Oscillospiraceae represented the main leaf response taxa, while microbes of fruit response were almost exclusively affiliated with Prevotellaceae.
a NMDS (center panel) of the Bray–Curtis dissimilarity based on the microbial community composition. Different colors corresponded to different gibbon individuals in the top panel. Boxplots (top panel) indicated the distribution of each individual along the first axis of NMDS. The boxplots on the left panel depicted different diet types according to their gut microbial community placement on the second axis of NMDS. Different letters represented significant differences (ANOVA followed by Duncan’s test). b The number of the diet-specific responsive ZOTUs. Colors indicated the types of responsive ZOTUs (yellow, responding to fruit; blue, responding to leaf). c Within-individual correlations between diet and the relative abundances of ZOTUs (Spearman’s correlation r > 0.6; FDR-corrected p-value < 0.01). The colored circles in the middle represented different gibbon individuals. The tree outside was obtained by 16S rRNA gene sequences, and the colors represented diverse microbial families. The lines with different colors indicated the types of responses.
Functional responses of gut microbiota to dietary changes
To obtain a deeper insight into the observed association between gut microbiota and diet changes, we generated 3.27 T of metagenomic sequence data from the 99 fecal samples of gibbons A2 and B2 (representing the NK and BC groups, respectively, mean: 27.7 ± 2.9 Gb). A total of 3,906,912 putative protein-coding genes were predicted, of which 39.5% could be annotated in the KEGG database (Supplementary Fig. 8a and b) and 2.2% annotated as carbohydrate-active enzymes (CAZymes, Supplementary Fig. 8c and d). More than half (51.9%) of the genes could not be assigned to known functions.
The clustering patterns of the metagenomic functional profiles of the two gibbons demonstrated a clear covariation between gut microbial community functions and dietary types (Supplementary Fig. 8e and f). The core KO categories were further examined to identify the significantly represented pathways associated with the different diet periods (Supplementary Fig. 9). Compared with the high-fruit (HF) periods, a considerably wider range of KEGG pathways, including membrane transport, carbohydrate metabolism-, and energy metabolism-related KO categories were enriched during high-leaf (HL) periods in both gibbon individuals (Supplementary Fig. 9; p < 0.05, Fisher’s exact test). Specifically, enrichment in specific pathways involved in complex carbohydrates degradation, including cellulolytic (endoglucanase and 6-phospho-beta-glucosidase) and dextran-lytic (dextranase and oligo-1,6-glucosidase) enzymes were clearly evidenced, suggesting enhanced capacities for nutrient digestion and utilization. Additionally, the increased relative abundances of cellular energy metabolisms (especially V/A type ATPase, Fig. 5) during the HL periods may provide additional energy to host in nutrient-depleted conditions. Similar trends of genes for volatile SCFAs production (e.g., butyrate, acetate, and lactate) were observed during the HL periods, particularly in A2 (Fig. 5). Notably, some other pathways were found to be uniquely enhanced in the A2 gibbon; these included the Embden–Meyerhof–Parnas (EMP) glycolysis pathway, histidine metabolism, acylglycerol degradation, and cell motility during the HL periods and the riboflavin synthesis pathway, Complex I and II during HF periods (Fig. 5).
The diagrams showed metabolic pathways enriched during high-leaf (left) and during high-fruit (right). The colors of different solid lines corresponded to significantly differential metabolic pathways (Wilcoxon rank-sum test, and FDR-corrected p-value < 0.05). The genes with no significant difference between the two diets were marked with gray lines. The detailed information on the genes was summarized in Supplementary Table 9.
The predicted protein-coding genes were mapped to the CAZymes database to further resolve the complex carbohydrate utilization in the gut microbiome. Nearly half of the genes with CAZymes annotation were assigned as glycoside hydrolases (GHs, 46.8 ± 2.1%), including the digestion of oligosaccharides (25.3 ± 2.9%), hemicellulose (16.6 ± 2.7%), starch (12.8 ± 1.7%), cellulose (5.5 ± 0.9%), and pectin (4.3 ± 1.8%). Again, apparent separation of CAZymes profiles along the diets was observed for both gibbon individuals (Supplementary Fig. 8g and h). Notably, genes related to cellulose and hemicellulose degradation enzymes were enriched during HL periods either in B2 (e.g., GH8, GH74, GH98, GH124) or in A2 (GH8) (Fig. 6a and b). Meanwhile, the amylase-encoding GH13 was found to be significantly over-represented in A2 during the same periods (Fig. 6c and d). Taxonomic assignment showed that these HL-associated CAZymes genes mainly belonged to the Lachnospiraceae, Oscillospiraceae, Eubacteriaceae, and Prevotellaceae, indicating critical roles of these taxa in fiber digestion and utilization in the gibbon gut ecosystem.
a and b Heatmap of the CAZymes profile in the gibbon gut metagenomes (a A2; b B2). CAZymes associated with cellulase, hemicellulase, pectinase, debranching enzymes, amylases, and oligosaccharide degradation were presented. CAZymes families with significant enrichment (Wilcoxon rank-sum test, and FDR-corrected p-value < 0.05) in the leaf- and fruit-dominated periods were marked. The standardized relative abundances of each CAZymes family were shown. c and d Sankey diagram describing the distribution of the top 10 microbial families associated with all selected CAZymes families ranked by the number of genes in gibbons A2 (c) and B2 (d). CAZymes were represented by different colors according to functional types and microbes were colored according to the associated families. The heights of the rectangles indicated the numbers of the CAZymes (left) and microbial species (right). The detailed information on the genes was summarized in Supplementary Table 10.
Given the individual-dependent responses of the gut microbial populations to the diet, an additional set of samples for the other four gibbon subjects within the typical dietary periods were further selected for metagenomic sequencing. Metagenomic analysis of the 38 representative fecal samples revealed generally similar clustering patterns of overall community function and CAZymes profiles shaped by diet variation (Supplementary Fig. 10) and identified additional KOs (especially those associated with pathways in membrane transport, signal transduction, carbohydrate metabolism, and energy metabolisms, Supplementary Fig. 10c and e) and CAZymes (Supplementary Fig. 10d) enriched in HL periods.
Resolving carbohydrate degradation and fermentation metabolism at the MAGs level
To further resolve the connection between community members and functional capacities, 13,388 prokaryotic genomes were assembled from 138 fecal metagenomes. The metagenome-assembled genomes (MAGs) were then dereplicated into 569 representative genomes at the species level. Compared with the high-fruit periods, a higher richness and phylogenetic diversity of MAGs were enriched during the high-leaf periods, resembling patterns of the 16S rRNA-based analysis (Supplementary Table 4). We then focused on these differentially enriched MAGs to explore the capability of interconnected microbial functional guilds to convert plant polysaccharides into soluble sugars. For this purpose, the genomes were assigned to the different trophic levels along the carbon food chain inferred from the linkages to specific substrates, including (1) complex carbohydrate polysaccharides, (2) sugar utilization, and (3) sugar fermentation.
A degradation potential of a large number of complex carbohydrate polysaccharides (including cellulose, hemicellulose, and starch) was identified in the reconstructed Lachnospiraceae, Acutalibacteraceae, Borkfalkiaceae, and Ruminococcaceae MAGs (Fig. 7 and Supplementary Fig. 11). The cellulose decomposition ability of the majority of these taxa could be inferred by the detection of cellulase families GH5, GH8, GH9, and GH45, of which GH5 was the most common (Supplementary Table 4). Notably, GH48 was only detected in a Ruminococcaceae MAG (B055_bin_86), indicating a potential for degradating cellulose while also possessing cohesion and dockerin domains associated with cellulosomes (Supplementary Table 5). In addition, the vital roles of these enriched taxa in starch and glucan biodegradation could be reflected by the wide detection of amylase and β-glucosidase (Supplementary Table 5). The distribution of the potentials of the next-level substrates, including rhamnose, mannose, fructose, galactose, fucose, and glucose, was similar to that of the complex sugar, stressing a metabolic versatility of gut populations. Notably, the genes for the utilization of a large number of substrates (12 or more) co-occurred in these enriched taxa (Supplementary Fig. 11), which may serve as metabolic hubs providing highly diversified capabilities to cope with polymer degradation in the gibbon gut. Unlike the two trophic levels above, the third one was composed of a limited number of SCFA producers, with the utilization of acetate and lactate contributing the most. The major butyrate and propionate fermenters were assigned to Lachnospiraceae, and the potential of succinate fermentation was scatteredly distributed in only four MAGs within the families Burkholderiaceae, Lachnospiraceae, Bacteroidaceae, and UBA932.
Heatmap indicated the proportions of MAGs with the abilities for major polysaccharides degradation, sugar utilization, and fermentation. The MAGs were summarized into family-level taxonomic clades based on the phylogeny inferred by GTDB-Tk. Functional profiles were reconstructed inferred from the presence of the key marker genes within the metabolic pathway. Detailed information was provided in Supplementary Table 5.
Discussion
To investigate the potential impacts of seasonal dietary variation on gut microbiota, recent works typically collected and analyzed fecal samples left behind by a specific social group of wild animals14. Thus, our direct sampling of fresh and individually resolved feces from the wild gibbons, coupled with parallel time series feeding data, represented a major step forward, enabling insights into the gut microbiome and dynamics of this endangered primate species.
By integrating the simultaneously collected fine-grained dietary data, we demonstrated that the gibbon gut microbiome was driven by the shifting dietary modes associated with the seasonal availability of resources. Different subjects responded to the seasonal diet variations in a similar way, despite considerable differences in their gut microbial community structure. Moreover, gibbons with more dissimilar diets also had more dissimilar microbiomes, and the variation of microbiome turnover could be largely explained by dietary turnover within each subject (explainable variation ranging from 49% to 62%, Supplementary Fig. 6), which is significantly higher than those previously reported for large-herbivore species in African20. A possible explanation was that we quantified diet and microbiome composition precisely for each gibbon individual, thus eliminating the effect of host lineage on their potential linkages. Notably, elevated microbiota alpha diversity (richness and evenness) and the number of KOs were detected with increased intake of plant fiber, possibly mirroring a need for more diverse microbial populations for a hard-to-digest diet21,22. This result was expected since the transformation of complex substrates into end products is typically accomplished through a number of metabolic stages mediated by inter-connected microbial groups23,24,25.
With the functional versatility encoding in many different MAGs, the metabolic repertoires of the gibbon gut microbiome exhibited a high degree of redundancy, which may provide functional plasticity and stability during dietary changes. Specifically, when a given taxon is compromised in suboptimal conditions, the niche could be supplemented by other functionally similar counterparts enabling a buffering against environmental perturbations at the community level26. Such a feature has been documented in rumen animals and human microbiomes27,28,29, where phylogenetically diversified functional guilds could maintain overall metabolic activities and growth under a wide range of environmental conditions including dietary fluctuations. The functional redundancy also led to an enhanced species competition stress among the microbial interactions during the high-leaf periods (Supplementary Fig. 12). The crucial role of competition in maintaining microbial species diversity and stabilizing microbial community composition has been stressed30, which reflects the potential of recovering the original state from internal or external disturbances. This stability may be essential to host health, as the maintenance of beneficial microbial symbionts and their associated functions in the gut is ensured over time26,31,32,33.
Recent investigations have suggested that some microbial taxa or metabolic pathways may respond to specific dietary compounds in humans34. In the present study, we observed highly positive correlations between increased leaf intake and relative abundances of certain bacterial taxa (e.g., Lachnospiraceae and Oscillospira), indicating a pivotal role of these microbes in fiber degradation in the gibbon gut. This finding was reasonable since Lachnospiraceae spp. are the main cellulolytic taxa in the mammalian gut13,35,36,37, producing short-chain fatty acids in the cellulolytic processes, and bacteria from the family Oscillospira have been found highly prevalent in cattle and sheep rumen38, and their relative abundance was associated with seasonal diet variation in the wild wood mice39. The metagenome-derived functional profiles showed that Lachnospiraceae and Oscillospira harbored various functional CAZymes involved in cellulose and hemicellulose degradation (Fig. 6c and d), supporting these taxa as keystone species for utilizing high-fiber food in the wild gibbons. On the other hand, Prevotella, which is capable of digesting non-cellulosic polysaccharides, pectin, and soluble sugars as energy sources40,41, was markedly enriched in the gibbon gut microbiota during periods of high-fruit availability. Similar results have been previously reported in western lowland gorillas14,42 and geladas13.
The role of gut microbiota in the host adaptation to dietary variation could also be reflected in the synergistic actions in community function profiles. Our metagenomic analysis revealed that diverse genes involved in cellulose and hemicellulose breakdown (e.g., endoglucanase, GH8, and GH124) were significantly enriched in HL periods, indicating efficient metabolic capabilities for the sequential conversion of these depolymerized polysaccharides into glucose. The high functional potential to produce SCFAs (such as butyrate, acetate, and lactate) in the HL metagenomes may imply compensation for energy intake efficiency by microbial fermentation. In support of this, previous studies have demonstrated that volatile SCFAs not only provide a substantial fraction of the daily energy supply for folivorous primates, sheep, and cattle43,44,45 but also are crucial in anti-inflammation and improving immunity46. Thus, our findings indicated a flexible functional configuration of the gibbon gut microbiota to obtain energy through fermentation to SCFAs or conversion to glucose suggesting a microbiome adaptive to the utilization of complex cellulose. In comparison, the overall gut microbiota function was more constrained and reflected a diet high in soluble sugars during HF periods (Fig. 5). Notably, our metagenomic analysis uncovered that the riboflavin (vitamin B2) synthesis pathway was significantly elevated in the HF periods (Fig. 5 and Supplementary Fig. 10), indicating its important role in the gibbon gut microbial community as riboflavin is critical in cellular metabolism and is involved in the carbohydrate, amino acids, and energy-producing metabolisms47,48.
In humans, altering the availability of diet has been found to change the taxonomic composition and functional profiles of the gut microbiome, resulting in intestinal health problems such as obesity and autoimmune disease49,50,51. In this study, we observed an increase in the relative abundance of Heliobacter (Supplementary Fig. 13), a potential pathogen genus that infects humans and other vertebrates52,53, during the shift from a fruit-dominated diet to a fibrous diet. This result was consistent with prior studies which reported an increase of potentially pathogenic microbes with fruit availability possibly due to more nutritional stresses during fruit scarcity37,54. Additionally, we found that two beneficial commensal genera, Bifidobacterium and Lactobacillus, were also negatively correlated with fruit availability. We anticipated that these genera would provide a balance for the gibbons to maintain healthy gut homeostasis. Understanding the balance between diet transmissions of pathogenic versus beneficial bacteria may thus provide a new approach to monitoring the health of wild animals.
Increasing evidence shows that the properties of co-occurrence networks may reflect interactions between co-existing taxa which could affect the gut microbial community’s response to host/environment-associated variables55,56. Furthermore, previous studies have reported resource and food availability as the key factor shaping the social network structures of gut microbiota57,58. Our results showed that the gibbon gut microbiome networks responded similarly to the shifting diet in the two social groups, with a stronger impact of diet observed in the BC group. Compared to the microbial network associated with a fruit-rich diet, the fiber-rich diet network was larger in size and relatively complex, indicating more mutualistic interactions, guilds, or niches sharing among microorganisms59,60. These results suggested that, in order to obtain adequate energy from energy-poor fibrous materials, a more diverse microbial community with a more complex network of metabolic interdependencies to ferment the low nutrients into SCFAs is required for the wild gibbons. In principle, these complex microbial social networks may provide the gibbon hosts with dietary flexibility, allowing maximized energy extraction and thus improved fitness.
Our massive 16S rRNA gene and metagenomic data sets have revealed dynamic gibbon gut microbiomes sensitive to seasonal dietary changes. Such a community is compositional and functional responses were largely personalized, resulting in a gut microbiota better predicted at the individual level than at the whole sample level (Fig. 8; see also Supplementary Table 6). The comprehensive set of genomes assembled from the metagenomes has further enabled resolving the metabolic capacities associated with carbon degradation among different community members. Future studies are needed to utilize these MAGS to investigate how other important functions are partitioned in the community and how taxa interact, either competitively or cooperatively, in response to the fluctuating diet. Given the critical importance of gut microbiota to wild animals, a comprehensive mechanistic understanding of its temporal dynamics and functional consequences in Skywalker hoolock gibbons will ultimately contribute to the development of effective conservation strategies to help this endangered species adapt to their new, suboptimal habitats.
The comparison of cross-validation results (a–c) and prediction accuracies (d–f) between different biotic levels in different sampling scales. a–c Scatter plots showing the predicted and observed values of relative abundances of different biotic levels inferred from dietary compositions. Colors represented different biotic levels (dark gray: phylum; light gray: family; black: ZOTU). The diagonal line represented perfect prediction (predicted value = observed value). d–f The accuracy of random forest models in predicting relative abundances in different taxa. Significant differences among different datasets were denoted by lettering (P < 0.05, ANOVA followed Duncan’s test). The detailed information was summarized in Supplementary Table 6.
Methods
Study sites and gibbon individuals
Our research was conducted at two sites within Mt. Gaoligon National Nature Reserve, Yunnan, China: Nankang (NK, 24°49′N, 98°46′E) from October 2017 to October 2018, and Banchang (BC, N25°12′, E98°46′) from October 2017 to December 2018 (Fig. 1a). Both habitats are strongly seasonal, with the majority of the precipitation falling between May to October at NK and between June to October at BC. The annual mean temperature at NK was 13.3 °C from October 2010 to September 201119. Among them, the minimum temperature was −2.2 °C in January, and the maximum was 30.9 °C in July. Similarly, the annual mean temperature at BC was 13.0 °C from June 2013 to May 201561, with the lowest temperature −3 °C dropped in December and the highest temperature at 33.6 °C in June. The Skywalker hoolock gibbons in this area have been continuously monitored by our group for over 10 years. Thus, different individuals cloud be identified based on facial characteristics and body scars. In the present study, we focused on four individuals (consisting of an adult male, an adult female, and two juveniles) at NK and two individuals (an adult male and an adult female) at BC. A 10-year-old subadult female from NK died during the sampling period (July 2018).
Fecal sample collection and feeding behavior observation
To ensure sample quality, fecal samples were collected immediately after defecation (typically less than 5 min). Fecal samples free of soil and litter contamination were carefully and aseptically collected. Samples were placed into 50-ml sterile tubes with 95% ethanol62 and then transported to the laboratory, where they were stored at −80 °C prior to subsequent processing.
Diet data resolved at the individual level were collected8. In brief, each month we followed the gibbons for on average eight days. Gibbons were located by visiting their sleeping sites of the previous day, listening to their loud calls, and visiting the fruit trees that the gibbons frequented. Once found, gibbon members were tracked until they arrived at their sleeping sites. Through continuous observation, the food species and food type (including fruits, leaves, flowers, animals, and unknown/unidentified diet items) eaten by gibbons were recorded by using two methods (5-min scan and ad libitum)63. The observed time gibbons spent on specific food types was used to quantify the proportions of each food type instead of a direct estimation of the amount of food consumed. Hierarchical cluster analysis of dietary compositions was conducted with the average linkage method (hclust argument) based on Bray–Curtis dissimilarity (using vegan) and visualized with ggtree. The detailed information of each sample was summarized in Supplementary Table 7.
16S rRNA amplicon sequencing, bioinformatic and statistical analyses
DNA was extracted from the fecal samples using the ALFA-SEQ Stool DNA Kit (Magigene, Guangdong, China) following the manufacturer’s instructions. Subsequently, the V4 hypervariable region of the 16S ribosomal RNA genes was amplified using the primer set F515 (5’-GTGCCAGCMGCCGCGGTAA-3’) and R806 (5’-GGACTACVSGGGTATCTAAT-3’). The resulting PCR products were pooled in equal amounts, and paired-end 250 bp sequencing was carried out on an Illumina NovaSeq 6000 platform (Illumina, San Diego, CA). The generated 16S rRNA gene sequences were pre-processed (including assembling paired-end reads, trimming primer, and quality. filtering) using the USEARCH (v.10.0.240)64 The resulting sequences were denoised into Zero-radius Operational Taxonomy Units (ZOTUs) at the 100% similarity threshold. Putative chimeras were eliminated using UNOISE265. Taxonomy classification of each ZOTU was performed in QIIME 2 (v.2019.10)66 with the QIIME2 feature classifier plugin67 and the SILVA (v.138) sequence database68. ZOTUs that were classified as chloroplasts or mitochondria were removed. The taxonomic classifications of ZOTUs were summarized in Supplementary Table 8. To allow comparison on an equal basis, data were rarefied to 83,000 reads per sample (n = 514) for the downstream comparison analyses. Then, we averaged ZOTUs abundance for all samples on the same day within the same diet and rarefied to 82,600 reads per sample for the subsequent analyses.
All statistical analyses were implemented in R (v.4.0.2). Alpha diversity (i.e., observed richness, Shannon diversity, and evenness diversity) was calculated using the Microbiome package. The statistical significance of differences in alpha diversity and taxonomic composition between the two social groups was determined using the non-parametric Wilcoxon rank-sum test. The between-samples difference was evaluated with Aitchison distance and the principal component analysis (PCA) in “prcomp” function, enabling the projection of each sample and the variable loadings of ZOTU onto individual principal components (PCs). Regression analysis was used to test the association between diet and microbiome. SIMPER analysis was applied to identify taxa that primarily contributed to the observed differences in microbiota between two social groups69,70. Multivariate relationships among the microbiota of gibbon social groups and individuals were visualized with principal coordinates analysis (PCoA) and non-metric multidimensional scaling (NMDS) (vegan 2.5-6). The significant variance between groups was evaluated using the anosim function from vegan package with 999 permutations. Procrustes analysis was performed to determine the level of association between microbiome composition and diet composition (vegan 2.5-6). Estimated p-values were based on the Monte Carlo permutation tests (999 permutations). Spearman correlations were conducted using the Hmisc package to assess the relationships between microbiome composition and diet composition, and p-values were adjusted for multiple comparisons using the FDR method71. Hierarchical cluster analysis was conducted based on Bray–Curtis dissimilarity using the “hclust” argument and visualized with heatmap.2 function.
Co-occurrence network analysis
Network analysis was performed using the sparse inverse covariance estimation with ecological association inference (SPIEC-EASI) method (method = ‘mb’, lambda.min.ratio = 0.001, nlambda = 20, pulsar.params = list (rep.num = 50, ncores = 20)72. Samples from the two social groups were divided into five clusters (0–20%, 20–40%, 40–60%, 60–80%, and 80–100%) based on the proportion of leaves in the diet. Networks were built for each cluster separately, and only ZOTUs detected in at least half of the samples were used for network construction to avoid accidental associations caused by low-abundant ZOTUs73. The number of samples varies between different clusters, which may affect the comparison of co-occurrence networks between different clusters74. In order to eliminate this effect, we re-sampled the cluster with the smallest sample number 999 times randomly. The network topological parameters (network size, total links, average degree, average path length, and edge connectivity) were calculated in the R package igraph75.
Prediction of microbial community composition
By applying random forest modeling76, the microbial community composition in response to the diet across different individuals, social groups, and all samples was predicted. Each dataset was split into two parts: 70% as the training data and 30% as the validation data. In this study, we selected different taxonomic levels including phylum (top four phyla), family (top ten families), and core ZOTUs for further analyses. A shuffled dataset for null model testing was generated by randomizing the labels related to the real training set. Then, random forest modelings were performed with the observed and shuffled datasets as input by the R package “randomForest” (random Forest function, with 1000 trees trained). The accuracy of the random forest model was evaluated by mean absolute error (MAE), which was calculated as follows77:
where yi is the observed value of the response variable, f(xi) is the predicted value. The difference between predicted models and null models was compared by the Wilcoxon rank-sum test. The differences in diverse groups were compared with one-way ANOVA and Duncan’s multiple tests in R package “agricolae” (aov and duncan.test function). The performance of the models was evaluated by the coefficient of determination (R2) of the linear regression models of the observed and predicted values.
Metagenomic assembly and gene profile construction
Metagenomic sequencing was performed on a total of 137 samples with detailed dietary records from six individuals (average metagenome size 28.8 ± 3.2 Gb). The libraries were constructed and sequenced on Illumina NovaSeq 6000 platform (paired-end 150 bp reads). Raw reads were quality filtered to remove low-quality reads and adapter sequences using fastp (v.0.21.0) with default parameters78, and host contamination was removed by mapping the read to the host genome with Bowtie2 (v.2.2.9)79. Clean reads assembly was performed with Megahit (v.1.2.9) using kmers set of 21,29,39,59,79,99,119,14180. Open-reading-frames were predicted from the contigs longer than 500 bp using Prodigal (v.2.6.3)81. A non-redundant gene catalog was constructed by clustering all genes using CD-HIT (v.4.8.1)82 at 95% nucleic acid identity. The high-quality reads from each sample were mapped to the gene catalogs using Bowtie2 with default parameters. Normalized coverage was estimated based on contigs length. The reads were calculated by multiplying the average number of reads across all libraries and then dividing by the number of reads in each library.
Functional annotation and taxonomic classification
KEGG Orthologs (KOs) were identified by aligning genes against the KOFAM database using the hmmsearch (v.3.3.2, e-value <1e−5). To perform enrichment analysis, we first used the Wilcoxon rank-sum test to test for each gene difference across the two dietary stages. Then, the total number of enriched KOs within the specific pathway was summarized and Fisher exact test was performed to detect the enriched diet-specific pathway. CAZymes were annotated against the dbCAN2 database83 (available July 2021) using the hmmsearch (e-value < 1e−5) tools of HMMER. The significantly different CAZymes between the two dietary stages were identified using the Wilcoxon rank-sum test. All p-values were corrected by the Benjamini–Hochberg false discovery rate (FDR). The taxonomic classification of predicted CAZyme genes was aligned against the NCBI-NR database with Diamond (v.2.0.6) in blastp option (e-value < 1e−10) at thresholds of identity >90% and alignment coverage >70%, which the best result with the highest average similarity was defined as the final annotation of the gene. SankeyMATIC (http://sankeymatic.com/) was used to visualize the relationships between bacteria host and CAZymes.
Metagenome-assembled genomes reconstruct and analysis
High-quality reads were mapped to the scaffolds (≥1000 bp) separately to obtain the coverage of the scaffolds in the respective samples using bowtie v.2.4.579. These scaffolds were used for binning using MetaBAT v.2.12.184 with default parameters, considering the GC content, tetranucleotide frequencies, and abundance profiles of the scaffolds. All MAGs were manually curated using RefineM v.0.1.285. Completeness and contamination of the MAGs were assessed with CheckM v.1.2.086. Only MAGs with genome completeness ≥50% and contamination <10% after manual curation were chosen for further analysis. The metagenome-assembled genomes (MAGs) were then clustered at an estimated species level (ANI ≥ 95%) with dRep v.3.2.287 using the parameters ‘-comp 50 -con 10 -pa 0.9 -sa 0.95 -cm larger -nc 0.3’, resulting in 569 MAGs. The taxonomic classification of the MAGs was conducted with GTDB-Tk v.2.1.188. Open reading frames (ORFs) of these MAGs were determined using Prodigal v.2.6.381 with the “-p single” option. The functional annotations were obtained as mentioned above. The abundance of the MAGs was computed as the fraction of metagenomics reads that were assigned to the scaffolds of each MAGs. Genome-scale metabolic models for the representative genomes were reconstructed using CarveMe v.1.5.089, which were further applied to evaluate complementary and competition indices between pairs of MAGs using the R package RevEcoR v.0.99.390.
Data availability
All 16S rRNA raw sequences and raw shotgun metagenomic sequencing data have been deposited in the National Genomics Data Center, China National Center for Bioinformation or Beijing Institute of Genomics, Chinese Academy of Sciences, under the project number PRJCA012504.
Code availability
The R scripts and relevant data were provided on GitHub at https://github.com/lettial/Gibbon-gut-microbiome.
References
de La Torre, S., Snowdon, C. T. & Bejarano, M. Effects of human activities on wild pygmy marmosets in Ecuadorian Amazonia. Biol. Conserv. 94, 153–163 (2000).
Turvey, S. T. & Crees, J. J. Extinction in the Anthropocene. Curr. Biol. 29, R982–R986 (2019).
Newbold, T. et al. Global effects of land use on local terrestrial biodiversity. Nature 520, 45–50 (2015).
di Marco, M., Venter, O., Possingham, H. P. & Watson, J. E. M. Changes in human footprint drive changes in species extinction risk. Nat. Commun. 9, 1–9 (2018).
Ceballos, G. & Ehrlich, P. R. Mammal population losses and the extinction crisis. Science 296, 904–907 (2002).
Yang, L., Shi, K. C., Ma, C., Ren, G. P. & Fan, P. F. Mechanisms underlying altitudinal and horizontal range contraction: the western black crested gibbon. J. Biogeogr. 48, 321–331 (2021).
Li, X. et al. Human impact and climate cooling caused range contraction of large mammals in China over the past two millennia. Ecography 38, 74–82 (2015).
Fan, P. F., Ni, Q. Y., Sun, G. Z., Huang, B. & Jiang, X. L. Gibbons under seasonal stress: The diet of the black crested gibbon (Nomascus concolor) on Mt. Wuliang, Central Yunnan, China. Primates 50, 37–44 (2009).
Hanya, G. Seasonal variations in the activity budget of Japanese macaques in the coniferous forest of Yakushima: effects of food and temperature. Am. J. Primatol. 63, 165–177 (2004).
Mcconkey, K. R., Aldy, F., Ario, A. & Chivers, D. J. Selection of fruit by Gibbons (Hylobates muelleri × agilis) in the Rain Forests of Central Borneo. Int. J. Primatol. 23, 123–145 (2002).
Amato, K. R. et al. Habitat degradation impacts black howler monkey (Alouatta pigra) gastrointestinal microbiomes. ISME J. 7, 1344–1353 (2013).
McKenney, E. A., O’Connell, T. M., Rodrigo, A. & Yoder, A. D. Feeding strategy shapes gut metagenomic enrichment and functional specialization in captive lemurs. Gut Microbes 9, 202–217 (2018).
Baniel, A. et al. Seasonal shifts in the gut microbiome indicate plastic responses to diet in wild geladas. Microbiome 9, 1–20 (2021).
Hicks, A. L. et al. Gut microbiomes of wild great apes fluctuate seasonally in response to diet. Nat. Commun. 9, 1–18 (2018).
Huang, G. et al. Seasonal shift of the gut microbiome synchronizes host peripheral circadian rhythm for physiological adaptation to a low-fat diet in the giant panda. Cell Rep. 38, 110203 (2022).
Fan, P. F. et al. Description of a new species of Hoolock gibbon (Primates: Hylobatidae) based on integrative taxonomy. Am. J. Primatol. 79, e22631 (2017).
Fan, P. F., Turvey, S. T. & Bryant, J. V. Hoolock tianxing (amended version of 2019 assessment). IUCN Red List of Threatened Species 2020–2021 (2020).
McGrosky, A. et al. Gross intestinal morphometry and allometry in primates. Am. J. Primatol. 81, e23035 (2019).
Fan, P. F., Ai, H.-S., Fei, H. L., Zhang, D. & Yuan, S. D. Seasonal variation of diet and time budget of Eastern hoolock gibbons (Hoolock leuconedys) living in a northern montane forest. Primates 54, 137–146 (2013).
Kartzinel, T. R., Hsing, J. C., Musili, P. M., Brown, B. R. P. & Pringle, R. M. Covariation of diet and gut microbiome in African megafauna. Proc. Natl Acad. Sci. USA 116, 23588–23593 (2019).
Ley, R. E. et al. Evolution of mammals and their gut microbes. Science 320, 1647–1651 (2008).
Levin, D. et al. Diversity and functional landscapes in the microbiota of animals in the wild. Science 372, eabb5352 (2021).
Xiao, K. P. et al. Adaptation of gut microbiome and host metabolic systems to lignocellulosic degradation in bamboo rats. ISME J. 16, 1980–1992 (2022).
Solden, L. M. et al. Interspecies cross-feeding orchestrates carbon degradation in the rumen ecosystem. Nat. Microbiol. 3, 1274–1284 (2018).
Khanal, S. K. Microbiology and biochemistry of anaerobic biotechnology. Anaerobic Biotechnology for Bioenergy Production: Principles and Applications (ed. Khanal, S. K.) 29–40 (John Wiley & Sons, Inc., USA, 2008).
Lozupone, C. A., Stombaugh, J. I., Gordon, J. I., Jansson, J. K. & Knight, R. Diversity, stability and resilience of the human gut microbiota. Nature 489, 220–230 (2012).
Weimer, P. J. Redundancy, resilience, and host specificity of the ruminal microbiota: Implications for engineering improved ruminal fermentations. Front. Microbiol. 6, 296 (2015).
Gharechahi, J., Vahidi, M. F., DIng, X. Z., Han, J. L. & Salekdeh, G. H. Temporal changes in microbial communities attached to forages with different lignocellulosic compositions in cattle rumen. FEMS Microbiol. Ecol. 96, fiaa069 (2020).
Huttenhower, C. et al. Structure, function and diversity of the healthy human microbiome. Nature 486, 207–214 (2012).
Coyte, K. Z., Schluter, J. & Foster, K. R. The ecology of the microbiome: Networks, competition, and stability. Science 350, 663–666 (2015).
Relman, D. A. The human microbiome: ecosystem resilience and health. Nutr. Rev. 70, S2–S9 (2012).
Giongo, A. et al. Toward defining the autoimmune microbiome for type 1 diabetes. ISME J. 5, 82–91 (2011).
de Cruz, P. et al. Characterization of the gastrointestinal microbiota in health and inflammatory bowel disease. Inflamm. Bowel Dis. 18, 372–390 (2012).
Johnson, A. J. et al. Daily sampling reveals personalized diet-microbiome associations in humans. Cell Host Microbe 25, 789–802 (2019).
Amato, K. R. et al. The gut microbiota appears to compensate for seasonal diet variation in the Wild Black Howler Monkey (Alouatta pigra). Microb. Ecol. 69, 434–443 (2015).
Springer, A. et al. Patterns of seasonality and group membership characterize the gut microbiota in a longitudinal study of wild Verreaux’s sifakas (Propithecus verreauxi). Ecol. Evol. 7, 5732–5745 (2017).
Maurice, C. F. et al. Marked seasonal variation in the wild mouse gut microbiota. ISME J. 9, 2423–2434 (2015).
Mackie, R. I. et al. Ecology of uncultivated Oscillospira species in the rumen of cattle, sheep, and reindeer as assessed by microscopy and molecular approaches. Appl Environ. Microbiol. 69, 6808–6815 (2003).
Ren, T. et al. Seasonal, spatial, and maternal effects on gut microbiome in wild red squirrels. Microbiome 5, 1–14 (2017).
Flint, H. J., Scott, K. P., Duncan, S. H., Louis, P. & Forano, E. Microbial degradation of complex carbohydrates in the gut. Gut Microbes 3, 289–306 (2012).
White, B. A., Lamed, R., Bayer, E. A. & Flint, H. J. Biomass utilization by gut microbiomes. Annu. Rev. Microbiol. 68, 279–296 (2014).
Gomez, A. et al. Temporal variation selects for diet-microbe co-metabolic traits in the gut of Gorilla spp. ISME J. 10, 514–526 (2016).
Popovich, D. G. et al. The western lowland gorilla diet has implications for the health of humans and other hominoids. J. Nutr. 127, 2000–2005 (1997).
van der Hee, B. & Wells, J. M. Microbial regulation of host physiology by short-chain fatty acids. Trends Microbiol. 29, 700–712 (2021).
Bergman, E. N. Energy contributions of volatile fatty acids from the gastrointestinal tract in various species. Physiol. Rev. 70, 567–590 (1990).
Kim, C. H., Park, J. & Kim, M. Gut microbiota-derived short-chain fatty acids, T cells, and inflammation. Immune Netw. 14, 277–288 (2014).
Hossain, K. S., Amarasena, S. & Mayengbam, S. B Vitamins and their roles in gut health. Microorganisms 10, 1168 (2022).
LeBlanc, J. G. et al. Bacteria as vitamin suppliers to their host: a gut microbiota perspective. Curr. Opin. Biotechnol. 24, 160–168 (2013).
Zhang, S. et al. Gut microbiota serves a predictable outcome of short-term low-carbohydrate diet (LCD) intervention for patients with obesity. Microbiol. Spectr. 9, e00223–21 (2021).
Durrer, C. et al. A randomized controlled trial of pharmacist-led therapeutic carbohydrate and energy restriction in type 2 diabetes. Nat. Commun. 12, 1–8 (2021).
Reimer, R. A. Establishing the role of diet in the microbiota–disease axis. Nat. Rev. Gastroenterol. Hepatol. 16, 86–87 (2019).
Wasimuddin et al. High prevalence and species diversity of Helicobacter spp. detected in wild house mice. Appl. Environ. Microbiol. 78, 8158–8160 (2012).
O’Rourke, J. L., Grehan, A. & Lee, M. Non-pylori helicobacter species in humans. Gut 49, 601–606 (2001).
Orkin, J. D. et al. Seasonality of the gut microbiota of free-ranging white-faced capuchins in a tropical dry forest. ISME J. 13, 183–196 (2019).
Riera, J. L. & Baldo, L. Microbial co-occurrence networks of gut microbiota reveal community conservation and diet-associated shifts in cichlid fishes. Anim. Microbiome 2, 1–13 (2020).
de Vries, F. T. et al. Soil bacterial networks are less stable under drought than fungal networks. Nat. Commun. 9, 1–12 (2018).
Foster, E. A. et al. Social network correlates of food availability in an endangered population of killer whales, Orcinus orca. Anim. Behav. 83, 731–736 (2012).
Henzi, S. P., Lusseau, D., Weingrill, T., van Schaik, C. P. & Barrett, L. Cyclicity in the structure of female baboon social networks. Behav. Ecol. Sociobiol. 63, 1015–1021 (2009).
Berry, D. & Widder, S. Deciphering microbial interactions and detecting keystone species with co-occurrence networks. Front. Microbiol. 5, 219 (2014).
Shi, S. et al. The interconnected rhizosphere: high network complexity dominates rhizosphere assemblages. Ecol. Lett. 19, 926–936 (2016).
Yin, L. Y. et al. Effects of group density, hunting, and temperature on the singing patterns of eastern hoolock gibbons (Hoolock leuconedys) in Gaoligongshan, Southwest China. Am. J. Primatol. 78, 861–871 (2016).
Amato, K. R. et al. Evolutionary trends in host physiology outweigh dietary niche in structuring primate gut microbiomes. ISME J. 13, 576–587 (2019).
Altmann, J. Observational study of behavior: sampling methods. Behaviour 49, 227–266 (1974).
Edgar, R. C. Search and clustering orders of magnitude faster than BLAST. Bioinformatics 26, 2460–2461 (2010).
Edgar, R. C. UNOISE2: improved error-correction for Illumina 16S and ITS amplicon sequencing. https://doi.org/10.1101/081257 (2016).
Bolyen, E. et al. Reproducible, interactive, scalable and extensible microbiome data science using QIIME 2. Nat. Biotechnol. 37, 852–857 (2019).
Bokulich, N. A. et al. Optimizing taxonomic classification of marker-gene amplicon sequences with QIIME 2’s q2-feature-classifier plugin. Microbiome 6, 1–17 (2018).
Quast, C. et al. The SILVA ribosomal RNA gene database project: Improved data processing and web-based tools. Nucleic Acids Res. 41, D590–D596 (2013).
Clarke, K. R. Non-parametric multivariate analyses of changes in community structure. Austral. J. Ecol. 18, 117–143 (1993).
Wang, J. et al. Dietary history contributes to enterotype-like clustering and functional metagenomic content in the intestinal microbiome of wild mice. Proc. Natl Acad. Sci. USA 111, E2703–E2710 (2014).
Benjamini, Y. & Hochberg, Y. Controlling the false discovery rate-a practical and powerful approach to multiple testing. J. R. Stat. Soc. B 57, 289–300 (1995).
Kurtz, Z. D. et al. Sparse and compositionally robust inference of microbial ecological networks. PLoS Comput. Biol. 11, e1004226 (2015).
Deng, Y. et al. Molecular ecological network analyses. BMC Bioinforma. 13, 1–20 (2012).
Martinez, N. D., Hawkins, B. A., Dawah, H. A. & Feifarek, B. P. Effects of sampling effort on characterization of food-web structure. Ecology 80, 1044–1055 (1999).
Gabor, G. & Nepusz, T. The Igraph software package for complex network research. Int. J. Comp. Syst. 1695, 1–9 (2006).
Cutler, D. R. et al. Random forests for classification in ecology. Ecology 88, 2783–2792 (2007).
Willmott, C. J. et al. Statistics for the evaluation and comparison of models. J. Geophys. Res. 90, 8995–9005 (1985).
Chen, S. F., Zhou, Y. Q., Chen, Y. R. & Gu, J. Fastp: an ultra-fast all-in-one FASTQ preprocessor. Bioinformatics 34, i884–i890 (2018).
Langmead, B. & Salzberg, S. L. Fast gapped-read alignment with Bowtie 2. Nat. Methods 9, 357–359 (2012).
Li, D. H., Liu, C. M., Luo, R. B., Sadakane, K. & Lam, T. W. MEGAHIT: an ultra-fast single-node solution for large and complex metagenomics assembly via succinct de Bruijn graph. Bioinformatics 31, 1674–1676 (2015).
Hyatt, D. et al. Prodigal: Prokaryotic gene recognition and translation initiation site identification. BMC Bioinforma. 11, 1–11 (2010).
Fu, L. M., Niu, B. F., Zhu, Z. W., Wu, S. T. & Li, W. Z. CD-HIT: accelerated for clustering the next-generation sequencing data. Bioinformatics 28, 3150–3152 (2012).
Zhang, H. et al. DbCAN2: a meta server for automated carbohydrate-active enzyme annotation. Nucleic Acids Res. 46, W95–W101 (2018).
Kang, D. D., Froula, J., Egan, R. & Wang, Z. MetaBAT, an efficient tool for accurately reconstructing single genomes from complex microbial communities. PeerJ 2015, e1165 (2015).
Parks, D. H. et al. Recovery of nearly 8,000 metagenome-assembled genomes substantially expands the tree of life. Nat. Microbiol. 2, 1533–1542 (2017).
Parks, D. H., Imelfort, M., Skennerton, C. T., Hugenholtz, P. & Tyson, G. W. CheckM: Assessing the quality of microbial genomes recovered from isolates, single cells, and metagenomes. Genome Res. 25, 1043–1055 (2015).
Olm, M. R., Brown, C. T., Brooks, B. & Banfield, J. F. dRep: a tool for fast and accurate genomic comparisons that enables improved genome recovery from metagenomes through de-replication. ISME J. 11, 2864–2868 (2017).
Chaumeil, P. A., Mussig, A. J., Hugenholtz, P. & Parks, D. H. GTDB-Tk: a toolkit to classify genomes with the genome taxonomy database. Bioinformatics 36, 1925–1927 (2020).
Machado, D., Andrejev, S., Tramontano, M. & Patil, K. R. Fast automated reconstruction of genome-scale metabolic models for microbial species and communities. Nucleic Acids Res. 46, 7542–7553 (2018).
Cao, Y., Wang, Y. Y., Zheng, X. F., Li, F. & Bo, X. C. RevEcoR: an R package for the reverse ecology analysis of microbiomes. BMC Bioinforma. 17, 1–6 (2016).
Acknowledgements
This work was supported by the National Natural Science Foundation of China (Nos. 32201269 and 31822049), the National Key Program of Research and Development, the Ministry of Science and Technology (No. 2022YFF1301500), and the Guangdong Basic and Applied Basic Research Foundation (No. 2021A1515110523).
Author information
Authors and Affiliations
Contributions
Conceptualization, P.-F.F.; Methodology, P.-F.F. and L.-N.H.; Data curation, Q.L.; Investigation, H.-L.F, Q.L.; Resources, H.-L.F.; Formal analysis, Q.L., Z.-H.L., S.-M.G., P.-D.W., L.-Y.L., and X.-F.Z. Visualization, Q.L. and Z.-H.L. Writing original draft, Q.L. Writing review and editing, P.-F.F. and L.-N.H. Supervision; P.-F.F. and L.-N.H. Funding acquisition, S.-M.G., and P.-F.F. All authors read and approved the final manuscript.
Corresponding authors
Ethics declarations
Competing interests
The authors declare no competing interests.
Ethical
The noninvasive fecal sample collections were applied, keeping the gibbons from direct disturbance and contact, and thus no review from the Chinese ethics committee was required. This work was approved by Mt. Gaoligon National Nature Reserve and adheres to Sun Yat-sen University and the American Society of Primatologists’ Principles for the Ethical Treatment of Nonhuman Primates.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Li, Q., Fei, HL., Luo, ZH. et al. Gut microbiome responds compositionally and functionally to the seasonal diet variations in wild gibbons. npj Biofilms Microbiomes 9, 21 (2023). https://doi.org/10.1038/s41522-023-00388-2
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41522-023-00388-2
- Springer Nature Limited
This article is cited by
-
Eco-evolutionary dynamics of gut phageome in wild gibbons (Hoolock tianxing) with seasonal diet variations
Nature Communications (2024)
-
Seasonal patterns of the gut microbiota in the Assamese macaques (Macaca assamensis) in a limestone forest in Guangxi, China
European Journal of Wildlife Research (2024)