Male hypogonadism results in the alteration of rectal microbiota and elevated levels of the serum branched-chain amino acids (BCAA) in postpubescent cattle
To evaluate the possible relationship between male hypogonadism and the intestinal microbiota in cattle, we investigated bacterial communities in the rectal contents of male (n=5) and CtM Hanwoo (n=5) at juvenile (mean age: 11.9±1.1 months) and postpubescent stages (mean age: 19.3±1.5 months). Age-matched non-pregnant females (n=5) were included in the comparison of rectal microbiota. All animal groups were farmed in geographically closely located cages and fed the same diet (Additional file 2: Supplementary Table S1) to minimize any cage- and diet-induced inter-individual variation of the intestinal microbiota. Body weight was not significantly affected by male castration (Fig. 1a). At the postpubescent stage, but not at the juvenile stage, the serum testosterone levels in the male Hanwoo were significantly higher than those in CtM and females (Fig. 1b and Additional file 1: Supplementary Fig. S1a; ANOVA, p<0.001). The serum 17b-estradiol levels were not significantly different between groups at the postpubescent and juvenile stage (Fig. 1c and Additional file 1: Supplementary Fig. S1b). Principal coordinates analysis (PCoA) of the rectal microbiome indicated that the gut microbial communities in the juvenile or postpubescent males were significantly separated from the other groups (PERMANOVA, p=0.001; comparison of the male, CtM, and female animals) (Fig. 1d and Additional file 1: Supplementary Fig. S1c). The PCoA plots of the postpubescent CtM and female data grouped together, indicating that the effect of castration on the rectal microbiota became apparent after pubescence. We additionally investigated the impact of male castration on the rectal microbiota in another breed of cattle, the Holstein. Similar to the postpubescent Hanwoo, PCoA of the Holstein rectal microbiota data revealed a significant bacterial community separation according to male castration (PERMANOVA, p=0.001; comparison of the male, CtM, and female animals), with a clustering of the CtM and female data (Additional file 1: Supplementary Fig. S2a).
To evaluate the effects of changes in the gut microbiota induced by male castration on the host metabolomic profile, we next analyzed the serum metabolome profiles of postpubescent cattle by using gas chromatography time-of-flight mass spectrometry (GC-TOF-MS). Similar to the clustering patterns of the cattle rectal microbiota described above, PCoA of the Hanwoo metabolome data revealed that the male and CtM datasets clustered separately (Fig. 1e; PERMANOVA, p=0.073; comparison of the male and CtM Hanwoo). The CtM and female datasets clustered closely together. Profiling of the serum metabolomes of the male and CtM Hanwoo revealed meaningful differences in the serum amino acid levels. Specifically, the serum levels of isoleucine and proline were significantly higher in the CtM Hanwoo than in the male Hanwoo (Fig. 1f; Mann-Whitney U test, p<0.05). Of note, BCAAs (isoleucine, leucine, and valine) are responsible not only for the intramuscular lipid accumulation, by increasing the vascular fatty acid transport into the mouse skeletal muscle [19], but also for lipogenesis in the human adipocyte [20]. We accordingly quantified serum BCAA levels using an enzyme-based assay. The serum BCAA levels were significantly higher in the postpubescent CtM Hanwoo than in the male controls (Fig. 1g; Mann-Whitney U test, p<0.05). The serum metabolite profiles of Holstein revealed that the levels of isoleucine, valine, phenylalanine, and threonine were significantly higher (Mann-Whitney U test, p<0.05) in the CtM animals than in males (Additional file 1: Supplementary Fig. S2b,c). Further, an enzyme-based quantitative analysis revealed higher median serum BCAA levels in the CtM group than in the male controls, but the difference was not statistically significant (Additional file 1: Supplementary Fig. S2d).
Metataxonomic analysis of different intestinal compartments reveals a marked increase in the family Peptostreptococcaceae in the ileum of CtM animals
Although the analysis revealed differences in the rectal microbiota of the male and CtM cattle (Fig. 1), no direct link between the composition of rectal microbiota and elevated serum BCAA levels was apparent, nor the involvement of the rectal microbiota in the host amino acid metabolism (according to the rectal metabolome profiles of postpubescent cattle; Additional file 1: Supplementary Fig. S3). To reveal whether the high serum BCAA levels were a consequence of the gut microbial activity, we next extensively investigated microbial profiles in the different compartments of the gastrointestinal tract. We collected the luminal contents of the rumen, ileum, and colon from the adult male (mean age: 31.2±5.9 months, n=10) and CtM (mean age: 33.9±1.4 months, n=10) Hanwoo. Similar to the postpubescent stage, we observed a significant difference (Mann-Whitney U test, p<0.001) in the serum testosterone levels between the male and CtM groups at the adult stage (Fig. 2a). PCoA of the microbiota in the rumen, ileum, and colon revealed that the bacterial communities in the different segments were significantly different in the male and CtM Hanwoo (PERMANOVA, p<0.005 for each segment; comparison of the male and CtM animals in the rumen, ileum, and colon) (Fig. 2b). We next evaluated the gastrointestinal segment in which the bacterial communities were mostly affected by male castration. When all gastrointestinal samples were plotted together, only the ileal microbiota in the male and CtM groups were separated on both the abundance-weighted (weighted UniFrac, Fig. 2c and Additional file 1: Supplementary Fig. S4a) and -unweighted PCoA (unweighted UniFrac, Additional file 1: Supplementary Fig. S4b). Similar, analysis of the weighted UniFrac distance between the male and CtM groups revealed the largest dissimilarity value for the ileal microbiota (Fig. 2d).
We then compared the relative abundances of major taxa (>0.5% of the mean abundance) at the family level. The difference of the ileal microbiota in the male and CtM groups was apparent, with a marked increase in the family Peptostreptococcaceae in the CtM Hanwoo (Fig. 2e and Additional file 1: Supplementary Fig. S4c). Phylogenetic analysis of the operational taxonomic units (OTUs) assigned to the family Peptostreptococcaceae further revealed that the abundant OTUs mostly belonged to the genera Romboutsia and Paeniclostridium (Additional file 1: Supplementary Fig. S5).
To investigate the relationship between the intestinal microbiota and the resultant microbial metabolites (especially BCAAs) in detail, we subsequently analyzed metabolomic profiles of the luminal contents of the ileum, cecum, and colon of the CtM Hanwoo (Additional file 3: Supplementary Result). In the ileum, a strong positive correlation (Spearman’s rank correlation analysis, p<0.001) was detected between the BCAAs and two unclassified genera belonging to the family Peptostreptococcaceae, and the genera Butyrivibrio, Acetitomaculum, and Atopobium (Additional file 1: Supplementary Fig. S6a). Furthermore, the ileal levels of intestinal BCAAs were significantly higher (Mann-Whitney U test, p<0.001) in the CtM Hanwoo than those in the male controls; the BCAA levels in the cecum and colon were much lower than those in the ileum, and no quantitative difference in the BCAA levels was observed between the male and CtM groups (Additional file 1: Supplementary Fig. S6b).
Male castration results in increased intramuscular fat accumulation with high BCAA levels in the adult cattle
We next evaluated the consequence of the distinct metabolomic profile (i.e., high levels of BCAAs in the serum and ileum) of the CtM cattle. After the bodies were dressed (n=10 in each group), we observed clear differences in the body composition of the male and CtM Hanwoo (Fig. 3a). The thickness of the dorsal subcutaneous fat, total fat weight, and serum BCAA levels in the CtM group were significantly higher than those of the male controls (Fig. 3b; Mann-Whitney U test, p<0.001). We then analyzed the degree of intramuscular fat accumulation in the fresh striploin muscle in the male and CtM Hanwoo carcasses (n=5 in each group). We observed a significantly higher (Mann-Whitney U test, p<0.01) intramuscular fat accumulation in the CtM muscle than in the male muscle (Fig. 3c,d). We next evaluated the intramuscular metabolites profiles. Similar to the serum metabolite profiles described above, the intramuscular metabolomes of the male and CtM carcasses clustered significantly separately by PCoA (Fig. 3e; PERMANOVA, p=0.008; comparison of the male and CtM Hanwoo). The levels of BCAAs (i.e., isoleucine and leucine), as well as phenylalanine, tryptophan, and tyrosine, were significantly higher (Mann-Whitney U test, p<0.05) in the CtM muscle than in the male muscle (Fig. 3f). Among the amino acids whose levels were increased in the CtM muscle, leucine, phenylalanine, tryptophan, and tyrosine can be degraded into acetyl-CoA, a precursor of ketone bodies. We subsequently measured the intramuscular levels of b-hydroxybutyrate (3-HB), widely used to diagnose ketosis in dairy cow [21], in the male and CtM muscles. The 3-HB levels were significantly higher (Mann-Whitney U test, p<0.01) in the CtM muscle than in the male muscle (Fig. 3g). Interestingly, Jang et al. [19] reported that 3-HB secreted by the muscle cell activates endothelial fatty acid transport and promotes lipid accumulation in the muscle. This supports the data presented herein, bridging the high levels of serum BCAAs and the elevated intramuscular fat accumulation in the CtM cattle.
Male hypogonadism leads to an ileal microbial alteration, adiposity, and increased serum BCAA levels in mice
The correlation-based analysis in cattle presented above suggested an obesogenic effect(s) of the castration of young male on the subsequent host metabolic phenotype in association with altered intestinal microbiota and systemic metabolite levels. We next evaluated the causative role of the alteration of the gut microbiota following hypogonadism in the obese metabolic phenotype in a mouse model. Male mice underwent prepubertal castration by orchiectomy and were fed a high-fat diet (HFD) to promote the obese phenotype. Age-matched male mice that underwent sham-operation and fed low-fat diet (LFD) were included as the castration and diet controls, respectively (n=6 in each group; Fig. 4a). At the end of the experiment, the serum testosterone levels in the CtM groups were significantly lower than those in the Sham groups (unpaired Student’s t-test, p<0.05), confirming that hypogonadism developed after castration (Fig. 4b). Further, serum testosterone levels in diet-induced obese mice were lower than those in the lean controls (unpaired Student’s t-test, p=0.064; comparison of the Sham-LFD and Sham-HFD groups). This was in agreement with human epidemiological studies. Weighted PCoA of both the ileal and colonic microbiota revealed a male castration-associated separation of the intestinal microbial community structures, regardless of the intestinal compartment analyzed (PERMANOVA, p<0.04; comparison of the Sham and CtM groups). However, the difference between the ileal microbiota was more obvious than that between the colonic microbiota in HFD-fed mice (Fig. 4c and Additional file 1: Supplementary Fig. S7a,b). In both LFD- and HFD-fed mice, male hypogonadism amplified the expansion of the family Peptostreptococcaceae in the ileum (Fig. 4d and Additional file 1: Supplementary Fig. S8a,b), and resulted in significantly increased levels of serum BCAAs (Fig. 4e; unpaired Student’s t-test, p<0.05).
To reveal the effect(s) of gut microbiota on the host metabolism, the HFD-fed groups received a broad-spectrum antibiotic cocktail in the drinking water for 5 weeks (HFD+ABX, Fig. 4a). No signs of dehydration or anorexia were observed during the antibiotic treatment. The antibiotic treatment disrupted both the ileal and colonic microbial structures (Fig. 4c and Additional file 1: Supplementary Fig. S7c and S8c). As expected, the antibiotic treatment abolished the previously observed increase in the serum BCAA levels in the CtM groups compared with the Sham groups (Fig. 4e). The proportions of both the extramuscular white adipose tissue depots (the posterior subcutaneous fat, mesenteric fat, and retroperitoneal fat) and intermuscular fat (located between the gastrocnemius and rectus femoris) were significantly increased by HFD feeding and castration (unpaired Student’s t-test, p<0.01; Fig. 4f–h and Additional file 1: Supplementary Fig. S9). Although the castration-induced adiposity in the HFD-fed mice was significant in antibiotic-treated groups (Sham-ABX vs. CtM-ABX), the antibiotic treatment attenuated the level of significance.
Fecal microbiota transplantation (FMT) from the hypogonadal male mice donors leads to increased fat accumulation in the recipient eugonadal male mice
To determine whether the gut microbiota was responsible for the obese phenotype in castrated mice, we performed FMT from the HFD-fed Sham or CtM donor mice to age-matched surgery-naïve eugonadal male recipient mice (Sham-R and CtM-R, respectively; n=5 in each group) (Fig. 5a). Intriguingly, the difference in serum testosterone levels in the Sham-R and CtM-R groups approached statistical significance (Fig. 5b; unpaired Student’s t-test, p=0.0556), suggesting a bidirectional regulatory relationship between the gut microbiota and androgenic hormones. FMT resulted in the segregation of the ileal and colonic microbiota of the recipient mice according to treatment (PERMANOVA, p≤0.05; comparison of the Sham-R and CtM-R groups) (Fig. 5c and Additional file 1: Supplementary Fig. S10a). The LEfSe analysis of the ileal microbiota revealed the family Peptostreptococcaceae as the most discriminant taxon in comparisons of the Sham-R and CtM-R groups (Fig. 5d,e). Importantly, CtM-R mice recapitulated the phenotype observed in the CtM-HFD donor mice in terms of a significantly increased fat accumulation in the posterior subcutaneous, epididymal, mesenteric, and retroperitoneal depots, as well as of the intermuscular fat in the CtM-R group compared with the Sham-R group (Fig. 5f–h and Additional file 1: Supplementary Fig. S10b–g; unpaired Student’s t-test, p<0.05). Collectively, these observations suggest that the hypogonadism-mediated gut microbial changes contribute to the obese-prone metabolic phenotype per se.
Feeding BCAA-enriched diet elicits an obese phenotype in male mice
To evaluate whether the surplus BCAAs are the key factor contributing to the obese phenotype of the castrated animal, we fed non-castrated male mice with HFD (0% BCAA group) or customized isocaloric BCAA-HFDs (3% and 5% BCAA groups) for 8 weeks (Fig. 6a). For the BCAA-HFD, casein in HFD was substituted by BCAAs (Additional file 2: Supplementary Table S2). Feeding BCAA-HFD increased the body weight gain to a greater extent than feeding HFD, with a meaningful difference after 3 weeks of feeding (Fig. 6b; unpaired Student’s t-test, p<0.05). At the end of the experiment, we observed a significantly greater adiposity (characterized by the increased percentage to body weight ratio of the posterior subcutaneous fat, epididymal fat, mesenteric fat, and retroperitoneal fat) in the BCAA-HFD-fed groups compared with the HFD-fed group (Fig. 6c,d and Additional file 1: Supplementary Fig. S11a–h; unpaired Student’s t-test, p<0.01). Further, the serum BCAA levels were significantly increased in the mice fed diets containing over 3% of BCAAs, confirming systemic circulation of the dietary BCAAs (Fig. 6e; unpaired Student’s t-test, p<0.01). We subsequently investigated the effect of BCAA supplementations on the gut microbiota by analyzing the ileal and colonic bacterial communities. However, no connecting evidence was apparent linking the BCAA supplementation and gut microbial alteration (Fig. 6f and Additional file 1: Supplementary Fig. S11i). These observations implied that the surplus BCAAs detected in the hypogonadal animals might be a consequence of the altered gut microbial activity following male castration.
Hypogonadal male animals exhibit a high intestinal microbial urease activity
Testosterone acts not only as the major androgenic hormone but also as a metabolic hormone, affecting the hepatic urea cycle to regulate the whole-body protein catabolism [22, 23]. Because the metataxonomic analyses of the ileal microbiota of castrated animals revealed a high abundance of the family Peptostreptococcaceae, we hypothesized that a positive feedback loop might exist between the hepatic urea cycle and ureolysis undertaken by the abundant gut microbiota. Accordingly, we assessed the systemic urea/ammonia metabolism activities in cattle and mice in response to male hypogonadism. In adult Hanwoo, the microbial urease activity in both the rumen and ileum in the CtM group was significantly higher (Additional file 1: Supplementary Fig. S12a; Mann-Whitney U test, p<0.01) than that in the male group. The intestinal microbial ureases hydrolyze urea to ammonia [24]. Hence, we subsequently measured the intestinal ammonia levels. The ileal ammonia levels in the CtM group were significantly higher (Additional file 1: Supplementary Fig. S12b; Mann-Whitney U test, p<0.05) than those in the male group. In the gut, ammonia produced by ureolytic bacteria is absorbed into the bloodstream and used to fuel hepatic ureagenesis [25]. Accordingly, we determined ammonia levels in the mouse serum. For the HFD-fed mice, the serum ammonia levels in the CtM group were significantly higher than those in the Sham control (Additional file 1: Supplementary Fig. S12d; unpaired Student’s t-test, p<0.05). In both cattle and mice, however, no differences in the serum urea levels in the male and CtM groups were apparent (Additional file 1: Supplementary Fig. S12c,e). This was probably because of a simple diffusion of the systemic urea into the gastrointestinal tract [26]. Collectively, the above observations suggested that testosterone deficiency in the castrated animals might positively regulate the hepatic ureagenesis, and that urea (and its hydrolysis products, i.e., ammonia and carbon dioxide) potentially affects the ileal microbial profile in the CtM animals.