Gut Microbiome - Should we treat the gut and not the bones?

Gut microbiome (GM) forms an integral part of homeostasis of an individual. Due to the recent development of metagenomics, the plausibility of sequencing GM and its therapeutic ability for various diseases has been explored. Dysbiosis or disequilibrium or pertubations of GM leads to disruption of intercommunication signaling among gut-bone axis, gut-bone-brain axis, and gut-disc axis resulting in the progression of various chronic diseases. The therapeutic interventions to restore the GM like prebiotics and probiotics, bacteriophage therapy, fecal microbiota transplantation, and physical biomodulation have been identified. This review throw the lime light on the effect of gut dysbiosis in musculoskeletal diseases.     

The structural and hormonal basis of sex differences in peak appendicular bone strength in rats.

To identify the structural and hormonal basis for the lower incidence of fractures in males than females, sex differences in femoral mid-shaft geometry and breaking strength were studied in growth hormone (GH)-replete and -deficient male and female rats. Sexual dimorphism appeared during growth. Cortical thickening occurred almost entirely by acquisition of bone on the outer (periosteal) surface in males and mainly on the inner (endocortical) surface in females. By 8 months of age, males had 22% greater bone width and 33% greater breaking strength than females. Gonadectomy (Gx) at 6 weeks reduced sex differences in bone width to 7% and strength to 21% by halving periosteal bone formation in males and doubling it in females. Gx had no net effect on the endocortical surface in males but abolished endocortical bone acquisition in females. GH deficiency halved periosteal bone formation and had no net effect on the endocortical surface in males, but abolished bone acquisition on both surfaces in females, leaving males with 17% greater bone width and 44% greater breaking strength than females. Sex hormone deficiency produces greater bone fragility in males than females by removing a stimulator of periosteal growth in males and removing an inhibitor of periosteal growth in females. GH deficiency produces less bone fragility in males than females because males retain androgen-dependent periosteal bone formation while bone acquisition on both surfaces is abolished in females. Thus, periosteal growth is independently and additively stimulated by androgens and GH in males, inhibited by estrogen, and stimulated by GH in females. The hormonal regulation of bone surfaces establishes the amount and spatial distribution of bone and so the sexual dimorphism in its strength.     

Bone and mineral metabolism in the adult guinea pig: long-term effects of estrogen and androgen deficiency.

The effects of androgen and estrogen deficiency on skeletal homeostasis were studied in the guinea pig. Male and female adult (7 months old) guinea pigs were either sham operated (9 females and 7 males) or gonadectomized [9 ovariectomized (OVX) females and 6 orchidectomized (ORX) males] and sacrificed 4 months later for evaluation of bone mass, bone turnover, and serum calcium homeostasis. Parameters of bone turnover, calcium homeostasis, and vitamin D metabolites were similar in all groups except for increased serum IGF-I concentrations (+30%) in males compared to females. Gonadectomy resulted in a 50% decrease in serum IGF-I concentrations in males only (p < 0.001). Volume, total calcium content, and cortical density of the tibia were significant higher in males than in females. Estrogen deficiency had no effect on bone volume or calcium content. Androgen deficiency resulted in a significant lower volume and calcium content of the tibia and in a lower calcium content of the distal lumbar vertebrae. Single-photon absorptiometry of the tibia showed that only cortical, not trabecular bone density of the tibia was decreased after ORX. Histomorphometric studies of the tibial metaphysis also did not show significant differences in trabecular bone volume between sham-operated and ORX males. We conclude that in adult male guinea pigs androgen deficiency results in a decrease in (cortical) bone volume and content concomitant with decreased IGF-I levels. In female guinea pigs of the same age, estrogen deficiency did not affect total or regional bone mass.     

Significance of the microbiome in obstructive lung disease

The composition of the lung microbiome contributes to both health and disease, including obstructive lung disease. Because it has been estimated that over 70% of the bacterial species on body surfaces cannot be cultured by currently available techniques, traditional culture techniques are no longer the gold standard for microbial investigation. Advanced techniques that identify bacterial sequences, including the 16S ribosomal RNA gene, have provided new insights into the depth and breadth of microbiota present both in the diseased and normal lung. In asthma, the composition of the microbiome of the lung and gut during early childhood development may play a key role in the development of asthma, while specific airway microbiota are associated with chronic asthma in adults. Early bacterial stimulation appears to reduce asthma susceptibility by helping the immune system develop lifelong tolerance to innocuous antigens. By contrast, perturbations in the microbiome from antibiotic use may increase the risk for asthma development. In chronic obstructive pulmonary disease, bacterial colonisation has been associated with a chronic bronchitic phenotype, increased risk of exacerbations, and accelerated loss of lung function. In cystic fibrosis, studies utilising culture-independent methods have identified associations between decreased bacterial community diversity and reduced lung function; colonisation with Pseudomonas aeruginosa has been associated with the presence of certain CFTR mutations. Genomic analysis of the lung microbiome is a young field, but has the potential to define the relationship between lung microbiome composition and disease course. Whether we can manipulate bacterial communities to improve clinical outcomes remains to be seen.     

Bone has a sexually dimorphic response to aromatase deficiency.

Aromatase synthesizes estrogen from androgen precursors. To better understand the role of estrogen in skeletal metabolism and growth, we have assessed long bone growth and histomorphometry in aromatase-deficient (ArKO) mice. The age range for the animals was 5-7 months. At this age mice have already achieved peak bone density but continue slow bone growth. Femur length, an index of long bone growth, showed decreased growth in ArKO males compared with wild-type (wt) littermates but no significant difference in females. Radiographically, compared with age- and sex- matched littermates both ArKO males and females showed osteopenia in the lumbar spine. Histologically, both ArKO males and females showed an osteoporotic-type picture, characterized by significant decreases in trabecular bone volume and trabecular thickness. However, compared with wt littermates female ArKO animals showed a bone remodeling picture consistent with increased bone turnover, much like early postmenopausal osteoporosis in humans. On the other hand, male ArKO animals showed decreases in both osteoblastic and osteoclastic surfaces compared with wt littermates, similar to age-related osteopenia. These findings suggest that osteoporosis seen in aromatase-deficient mice may arise from different bone remodeling activities between males and females. These results also show that the ArKO model exhibits the expected results of estrogen deficiency and may be a good model for investigating sex-specific responses to estrogen deficiency. Furthermore, they imply that estrogen is important for attaining peak bone mass in male as well as in female mice.     

Is puberty an accelerator of type 1 diabetes in IL6-174CC females?

The pubertal peak in onset of type 1 diabetes occurs earlier in girls than boys. We postulated that this sex difference might be mediated in part by estrogen or by genes regulated by estrogen, such as the interleukin-6 (IL6) gene. Previous studies concerning the role of an estrogen-sensitive single nucleotide polymorphism (SNP) in the IL6 promoter in type 1 diabetes have proved contradictory. We therefore selected a large, genetically homogenous population-based cohort, analyzed by age at onset and sex, to test the hypothesis that the IL6-174G>C SNP affects age at onset of type 1 diabetes in females but not in males. We found that the IL6-174CC genotype was significantly less frequent in females diagnosed after than in those diagnosed before the age of 10 years (19 vs. 13%, P = 0.016). No genotype difference was observed in males stratified for age at onset. Among children diagnosed after age 10, the median age of onset was 11.9 years (intraquartile range 10.7-14.6) in 34 girls homozygous for IL6-174C compared with 13.2 years (11.6-15.4) in 229 girls with other genotypes and 13.5 years (12.0-15.6) in 339 males with any IL6-174 genotype (P = 0.012). These data support the hypothesis that pubertal changes may contribute to accelerated onset of type 1 diabetes in genetically susceptible females. This phenomenon may be orchestrated by the action of estrogen on the IL6 promoter.     

Estrogen receptor-alpha and beta are differentially distributed, expressed and activated in the fetal genital tubercle

PURPOSE: We examined the ontogenic and sex specific expression of estrogen receptor-alpha and beta in mouse genital tubercles and assessed the effects of in utero estrogen exposure on these parameters. MATERIALS AND METHODS: Expression of the 2 genes was detected in mouse genital tubercles from fetuses collected on gestational days 12, 14, 16 and 18, and from newborns using immunohistochemistry and quantitative polymerase chain reaction. Pregnant dams were exposed to ethinyl estradiol or corn oil as the control. RESULTS: Estrogen receptor-alpha and beta proteins first appeared on gestational days 12 and 14, respectively. The 2 proteins were expressed in the urethral plate and mesenchyma. Staining intensity was more prominent in the mesenchyma for estrogen receptor-alpha and in the urethral plate for estrogen receptor-beta. Female genital tubercles expressed more estrogen receptor-alpha than male genital tubercles (p <0.01), while estrogen receptor-alpha expression increased gradually in the 2 sexes until birth. Estrogen receptor-beta expression did not differ between males and females, and it showed no notable variation during fetal life. Ethinyl estradiol led to a 2.1 and 3.8-fold increase in estrogen receptor-alpha expression in females and in males with hypospadias (p = 0.002 and 0.04, respectively). Estrogen receptor-beta expression did not change in response to ethinyl estradiol. CONCLUSIONS: This study provides in vivo evidence that estrogen receptor-alpha expression in the genital tubercles of each sex increases until parturition but estrogen receptor-beta expression does not, implying genital tubercle sensitivity to estrogen increases during fetal life. Exogenous administration of estrogens results in a response of increased expression of estrogen receptor-alpha but not of estrogen receptor-beta. These differential findings for estrogen receptor-alpha and beta imply that the 2 receptors may have different roles in normal or anomalous genital tubercle development.     

Links Between the Microbiome and Bone

The human microbiome has been shown to influence a number of chronic conditions associated with impaired bone mass and bone quality, including obesity, diabetes, and inflammatory bowel disease. The connection between the microbiome and bone health, however, has not been well studied. The few studies available demonstrate that the microbiome can have a large effect on bone remodeling and bone mass. The gut microbiome is the largest reservoir of microbial organisms in the body and consists of more than a thousand different species interacting with one another in a stable, dynamic equilibrium. How the microbiome can affect organs distant from the gut is not well understood but is believed to occur through regulation of nutrition, regulation of the immune system, and/or translocation of bacterial products across the gut endothelial barrier. Here we review each of these mechanisms and discuss their potential effect on bone remodeling and bone mass. We discuss how preclinical studies of bone‐microbiome interactions are challenging because the microbiome is sensitive to genetic background, housing environment, and vendor source. Additionally, although the microbiome exhibits a robust response to external stimuli, it rapidly returns to its original steady state after a disturbance, making it difficult to sustain controlled changes in the microbiome over time periods required to detect alterations in bone remodeling, mass, or structure. Despite these challenges, an understanding of the mechanisms by which the gut microbiome affects bone has the potential to provide insights into the dissociation between fracture risk and bone mineral density in patients including those with obesity, diabetes, or inflammatory bowel disease. In addition, alteration of the gut microbiome has the potential to serve as a biomarker of bone metabolic activity as well as a target for therapies to improve bone structure and quality using pharmaceutical agents or pre‐ or probiotics. © 2016 American Society for Bone and Mineral Research.     

Components of the Gut Microbiome That Influence Bone Tissue-Level Strength

Modifications to the constituents of the gut microbiome influence bone density and tissue-level strength, but the specific microbial components that influence tissue-level strength in bone are not known. Here, we selectively modify constituents of the gut microbiota using narrow-spectrum antibiotics to identify components of the microbiome associated with changes in bone mechanical and material properties. Male C57BL/6J mice (4 weeks) were divided into seven groups (n = 7–10/group) and had taxa within the gut microbiome removed through dosing with: (i) ampicillin; (ii) neomycin; (iii) vancomycin; (iv) metronidazole; (v) a cocktail of all four antibiotics together (with zero-calorie sweetener to ensure intake); (vi) zero-calorie sweetener only; or (vii) no additive (untreated) for 12 weeks. Individual antibiotics remove only some taxa from the gut, while the cocktail of all four removes almost all microbes. After accounting for differences in geometry, whole bone strength was reduced in animals with gut microbiome modified by neomycin (−28%, p = 0.002) and was increased in the group in which the gut microbiome was altered by sweetener alone (+39%, p < 0.001). Analysis of the fecal microbiota detected seven lower-ranked taxa differentially abundant in animals with impaired tissue-level strength and 14 differentially abundant taxa associated with increased tissue-level strength. Histological and serum markers of bone turnover and trabecular bone volume per tissue volume (BV/TV) did not differ among groups. These findings demonstrate that modifications to the taxonomic components of the gut microbiome have the potential to decrease or increase tissue-level strength of bone independent of bone quantity and without noticeable changes in bone turnover. © 2021 American Society for Bone and Mineral Research (ASBMR).     

Gut microbiome in hemodialysis patients treated with calcium acetate or treated with sucroferric oxyhydroxide: a pilot study

Purpose

It has been proved that the gut microbiome is altered in patients with chronic kidney disease. This contributes to chronic inflammation and increases cardiovascular risk and mortality, especially in those undergoing hemodialysis. Phosphate binders may potentially induce changes in their microbiome. This trial aimed to compare the changes in the gut microbiome of hemodialysis patients treated with calcium acetate to those treated with sucroferric oxyhydroxide.

Methods

Twelve hemodialysis patients were distributed to receive calcium acetate or sucroferric oxyhydroxide for 5 months. Blood samples (for biochemical analysis) and stool samples (for microbiome analysis) were collected at baseline, 4, 12, and 20 weeks after treatment initiation. Fecal DNA was extracted and a 16S rRNA sequencing library was constructed targeting the V3 and V4 hypervariable regions.

Results

Regarding clinical variables and laboratory parameters, no statistically significant differences were observed between calcium acetate or sucroferric oxyhydroxide groups. When analyzing stool samples, we found that all patients were different (p?=?0.001) among themselves and these differences were kept along the 20 weeks of treatment. The clustering analysis in microbial profiles grouped the samples of the same patient independently of the treatment followed and the stage of the treatment.

Conclusion

These results suggest that a 5-month treatment with either calcium acetate or sucroferric oxyhydroxide did not modify baseline diversity or baseline bacterial composition in hemodialysis patients, also about the high-variability profiles of the gut microbiome found among these patients.

     

Sex differences in the skin microbiome of burn scars

Sex differences are observed in various spectrums of skin diseases, and there are differences in wound healing rate. Herein, sex differences were identified for the newly healed skin microbiome of burn patients. Fifty-two skin samples (26 normal skin, 26 burn scars) were collected from 26 burn patients (12 male, 14 female) and microbiota analysis was performed. The correlation between skin microbiota and biomechanical properties of burn scars was also investigated. There were no significant differences in clinical characteristics between male and female patients. Considering the biomechanical properties of burn scars and normal skin around it performed before sample collection, the mean erythema level of men's normal skin was significantly higher than that of women, whereas the mean levels of melanin, transepidermal water loss and skin hydration showed no significant sex differences. The erythrocyte sedimentation rate was significantly higher in females than that in males. Alpha diversity showed no significant differences between normal skin and burn scars in the male group. However, the scar was significantly higher than that of normal skin in the female group. Microbial network analysis revealed that the male group had more complex microbial network than the female group. Additionally, in the male group, the edge density and clustering coefficient were higher in burn scars when compared to normal skin, than the female group. There were sex differences in the results of microbiome of normal skin and burn scars. Some of the altered microbiota have been correlated with the biomechanical properties of burn scars. In conclusion, sex difference in the burn scar microbiome was confirmed. These results suggest that burn treatment strategies should vary with sex.     

Increased fecal viral content associated with obesity in mice

AIMTo investigate the presence of total gut viral content in obese mice, and establish correlation with obesity associated metabolic measures and gut microbiome.METHODSFresh fecal samples were collected from normal and obese (Leptin deficient: Lep^ob/ob) mice. Total viral DNA and RNA was isolated and quantified for establishing the correlation with metabolic measures and composition of gut bacterial communities.RESULTSIn this report, we found that obese mice feces have higher viral contents in terms of total viral DNA and RNA (P < 0.001). Interestingly, these increased viral DNA and RNA content were tightly correlated with metabolic measures, i.e., body weight, fat mass and fasting blood glucose. Total viral content were positively correlated with firmicutes (R² > 0.6), whilst negatively correlated with bacteroidetes and bifidobacteria.CONCLUSIONThis study suggests the strong correlation of increased viral population into the gut of obese mice and opens new avenues to explore the role of gut virome in pathophysiology of obesity.     

Deletion of the androgen receptor in adipose tissue in male mice elevates retinol binding protein 4 and reveals independent effects on visceral fat mass and on glucose homeostasis

Testosterone deficiency is epidemic in obese ageing males with type 2 diabetes, but the direction of causality remains unclear. Testosterone-deficient males and global androgen receptor (AR) knockout mice are insulin resistant with increased fat, but it is unclear whether AR signaling in adipose tissue mediates body fat redistribution and alters glucose homoeostasis. To investigate this, mice with selective knockdown of AR in adipocytes (fARKO) were generated. Male fARKO mice on normal diet had reduced perigonadal fat but were hyperinsulinemic and by age 12 months, were insulin deficient in the absence of obesity. On high-fat diet, fARKO mice had impaired compensatory insulin secretion and hyperglycemia, with increased susceptibility to visceral obesity. Adipokine screening in fARKO mice revealed a selective increase in plasma and intra-adipose retinol binding protein 4 (RBP4) that preceded obesity. AR activation in murine 3T3 adipocytes downregulated RBP4 mRNA. We conclude that AR signaling in adipocytes not only protects against high-fat diet-induced visceral obesity but also regulates insulin action and glucose homeostasis, independently of adiposity. Androgen deficiency in adipocytes in mice resembles human type 2 diabetes, with early insulin resistance and evolving insulin deficiency.     

Estrogen receptor expression in lumbar intervertebral disc of the elderly: Gender- and degeneration degree-related variations

ObjectivesSexual dimorphism does occur in intervertebral disc (IVD) degeneration. The involvement of estrogen on IVD health has been well reported in recent years. The estrogen receptors (ER) are the main mediators of estrogen action. ER might play specific roles in the sexual variations of the IVD degeneration.MethodsThirty-six elderly patients with lumbar disc degeneration were selected and graded using Pfirrmann's system based on MRI images. Differences of ERα and ERβ immunoreactivity staining in nucleus pulposus of each sex and degeneration degree were recorded and compared.ResultsBoth cytoplasmic and nuclear staining of ERα and ERβ immunoreactivity were observed in the nucleus pulposus cells. ERα and ERβ expression significantly decreased along with the aggravation of IVD degeneration both in males and females. Expression of ERα and ERβ protein in nucleus pulposus of males was significantly higher than that of females.ConclusionsGender-specific expression of ER might play a part in sexual dimorphism of IVD degeneration. Gender and degeneration condition differences should be taken into account when the effects of estrogen on IVD metabolism are studied further.     

Estrogen-related gender difference in survival rate and cortical blood flow after impact-acceleration head injury in rats

While a number of laboratories have begun to examine gender differences in outcome following experimental stroke, little is known about the relative response of male and female brains to traumatic injury. In the following series of experiments, we used the Marmarou impact-acceleration head injury model (with a 500-g, 1.5-m weight drop) to compare the pathophysiological responses of male and female rats to closed-head injury. Cortical blood flow (CBF; laser-doppler flowmetry), mean arterial blood pressure (MAP), blood gas levels, blood pH, and body temperature were measured preinjury and at regular intervals postinjury. Acute survival was assessed 1 h after injury. The role of estrogen in the observed gender differences was assessed by examining these physiological measures after injury in ovariectomized females, with or without 17beta-estradiol replacement, and in intact males, with or without exogenous 17beta-estradiol administration. In the first experiment, significantly more females (100%) survived the acute injury period (60 min) after injury than did males (72%). Survival appeared related to the magnitude and persistence of the posttraumatic drop in MAP. In a second experiment, females showed a less dramatic reduction in and better recovery of CBF than males. The gender difference in CBF was paralleled to some degree by differences in the pattern of MAP changes after injury. Differences in body weight, blood gas levels, or blood pH did not account for the gender difference in CBF. Postinjury CBF was higher in female and male rats given 2 weeks of daily 17beta-estradiol injections prior to injury compared to those given the vehicle only. However, 17beta-estradiol administration did not alter MAP, suggesting that the gender difference in CBF was not strictly due to MAP changes. Our findings suggest that estrogen plays a role in maintaining adequate cerebral perfusion in the acute period following closed-head injury. This protective mechanism may underlie the gender difference in acute survival observed in this study, and may help explain observations of better outcome in females than in males after brain injury. We conclude that CBF preservation is one mechanism by which estrogen is neuroprotective following traumatic brain injury. We hypothesize, based upon known effects of estrogen, that the beneficial microvascular effects of estrogen most likely involve a combination of endothelial nitric oxide synthase induction and an antioxidant effect.     

Integrating insulin-like growth factor 1 and sex hormones into neuroprotection: Implications for diabetes

Brain integrity and cognitive aptitude are often impaired in patients with diabetes mellitus, presumably a result of the metabolic complications inherent to the disease. However, an increasing body of evidence has demonstrated the central role of insulin-like growth factor 1(IGF1) and its relation to sex hormones in many neuroprotective processes. Both male and female patients with diabetes display abnormal IGF1 and sexhormone levels but the comparison of these fluctuations is seldom a topic of interest. It is interesting to note that both IGF1 and sex hormones have the ability to regulate phosphoinositide 3-kinase-Akt and mitogen-activated protein kinases-extracellular signal-related kinasesignaling cascades in animal and cell culture models of neuroprotection. Additionally, there is considerable evidence demonstrating the neuroprotective coupling of IGF1 and estrogen. Androgens have also been implicated in many neuroprotective processes that operate on similar signaling cascades as the estrogen-IGF1 relation. Yet, androgens have not been directly linked to the brain IGF1 system and neuroprotection. Despite the sex-specific variations in brain integrity and hormone levels observed in diabetic patients, the IGF1-sex hormone relation in neuroprotection has yet to be fully substantiated in experimental models of diabetes. Taken together, there is a clear need for the comprehensive analysis of sex differences on brain integrity of diabetic patients and the relationship between IGF1 and sex hormones that may influence brain-health outcomes. As such, this review will briefly outline the basic relation of diabetes and IGF1 and its role in neuroprotection. We will also consider the findings on sex hormones and diabetes as a basis for separately analyzing males and females to identify possible hormone-induced brain abnormalities. Finally, we will introduce the neuroprotective interplay of IGF1 and estrogen and how androgen-derived neuroprotection operates through similar signaling cascades. Future research on both neuroprotection and diabetes should include androgens into the interplay of IGF1 and sex hormones.     

Impact of female sex hormones on liver tissue lactic acidosis during ischemia

BACKGROUND: Lower liver transplant success is observed when the donor is female. Intracellular acidosis during ischemia is proposed to contribute to the injury sustained by the transplanted organ and its role in livers obtained from nonheartbeating donors is unclear. Research has shown that livers of female rats develop a greater degree of intracellular acidosis during ischemia than males. This work explores the role of sex hormones in mediating this sex difference. METHODS: Subgroups of neutered female rats were given 17 beta-estradiol (E), progesterone (P), or combination (E+P). To compare the effects of female sex hormones in males, subgroups of intact and castrated males received 17 beta-estradiol. In vivo and ischemic liver biopsies were taken and analyzed for lactate and H. RESULTS: Although there was no effect of hormone therapy on baseline metabolic parameters, during ischemia compared to neutered females, livers from E females significantly (P<0.01) increased lactate by 56% and H+ by 71%, while E+P significantly increased only lactate (39%; P<0.05). Livers from neutered males given 17 beta-estradiol showed significantly greater (P<0.001) accumulation of lactate (80%) and H+ (79%). This was even shown in intact males, where despite a blunted response, 17 beta-estradiol, significantly (P<0.05) increased lactate by 39% and H+ by 25%. CONCLUSION: This study illustrates the mechanisms for the sex difference in the liver's metabolic response to ischemia are estrogen mediated, which is seen even in the presence of male hormones, thus offering one explanation for the lower liver transplant success when the donor is female.     

Marked gender effect on lipid peroxidation after severe traumatic brain injury in adult patients

Striking gender differences have been reported in the pathophysiology and outcome of acute neurological injury. Greater neuroprotection in females versus males may be due, in part, to direct and indirect sex hormone-mediated antioxidant mechanisms. Progesterone administration decreases brain levels of F(2)-isoprostane, a marker of lipid peroxidation, after experimental traumatic brain injury (TBI) in male rats, and estrogen is neuroprotective in experimental neurological injury. In this study, we evaluated the effect of gender on lipid peroxidation, as assessed by cerebrospinal fluid (CSF) levels of F(2)-isoprostane, after severe TBI in humans. Lipid peroxidation was assessed in CSF from 68 adults enrolled in two randomized controlled trials evaluating the effect of therapeutic hypothermia after severe TBI (Glasgow coma scale [GCS] score 相似文献   

Osteoarthritis severity is sex dependent in a surgical mouse model

OBJECTIVE: To investigate the role of sex hormones in cartilage degradation and progression of osteoarthritis (OA) in a murine model induced by destabilization of the medial meniscus (DMM). DESIGN: Accelerated OA development in mice was induced by transection of the menisco-tibial ligament, which anchors the medial meniscus to the tibial plateau. Intact male and female, and orchiectomized (ORX) male and ovariectomized (OVX) female mouse knee histology were compared for signs of OA following DMM. The effect of testosterone or estrogen addition in vivo was assessed in ORX males in the surgical OA model. RESULTS: OA severity was markedly higher in males than females after DMM. OVX females developed significantly more severe OA than control females. ORX males developed significantly less severe OA than control males. When ORX male mice were supplemented with exogenous dihydrotestosterone (DHT), the severity of OA was restored to the level experienced by the control male mice. Hip cartilage from mice of both sexes demonstrated similar spontaneous and interleukin-1alpha (IL-1alpha) induced proteoglycan (PG) release in vitro. DHT and 17-beta estradiol (E2) did not significantly alter the PG release pattern when supplemented to cartilage cultures of either sex. CONCLUSION: Sex hormones play a critical role in the progression of OA in the murine DMM surgical model, with males having more severe OA than females. Intact females had more OA than OVX females, indicating that ovarian hormones decrease the severity of OA in the female mice. Male hormones, such as testosterone, exacerbate OA in male mice as demonstrated by the fact that ORX mice experienced less OA than intact males, and that addition of DHT to ORX males was able to counteract the effect of castration and re-establish severe OA.     

Liver tissue microbiota in nonalcoholic liver disease: a change in the paradigm of host-bacterial interactions

Nonalcoholic fatty liver disease (NAFLD) pathogenesis is explained by the complex relationship among diet and lifestyle-predisposing factors, the genetic variance of the nuclear and mitochondrial genome, associated phenotypic traits, and the yet not fully explored interactions with epigenetic and other environmental factors, including the microbiome. Despite the wealth of knowledge gained from molecular and genome-wide investigations in patients with NAFLD, the precise mechanisms that explain the variability of the histological phenotypes are not fully understood. Earlier studies of the gut microbiota in patients with NAFLD and nonalcoholic steatohepatitis (NASH) provided clues on the role of the fecal microbiome in the disease pathogenesis. Nevertheless, the composition of the gut microbiota does not fully explain tissue-specific mechanisms associated with the degree of disease severity, including liver inflammation, ballooning of hepatocytes, and fibrosis. The liver acts as a key filtration system of the whole body by receiving blood from the hepatic artery and the portal vein. Therefore, not only microbes would become entrapped in the complex liver anatomy but, more importantly, bacterial derived products that are likely to be potentially powerful stimuli for initiating the inflammatory response. Hence, the study of liver tissue microbiota offers the opportunity of changing the paradigm of host-NAFLD-microbial interactions from a “gut-centric” to a “liver-centric” approach. Here, we highlight the evidence on the role of liver tissue bacterial DNA in the biology of NAFLD and NASH. Besides, we provide evidence of metagenomic findings that can serve as the seed of further hypothesis-raising studies as well as can be leveraged to discover novel therapeutic targets.