GPR109A gene deletion ameliorates gonadectomy-induced bone loss in mice

Gut microbiota and microbial metabolites for osteoporosis

Osteoporosis is an age-related bone metabolic disease. As an essential endocrine organ, the skeletal system is intricately connected with extraosseous organs. The crosstalk between bones and other organs supports this view. In recent years, the link between the gut microecology and bone metabolism has become an important research topic, both in preclinical studies and in clinical trials. Many studies have shown that skeletal changes are accompanied by changes in the composition and structure of the gut microbiota (GM). At the same time, natural or artificial interventions targeting the GM can subsequently affect bone metabolism. Moreover, microbiome-related metabolites may have important effects on bone metabolism. We aim to review the relationships among the GM, microbial metabolites, and bone metabolism and to summarize the potential mechanisms involved and the theory of the gut‒bone axis. We also describe existing bottlenecks in laboratory studies, as well as existing challenges in clinical settings, and propose possible future research directions.

Sex-dependent effect of GPR109A gene deletion in myeloid cells on bone development in mice

Blueberry metabolite-derived phenolic acids are thought to suppress bone resorption via interactions with the G protein-coupled receptor 109A (GPR109A). Previously, global GPR109A knockout (GPR109A ⁻/⁻ ) mice exhibited increased bone mass and a diminished bone-protective response to phenolic acids. While GPR109A is highly expressed in osteoclast precursor macrophages, its role in bone development remains unclear. To address this, we generated a myeloid cell-specific GPR109A knockout (GPR109A flox/flox /LysM-Cre⁺; CKO) mouse model and assessed bone phenotypes in male and female mice at 35 days, 3 months, 6 months, and 12 months using µCT. At 35 days, CKO males showed significantly improved tibia and vertebrae µCT parameters compared to controls (f/f, Cre⁺). However, at later time points (6 and 12 months), Cre recombinase effects were observed, with Cre⁺ males exhibiting similar bone parameters to CKO mice. In contrast, female CKO mice displayed significantly improved µCT parameters at 6 and 12 months. Notably, 12-month-old Cre⁺ males exhibited altered bone mechanical properties, while females did not. Gene expression analysis revealed increased Interferon regulatory factor 8 (Irf8), an osteoclastogenesis suppressor, in female CKO mice. These findings suggest that GPR109A regulates bone resorption through osteoclastogenic pathways in a sex-specific manner.

Fructooligosaccharides act on the gut-bone axis to improve bone independent of Tregs and alter osteocytes in young adult C57BL/6 female mice

Targeting the gut-bone axis with probiotics and prebiotics is considered as a promising strategy to reduce the risk of osteoporosis. Gut-derived short chain fatty acids (SCFA) mediate the effects of probiotics on bone via Tregs, but it is not known whether prebiotics act through a similar mechanism. We investigated how 2 different prebiotics, tart cherry (TC) and fructooligosaccharide (FOS), affect bone, and whether Tregs are required for this response. Eight-wk-old C57BL/6 female mice were fed with diets supplemented with 10% w/w TC, FOS, or a control diet (Con; AIN-93M) diet, and they received an isotype control or CD25 Ab to suppress Tregs. The FOS diet increased BMC, density, and trabecular bone volume in the vertebra (~40%) and proximal tibia (~30%) compared to the TC and control diets (Con), irrespective of CD25 treatment. Both prebiotics increased (P < .01) fecal SCFAs, but the response was greater with FOS. To determine how FOS affected bone cells, we examined genes involved in osteoblast and osteoclast differentiation and activity as well as genes expressed by osteocytes. The FOS increased the expression of regulators of osteoblast differentiation (bone morphogenetic protein 2 [Bmp2], Wnt family member 10b [Wnt10b] and Osterix [Osx]) and type 1 collagen). Osteoclasts regulators were unaltered. The FOS also increased the expression of genes associated with osteocytes, including (Phex), matrix extracellular phosphoglycoprotein (Mepe), and dentin matrix acidic phosphoprotein 1 (Dmp-1). However, Sost, the gene that encodes for sclerostin was also increased by FOS as the number and density of osteocytes increased. These findings demonstrate that FOS has a greater effect on the bone mass and structure in young adult female mice than TC and that its influence on osteoblasts and osteocytes is not dependent on Tregs.