大鼠骨骼肌损伤后中性粒细胞、巨噬细胞和肌成纤维细胞数量分析研究

目的 研究大鼠骨骼肌损伤后中性粒细胞、巨噬细胞和肌成纤维细胞数量的变化情况,为今后骨骼肌损伤修复的病理学机制研究打下坚实的基础.方法 建立大鼠骨骼肌机械性损伤动物模型,随机分为伤后6h、12h、1d、3d、7d、10d、14d及正常对照组.应用免疫组织荧光染色和免疫组织化学染色,检测大鼠骨骼肌损伤后不同时间点中性粒细胞、巨噬细胞和肌成纤维细胞的数量.结果 伤后6h-12h,损伤区可见中性粒细胞和巨噬细胞浸润,中性粒细胞数量达到高峰.伤后1d,损伤区巨噬细胞数量急剧增加,迅速达到高峰,而中性粒细胞数量开始下降.伤后3d,中性粒细胞和巨噬细胞数量都显著下降.伤后7d,肌成纤维细胞开始出现.到伤后10d-14d,损伤区主要以肌成纤维细胞为主,偶见巨噬细胞.结论 大鼠骨骼肌损伤区中性粒细胞、巨噬细胞和肌成纤维细胞数量呈时间规律性变化,以期为骨骼肌损伤修复的病理学机制研究提供参考资料.     

冬眠动物骨骼肌生理适应及机制的研究进展

非冬眠动物的骨骼肌在废用条件下会发生明显的萎缩。冬眠动物在历经数月的冬眠期骨骼肌废用后,仍能保持较完整的形态结构与良好的收缩功能,成为天然的抗废用性肌萎缩动物模型。探明冬眠动物骨骼肌对废用的生理适应机制,是生理生态学领域的重要课题之一。本文从形态结构、肌纤维类型和收缩功能等方面综述了冬眠动物对冬眠期骨骼肌废用状态的生理适应,并从蛋白质代谢、生长与分化的调控、代谢类型的调控、氧化应激以及线粒体结构与氧化能力等方面分析了冬眠期骨骼肌生理适应的可能机制。     

The role of GDF11 in aging and skeletal muscle,cardiac and bone homeostasis

GDF11 is a secreted factor in the TGFß family of cytokines. Its nearest neighbor evolutionarily is myostatin, a factor discovered as being a negative regulator of skeletal muscle growth. High profile studies several years ago suggested that GDF11 declines with age, and that restoration of systemic GDF11 to ‘youthful’ levels is beneficial for several age-related conditions. Particularly surprising was a report that supplementation of GDF11 aided skeletal muscle regeneration, as its homolog, myostatin, has the opposite role. Given this apparent contradiction in functionality, multiple independent labs sought to discern differences between the two factors and better elucidate age-related changes in circulating GDF11, with most failing to reproduce the initial finding of declining GDF11 levels, and, importantly, all subsequent studies examining the effects of GDF11 on skeletal muscle described an inhibitory effect on regeneration – and that higher doses induce skeletal muscle atrophy and cachexia. There have also been several studies examining the effect of GDF11 and/or the downstream ActRII pathway on cardiac function, along with several interesting reports on bone. A review of the GDF11 literature, as it relates in particular to aging and skeletal muscle, cardiac and bone biology, is presented.     

Differential expression profiles of miRNA in the serum of sarcopenic rats

As the geriatric population and life expectancy increase, the interest in preventing geriatric diseases, such as sarcopenia, is increasing. However, the causes of sarcopenia are unclear, and current diagnostic methods for sarcopenia are unreliable. We hypothesized that the changes in the expression of certain miRNAs may be associated with the pathophysiology of sarcopenia. Herein, we analyzed the miRNA expression profiles in the blood of young (3-months-old) healthy rats, old sarcopenic (17-months-old) rats, and age-matched (17-months-old) control rats. The changes in miRNA expression levels were analyzed using Bowtie 2 software. A total of 523 miRNAs were detected in the rat serum. Using scatter plots and clustering heatmap data, we found 130 miRNAs that were differentially expressed in sarcopenic rats (>2-fold change) compared to the expression in young healthy and age-matched control rats. With a threshold of >5-fold change, we identified 14 upregulated miRNAs, including rno-miR-133b-3p, rno-miR-133a-3p, rno-miR-133c, rno-miR-208a-3p, and rno-miR434-5p among others in the serum of sarcopenic rats. A protein network map based on these 14 miRNAs identified the genes involved in skeletal muscle differentiation, among which Notch1, Egr2, and Myocd represented major nodes. The data obtained in this study are potentially useful for the early diagnosis of sarcopenia and for the identification of novel therapeutic targets for the treatment and/or prevention of sarcopenia.     

Wolframin deficiency is accompanied with metabolic inflexibility in rat striated muscles

The protein wolframin is localized in the membrane of the endoplasmic reticulum (ER), influencing Ca2+ metabolism and ER interaction with mitochondria, but the exact role of the protein remains unclear. Mutations in Wfs1 gene cause autosomal recessive disorder Wolfram syndrome (WS). The first symptom of the WS is diabetes mellitus, so accurate diagnosis of the disease as WS is often delayed. In this study we aimed to characterize the role of the Wfs1 deficiency on bioenergetics of muscles. Alterations in the bioenergetic profiles of Wfs1-exon-5-knock-out (Wfs1KO) male rats in comparison with their wild-type male littermates were investigated using high-resolution respirometry, and enzyme activity measurements. The changes were followed in oxidative (cardiac and soleus) and glycolytic (rectus femoris and gastrocnemius) muscles. There were substrate-dependent alterations in the oxygen consumption rate in Wfs1KO rat muscles. In soleus muscle, decrease in respiration rate was significant in all the followed pathways. The relatively small alterations in muscle during development of WS, such as increased mitochondrial content and/or increase in the OxPhos-related enzymatic activity could be an adaptive response to changes in the metabolic environment. The significant decrease in the OxPhos capacity is substrate dependent indicating metabolic inflexibility when multiple substrates are available.     

FGF9 regulates early hypertrophic chondrocyte differentiation and skeletal vascularization in the developing stylopod

Gain-of-function mutations in fibroblast growth factor (FGF) receptors result in chondrodysplasia and craniosynostosis syndromes, highlighting the critical role for FGF signaling in skeletal development. Although the FGFRs involved in skeletal development have been well characterized, only a single FGF ligand, FGF18, has been identified that regulates skeletal development during embryogenesis. Here we identify Fgf9 as a second FGF ligand that is critical for skeletal development. We show that Fgf9 is expressed in the proximity of developing skeletal elements and that Fgf9-deficient mice exhibit rhizomelia (a disproportionate shortening of proximal skeletal elements), which is a prominent feature of patients with FGFR3-induced chondrodysplasia syndromes. Although Fgf9 is expressed in the apical ectodermal ridge in the limb bud, we demonstrate that the Fgf9-/- limb phenotype results from loss of FGF9 functions after formation of the mesenchymal condensation. In developing stylopod elements, FGF9 promotes chondrocyte hypertrophy at early stages and regulates vascularization of the growth plate and osteogenesis at later stages of skeletal development.     

海藻酸钙对骨质疏松症大鼠骨骼肌SDF-1含量和骨密度的影响

摘要 目的：探讨海藻酸钙对骨质疏松症大鼠骨骼肌基质细胞衍生因子-1（Stromal Cell-derived Factor-1,SDF-1）含量和骨密度的影响。方法：骨质疏松症大鼠（n=48）随机平分为三组-模型组、尼尔雌醇组与海藻酸钙组,在建模后1周后三组分别给予双蒸水、0.1 mg/100 g尼尔雌醇与37.5 mg/mL海藻酸钙/枸杞多糖凝胶微球水溶液灌胃治疗,1 次/d,检测大鼠骨骼肌SDF-1含量和骨密度变化情况。结果：（1）尼尔雌醇组与海藻酸钙组给药第4周与第8周的血清钙离子含量高于模型组（P<0.05）,磷离子含量低于模型组（P<0.05）,尼尔雌醇组与海藻酸钙组对比差异有统计学意义（P<0.05）;（2）尼尔雌醇组与海藻酸钙组给药第4周与第8周的骨骼肌SDF-1含量低于模型组（P<0.05）,海藻酸钙组低于尼尔雌醇组（P<0.05）;（3）尼尔雌醇组与海藻酸钙组给药第4周与第8周的腰椎和股骨骨密度高于模型组（P<0.05）,海藻酸钙组低于尼尔雌醇组（P<0.05）;（4）尼尔雌醇组与海藻酸钙组给药第4周与第8周的股骨最大载荷、最大应力高于模型组(P<0.05),海藻酸钙组高于尼尔雌醇组（P<0.05）;（5）海藻酸钙组造血细胞数量较多,骨皮质结构较完整,致密均匀粗壮,小梁数目明显增多,骨髓腔变小。结论：海藻酸钙在骨质疏松症大鼠的应用能抑制骨骼肌SDF-1的释放,有助于提高骨密度,改善骨生物力学指标,提高血清钙离子含量,降低磷离子含量。     

Impact of apolipoprotein A1- or lecithin:cholesterol acyltransferase-deficiency on white adipose tissue metabolic activity and glucose homeostasis in mice

High density lipoprotein (HDL) has attracted the attention of biomedical community due to its well-documented role in atheroprotection. HDL has also been recently implicated in the regulation of islets of Langerhans secretory function and in the etiology of peripheral insulin sensitivity. Indeed, data from numerous studies strongly indicate that the functions of pancreatic β-cells, skeletal muscles and adipose tissue could benefit from improved HDL functionality. To better understand how changes in HDL structure may affect diet-induced obesity and type 2 diabetes we aimed at investigating the impact of Apoa1 or Lcat deficiency, two key proteins of peripheral HDL metabolic pathway, on these pathological conditions in mouse models. We report that universal deletion of apoa1 or lcat expression in mice fed western-type diet results in increased sensitivity to body-weight gain compared to control C57BL/6 group. These changes in mouse genome correlate with discrete effects on white adipose tissue (WAT) metabolic activation and plasma glucose homeostasis. Apoa1-deficiency results in reduced WAT mitochondrial non-shivering thermogenesis. Lcat-deficiency causes a concerted reduction in both WAT oxidative phosphorylation and non-shivering thermogenesis, rendering lcat^?/? mice the most sensitive to weight gain out of the three strains tested, followed by apoa1^?/? mice. Nevertheless, only apoa1^?/? mice show disturbed plasma glucose homeostasis due to dysfunctional glucose-stimulated insulin secretion in pancreatic β-islets and insulin resistant skeletal muscles. Our analyses show that both apoa1^?/? and lcat^?/? mice fed high-fat diet have no measurable Apoa1 levels in their plasma, suggesting no direct involvement of Apoa1 in the observed phenotypic differences among groups.