Keto microbiota: A powerful contributor to host disease recovery

Cabrera-Mulero, Amanda; Tinahones, Alberto; Bandera, Borja; Moreno-Indias, Isabel; Macías-González, Manuel; Tinahones, Francisco J.

doi:10.1007/s11154-019-09518-8

Cited by 50 publications

(48 citation statements)

References 96 publications

(122 reference statements)

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“…D-alanine metabolism intervenes in the glucose-alanine cycle of gluconeogenesis and participates actively in process of protein synthesis. The ketone bodies are substrates contributing to lipogenesis and sterol biosynthesis in anabolic condition and can also reduce oxidative stress by inhibiting reactive oxygen species production and increasing antioxidant proteins to prevent lipid peroxidation and protein oxidation during periods of starvation [38]. Likewise, gut microbiota interacts, through the modification of substrate availability secondary to protein restriction, with the diet leading to metabolic pathway reprogramming and impacting on host functioning to adapt this nutrient manipulation.…”

Section: Discussionmentioning

confidence: 99%

Compositional and Functional Adaptations of Intestinal Microbiota and Related Metabolites in CKD Patients Receiving Dietary Protein Restriction

Lee

Hsu

et al. 2020

Nutrients

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The relationship between change of gut microbiota and host serum metabolomics associated with low protein diet (LPD) has been unraveled incompletely in CKD patients. Fecal 16S rRNA gene sequencing and serum metabolomics profiling were performed. We reported significant changes in the β-diversity of gut microbiota in CKD patients having LPD (CKD-LPD, n = 16). We identified 19 genera and 12 species with significant differences in their relative abundance among CKD-LPD patients compared to patients receiving normal protein diet (CKD-NPD, n = 27) or non-CKD controls (n = 34), respectively. CKD-LPD had a significant decrease in the abundance of many butyrate-producing bacteria (family Lachnospiraceae and Bacteroidaceae) associated with enrichment of functional module of butanoate metabolism, leading to concomitant reduction in serum levels of SCFA (acetic, heptanoic and nonanoic acid). A secondary bile acid, glyco λ-muricholic acid, was significantly increased in CKD-LPD patients. Serum levels of indoxyl sulfate and p-cresyl sulfate did not differ among groups. The relationship between abundances of microbes and metabolites remained significant in subset of resampling subjects of comparable characteristics. Enrichment of bacterial gene markers related to D-alanine, ketone bodies and glutathione metabolism was noted in CKD-LPD patients. Our analyses reveal signatures and functions of gut microbiota to adapt dietary protein restriction in renal patients.

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Section: Discussionmentioning

confidence: 99%

Compositional and Functional Adaptations of Intestinal Microbiota and Related Metabolites in CKD Patients Receiving Dietary Protein Restriction

Lee

Hsu

et al. 2020

Nutrients

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“…Calcium signaling pathways are associated with skeletal muscle development, maintenance, and regeneration [37]. Microbial synthesis and degradation of ketone bodies (KB), identified in the ARS-FY-H samples, were reported as associated with increased muscle mass in humans [38,39]. Ketone bodies are an energy substrate that supply energy to the brain and muscles, contributing to the maintenance of energy homeostasis through regulation of lipogenesis [38].…”

Section: Taxonomy and Functional Diversity Correlate With Selection Fmentioning

confidence: 99%

“…Microbial synthesis and degradation of ketone bodies (KB), identified in the ARS-FY-H samples, were reported as associated with increased muscle mass in humans [38,39]. Ketone bodies are an energy substrate that supply energy to the brain and muscles, contributing to the maintenance of energy homeostasis through regulation of lipogenesis [38]. Arachidonic acid metabolism is essential for the functions of skeletal muscle and the immune system, which might be associated with increased muscle mass and health in the host [40,41].…”

Section: Taxonomy and Functional Diversity Correlate With Selection Fmentioning

confidence: 99%

Distinct Microbial Assemblages Associated with Genetic Selection for High- and Low- Muscle Yield in Rainbow Trout

Chapagain

Walker

Leeds

et al. 2020

Preprint

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Background Fish gut microbial assemblages play a crucial role in the growth rate, metabolism, and immunity of the host. We hypothesized that the gut microbiota of rainbow trout was correlated with breeding program based genetic selection for muscle yield. To test this hypothesis, fecal samples from 19 fish representing an F2 high-muscle genetic line (ARS-FY-H) and 20 fish representing an F1 low-muscle yield genetic line (ARS-FY-L) were chosen for microbiota profiling using the 16srRNA gene. Significant differences in microbial population between these two genetic lines might represent the effect of host genetic selection in structuring the gut microbiota of the host.Results Tukey’s transformed inverse Simpson indices indicated that ARS-FY-H samples have higher microbial diversity compared to those of the ARS-FY-L (LMM, χ2(1) = 14.11, p < 0.05). The fecal samples showed distinct clusters with significant differences in microbial assemblages between the genetic lines (F1,36= 4.7, p < 0.05, R2 = 11.9%). Further, Tax4Fun analyses predicted characteristic functional capabilities of the microbial communities in the ARS-FY-H and ARS-FY-L samples.Conclusion The significant differences of the microbial assemblages between ARS-FY-H and ARS-FY-L indicate an effect of genetic selection on the microbial diversity of the host. The functional composition of taxa demonstrates correlation of the function in improving the muscle accretion in the host, probably, by producing various metabolites and enzymes that might aid in digestion. Further research is required to elucidate the mechanisms involved in shaping the microbial community through host genetic selection.

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“…Genus Fusobacterium with higher abundance in high (ARS-FY-H) muscle yield genetic line is involved in lysine degradation and production of SCFAs [55]. Microbial synthesis and degradation of ketone bodies (KB), identi ed in the ARS-FY-H samples, were reported as associated with increased muscle mass in humans [56,57]. Ketone bodies make an energy substrate that supplies energy to the brain and muscles, contributing to the maintenance of energy homeostasis through regulation of lipogenesis [56].…”

Section: Comparison Of Gut Assemblages In High-(ars-fy-h) and Low-(armentioning

confidence: 99%

“…Microbial synthesis and degradation of ketone bodies (KB), identi ed in the ARS-FY-H samples, were reported as associated with increased muscle mass in humans [56,57]. Ketone bodies make an energy substrate that supplies energy to the brain and muscles, contributing to the maintenance of energy homeostasis through regulation of lipogenesis [56]. Arachidonic acid metabolism is essential for the functions of skeletal muscle and the immune system, which might be associated with increased muscle mass and health in the host [58,59].…”

Section: Comparison Of Gut Assemblages In High-(ars-fy-h) and Low-(armentioning

confidence: 99%

Distinct microbial assemblages associated with genetic selection for high- and low- muscle yield in rainbow trout

Chapagain

Walker

Leeds

et al. 2020

Preprint

View full text Add to dashboard Cite

Background Fish gut microbial assemblages play a crucial role in the growth rate, metabolism, and immunity of the host. We hypothesized that the gut microbiota of rainbow trout was correlated with breeding program based genetic selection for muscle yield. To test this hypothesis, fecal samples from 19 fish representing an F2 high-muscle genetic line (ARS-FY-H) and 20 fish representing an F1 low-muscle yield genetic line (ARS-FY-L) were chosen for microbiota profiling using the 16S rRNA gene. Significant differences in microbial population between these two genetic lines might represent the effect of host genetic selection in structuring the gut microbiota of the host. Results Tukey’s transformed inverse Simpson indices indicated that high muscle yield genetic line (ARS-FY-H) samples have higher microbial diversity compared to those of the low muscle yield genetic line (ARS-FY-L) (LMM, c2(1) =14.11, p<0.05). The fecal samples showed statistically distinct structure in microbial assemblages between the genetic lines (F1,36= 4.7, p<0.05, R2=11.9%). Functional profiling of bacterial operational taxonomic units predicted characteristic functional capabilities of the microbial communities in the high (ARS-FY-H) and low (ARS-FY-L) muscle yield genetic line samples. Conclusion The significant differences of the microbial assemblages between high (ARS-FY-H) and low (ARS-FY-L) muscle yield genetic lines indicate an effect of genetic selection on the microbial diversity of the host. The functional composition of taxa demonstrates a correlation between bacteria and improving the muscle accretion in the host, probably, by producing various metabolites and enzymes that might aid in digestion. Further research is required to elucidate the mechanisms involved in shaping the microbial community through host genetic selection.

show abstract

Keto microbiota: A powerful contributor to host disease recovery

Cited by 50 publications

References 96 publications

Compositional and Functional Adaptations of Intestinal Microbiota and Related Metabolites in CKD Patients Receiving Dietary Protein Restriction

Compositional and Functional Adaptations of Intestinal Microbiota and Related Metabolites in CKD Patients Receiving Dietary Protein Restriction

Distinct Microbial Assemblages Associated with Genetic Selection for High- and Low- Muscle Yield in Rainbow Trout

Distinct microbial assemblages associated with genetic selection for high- and low- muscle yield in rainbow trout

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