A narrative review of the moderating effects and repercussion of exercise intervention on osteoporosis: ingenious involvement of gut microbiota and its metabolites

As one of the significant metabolites of GM, SCFAs are mainly composed of the carboxylic acids and small hydrocarbon chains [102, 103]. SCFAs is mainly composed of the acetic acid, propionic acid, butyric acid, and so on. Therein, the acetic acid and propionic acid can act on the liver and surrounding organs, and are the substrates for gluconeogenesis and lipogenesis, while the butyric acid provides the energy for colonic epithelial cells [104‐106]. Barton et al. [107] compared the 16 S rRNA sequencing and metabolomics results of 40 professional athletes and 46 sedentary controls, and found that the GM of professional athletes had enhanced the ability to synthesize amino acids and regulate the carbohydrate metabolic pathways, and the contents of metabolites also increased significantly. Yu et al. [108] revealed that increased production of metabolites after exercise can induce an increase in the genetic expression of sestrin-2 (SESN2) and CREB regulated transcription coactivator 2 (CRTC2) in the liver of mice, resulting in a decline in the expression of inflammatory factors (such as IL-1β and TNF-α), and significantly reduce the level of LPS in circulation, so as to ameliorate the inflammatory or metabolic related diseases. Mailing et al. [109] also showed a role of butyric acid in the intestine to prevent the degradation of intestinal mucosa. Researchers observed an increase in relative abundance of butyric acid-producing bacteria (Blautia, Roseburia, Anaerostipes, Butyricicoccus) in the intestine of athletes under high intensity exercise conditions. Butyric acid can directly supply the energy to the intestinal epithelial cells and repair injury, thereby reducing the injury to intestine of body caused by high intensity exercise training [110, 111]. Meanwhile, Xia et al. [112] suggested that the benefits of exercise could be transmitted between the individuals via the transplantation of GM. Specifically, after 12 weeks of moderate intensity exercise, the systolic blood pressure of hypertensive rats reduced, accompanied by the increase in diversity of GM, and this antihypertensive effect can be transmitted to non-exercise hypertensive rats by means of FMT. Scheiman et al. [113] transplanted the atypical Veillonella isolated from the feces of marathon athletes into experimental mice, and the exercise endurance of mice was significantly improved. Besides, several studies have also reported that the production of butyric acid is related to the production of heat shock protein 70 (HSP70) [114, 115]. HSP70 contributes to maintaining the structural and functional properties of intestinal epithelial cells in response to the damage caused by the prolonged vigorous exercise, which may provide structural and functional stability to intestinal epithelial cells under adverse conditions. Hence, these researches revealed that GM and SCFAs played a critical role in mediating the exercise benefits.

In addition to SCFAs, the metabolic disturbance of bile acids (BAs) is also involved in the occurrence and progression of OP. As a kind of signal molecule, BAs not only play a significant role in the absorption, transport and distribution of fat and fat-soluble vitamins, but also participate in the regulation of energy metabolism, thereby inhibiting the excessive proliferation of GM [116]. Fukiya et al. [117] showed that Bacteroides enterica and Escherichia coli were involved in the production of secondary BAs in the colon, and exercise may increase the level of secondary BAs by increasing the contents of beneficial bacteria. Meanwhile, Meissner et al. [118] also revealed that compared with the mice in sedentary group, mice participating in 12-week autonomous exercise had the increased secretion of BAs and output of fecal BAs, and the fecal BAs increased with the enhancement of exercise amount and exercise intensity. On the basis of this, Clark et al. [119] showed that secondary BAs produced by GM could participate in the regulation of reactive oxygen species (ROS) and inflammatory responses in body by attenuating TNF-α-mediated immune responses and reducing the expression of inflammasomes (such as NOD-like receptor thermal protein domain associated protein 3 (NLRP3)). In addition, the dysbiosis of GM may also decrease the activation of BAs and reduce the levels of free BAs and secondary BAs, and the activation of farnesoid X receptor (FXR), takeda G protein-coupled receptor 5 (TGR5) and the interaction with mitochondria might also be weakened, and these receptors have been verified to be closely related to the regulation of the balance between osteoblasts and osteoclasts [120, 121]. It is recognized that the changes of GM and its metabolites under different intervention conditions, as well as the further in-depth regulatory effects, have become one of vital potential mechanisms of exercise-mediated OP benefits.

Different exercise amount and exercise intensity may have different effects on the intestinal mucosal barrier and mucosal immune function, and regular moderate exercise may reduce the incidence of infection in body [122]. Meanwhile, moderate exercise can reduce the intestinal inflammatory reaction without affecting the normal tissue structure and morphology of intestinal mucosal barrier [123]. Both prolonged endurance exercise and high intensity exercise could result in the impaired intestinal mucosal barrier function, and mechanisms may be related to the redistribution of blood in whole body. During the process of exercise, blood is mainly concentrated in the heart and skeletal muscles, and the symptoms (such as ischemia and hypoxia) may appear in intestine for a short period of time [124]. With the enhancement of exercise intensity and prolonged duration, the blood redistribution of body may become more apparent. Furthermore, the decrease of intestinal PH value caused by mesenteric ischemia, hypoxia and ischemia-reperfusion is the main reason to induce the intestinal oxidative stress and metabolic abnormalities. The production of excessive nitrogen and oxides caused by high intensity exercise might exacerbate the oxidative damage of intestinal biomolecules, resulting in the injury of intestinal tight junction proteins, and the structure and function of intestinal epithelial cells, thereby further resulting in “intestinal leakage” [125, 126]. Moreover, during the process of acute/vigorous exercise, core temperature in body increases continuously, and prolonged overheating (> 40 °C) can bring about the damage to intestinal epithelial cells, thereby resulting in cell shedding, intestinal villus contraction, edema or hemorrhage [127].

In addition, the long-term aerobic exercise can enhance the adaptability of body to exercise, and the intestinal mucosal barrier function can also be significantly improved under the long-term exercise intervention [128]. Kang et al. [129] indicated that long-term round-running exercise intervention could significantly increase the expression of antioxidant enzymes, anti-inflammatory factors and anti-apoptotic proteins in intestinal lymphocytes of mice, accompanied by the decline of serum inflammatory factor levels, suggesting that long-term aerobic exercise plays a positive role in maintaining intestinal villus morphology and improving intestinal permeability. Motiani et al. [130] observed that after 12 weeks of HFD induction, the basal part of intestinal villi of mice could be significantly widened, and its mechanisms may be related to the infiltration of intestinal inflammatory cells and increase of adipocytes. However, the morphology of intestinal villi and proportion of intestinal inflammatory cells in mice treated with HFD combined with long-term round-running exercise intervention were significantly improved. Other researches have also proposed that the positive impact of long-term aerobic exercise on intestinal mucosal barrier function is associated with the improvement of structure and abundance of GM, the decline of serum inflammatory level and the tolerance level of intestinal ROS [131, 132]. A large number of free radicals generated during exercise are related to the damage of bone, skeletal muscle and the decline of exercise capacity. Excessive free radicals generated by long-term and high intensity exercise might result in the body to generate the exercise-induced oxidative stress damage, which is detrimental to the health and exercise capacity of athletes [133, 134]. Hsu et al. [135] revealed that the endurance exercise time of specific pathogen free (SPF) mice was significantly higher than that of GF mice, and levels of serum glutathione peroxidase and catalase were also higher than that of GF mice, indicating that GM might eliminate the excessive free radicals produced by exercise, alleviate the exercise fatigue and improve the exercise capacity by enhancing the level of antioxidant enzymes. As there are few relevant studies, more animal models and its potential mechanisms still need to be verified in the future. Nevertheless, as a beneficial stimulus, it is recognized that the exercise intervention can enhance the long-term elasticity of intestinal mucosal barrier, reduce the release of pro-osteoclastogenic cytokines, and increase antioxidant capacity, thus inhibiting the activation of RANKL/OPG/RANK pathway, regulating the balance of osteoblasts and osteoclasts, and further preventing or treating OP.

On one hand, GM is involved in immune maturation and anti-infection protection of the body, and in this process, the microorganisms are involved in immune system to recognize and distinguish between the beneficial and harmful bacteria [136]. On the other hand, GM can directly or indirectly influence the function of dendritic cells and macrophages, modulate the activity of T cells, and induce the maturation of B cells via epithelial cells [137, 138]. Moreover, GM can also promote the immune progress of intestinal mucosa through dialogue with the immune system, which might be a critical mechanism for body to prevent the invasion of pathogens [139]. The innate immune system recognizes and differentiates the pathogens and harmless substances through the toll-like receptors (TLRs) and nucleotide-bonded oligomerization domain receptor mechanisms, while microorganisms regulate the expression of TLRs through microbe-associated molecular patterns (MAMPs) pathway, trigger the cascade effect, and further induce the immune response [140, 141].

In addition, the supplementation of probiotics/prebiotics also has a crucial impact and repercussion on exercise-mediated immune regulation. Athletes might also benefit from the regular probiotic supplementations, while with certain strain specificity [142, 143]. Probiotics commonly used to improve the immune function of athletes include Lactobacillus and Bifidobacterium [144, 145]. Previous studies have indicated that after the regular supplementation of probiotics, the severity of gastrointestinal diseases and incidence rate of respiratory diseases in high intensity male athletes are significantly reduced, and the immune disturbance induced by exercise is correspondingly weakened [146‐148]. Bermon et al. [149] revealed that the course and severity of upper respiratory tract infection were decreased in the 20 high-level long-distance runners after the oral administration of Lactobacillus yeast, while the levels of IgA, IL-4 and IL-12 in saliva were not significantly changed. Furthermore, as a kind of indigestible polysaccharide, the prebiotics can stimulate the activation and growth of one or more beneficial bacteria in intestine. Similarly, Drakoularakou et al. [150] revealed in a randomized controlled study involving 159 healthy volunteers engaged in an international tourism that the incidence rate and the duration of diarrhea were reduced after the supplementation of Galactooligosaccharides (GOS). Regular supplementation of Fructooligosaccharides (FOS) is also related to increased serum intestinal peptide concentrations and decreased circulating C-reactive protein (CRP) levels [151]. As a result, although there are still few studies on the involvement of exercise in osteoimmunology regulation via GM and its metabolites [152], more and more relevant researches in recent years have indicated that GM has a potential immunomodulatory function and can build a bridge between exercise and osteoimmunology, indicating a novel research direction of exercise-bone-immunology. Collectively, the potential mechanism of exercise intervention on bone metabolism from the perspective of GM and its metabolites are summarized in Fig. 2.