24小时快速起搏右心房对兔心房单向动作电位的影响

目的应用心内电生理技术研究心房快速起搏(RAP)对兔心房单向动作电位(MAP)的影响。方法成年新西兰兔20只随机分为二组:假手术组、模型组各10只。经颈内静脉将电极置入右心房。以600次/分行RAP,同时分析在0、4、8、12和24h的单向动作电位时程(MAPD)。结果假手术组在实验的时间段内右房游离壁MAP复极90%时程(MAPD90)无明显差别。RAP8h,起搏组右房游离壁MAPD90较P0有明显缩短,从起搏前(112.50±9.57)ms至起搏8h分别缩短到(51.25±4.79)ms,分别缩短了61.25ms。结论房颤(AF)时心房MAPD90缩短。MAP技术可安全地用于研究AF时的电重构(ER),能提供准确的电生理改变的信息。     

采用系统生物学方法分析乳腺癌转移中Runx2对细胞外基质重塑的调节机制

摘要细胞外基质(extracellular matrix,ECM)重塑是癌细胞迁移的关键步骤.本研究基于乳腺癌组织的基因表达谱数据,采用系统生物学方法推测乳腺癌转移中Runx2对细胞外基质重塑的调节机制.采用相关性分析程序分析49例乳腺原发癌和15例淋巴结转移癌组织的基因表达谱数据,筛选与Runx2呈相关性表达的基因,结果得到与ECM重塑相关的候选基因52个,包括ECM成分11个,ECM降解酶及其抑制剂8个,细胞信号分子33个.利用转录调节因子结合序列数据库搜索候选基因启动子区的Runx2结合模序,筛选其中Runx2转录调控的ECM重塑相关基因,并判断可能调节Runx2的上游信号分子;文献检索实验证实的与Runx2有相互调节关系的基因,并基于Runx2上游调控信号分子和下游转录调节基因的分析,构建得到以Runx2为中心的ECM重塑的生物学调控网络.WNT和TGF/BMPs是启动Runx2表达的主要信号通路,Runx2通过转录调节ECM组分、ECM降解酶及其抑制剂和信号分子调节ECM重塑,促进癌细胞完成转移的生物学过程.     

肌球蛋白X在细胞运动中的作用

肌球蛋白X(myosin X,Myo X)是一类尾部具有MyTH4(myosin tail homology 4,MyTH4)和FERM(band4.1/ezrin/radixin/moesin,FERM)结构域的非传统型肌球蛋白,广泛分布于脊椎动物细胞中.近几年的研究表明,Myo X尾部结构域能够与众多的信号分子相互作用,参与调节从丝状伪足形成到胞质分裂等多种细胞运动过程,但其具体的调控机制目前尚不完全清楚.Myo X作为一类连接细胞膜与细胞骨架的动力蛋白分子,它的研究越来越受到人们的关注,其功能的揭示将为进一步阐明细胞多种运动机制提供理论依据.     

Introduction of phospholipids to cultured cells with cyclodextrin

Previous studies indicate that methyl-β-cyclodextrin (meβ-CD) can greatly enhance translocation of long-chain phospholipids from vesicles to cells in culture, which is very useful when studying, e.g., phospholipid metabolism and trafficking. However, the parameters affecting the transfer have not been systematically studied. Therefore, we studied the relevant parameters including meβ-CD and vesicle concentration, incubation time, phospholipid structure, and cell type. Because meβ-CD can extract cholesterol and other lipids from cells, thereby potentially altering cell growth or viability, these issues were studied as well. The results show that efficient incorporation of phospholipid species with hydrophobicity similar to that of natural species can be obtained without significantly compromising cell growth or viability. Cellular content of phosphatidyl-serine, -ethanolamine, and -choline could be increased dramatically, i.e., 400, 125, and 25%, respectively. Depletion of cellular cholesterol could be prevented or alleviated by inclusion of the proper amount of cholesterol in the donor vesicles. In summary, meβ-CD mediates efficient transfer of long-chain (phospho) lipids from vesicles to cells without significantly compromising their growth or viability. This lays a basis for detailed studies of phospholipid metabolism and trafficking as well as enables extensive manipulation of cellular phospholipid composition, which is particularly useful when investigating mechanisms underlying phospholipid homeostasis.     

Cell elongation is key to in silico replication of in vitro vasculogenesis and subsequent remodeling

Vasculogenesis, the de novo growth of the primary vascular network from initially dispersed endothelial cells, is the first step in the development of the circulatory system in vertebrates. In the first stages of vasculogenesis, endothelial cells elongate and form a network-like structure, called the primary capillary plexus, which subsequently remodels, with the size of the vacancies between ribbons of endothelial cells coarsening over time. To isolate such intrinsic morphogenetic ability of endothelial cells from its regulation by long-range guidance cues and additional cell types, we use an in vitro model of human umbilical vein endothelial cells (HUVEC) in Matrigel. This quasi-two-dimensional endothelial cell culture model would most closely correspond to vasculogenesis in flat areas of the embryo like the yolk sac. Several studies have used continuum mathematical models to explore in vitro vasculogenesis: such models describe cell ensembles but ignore the endothelial cells' shapes and active surface fluctuations. While these models initially reproduce vascular-like morphologies, they eventually stabilize into a disconnected pattern of vascular "islands." Also, they fail to reproduce temporally correct network coarsening. Using a cell-centered computational model, we show that the endothelial cells' elongated shape is key to correct spatiotemporal in silico replication of stable vascular network growth. We validate our simulation results against HUVEC cultures using time-resolved image analysis and find that our simulations quantitatively reproduce in vitro vasculogenesis and subsequent in vitro remodeling.     

Cortical bone remodeling rates in a sample of African American and European American descent groups from the American Midwest: comparisons of age and sex in ribs

This study employs regression analysis to explore population and sex differences in the pattern of age-associated bone loss, as reflected by histomorphometric variables that are measures of intracortical and endocortical bone remodeling. A comparison of an African American sample from the Washington Park Cemetery in St. Louis, Missouri, and a European American rib sample composed of cadavers, autopsies, and forensic cases from Missouri reveals the existence of complex age-associated patterns for differences in measures of intracortical remodeling and cortical area. Females from the two samples express similar bone dimensions and dynamics. The African American females appear to lose more bone than their male counterparts, but this difference is absent in the European American sample. When age-associated patterns are considered, it is in the younger cohorts that African Americans exhibit greater relative cortical area than European Americans, but this is reversed in the older ages, when the latter group manifests greater bone mass. The European American males consistently differ in the slopes and intercepts for the variables compared to the other groups, and differences are highly significant with African American females, with the former group maintaining bone mass while the latter exhibit a more rapid bone loss. Achieving larger relative cortical area due to smaller endosteal area, coupled with better bone quality due to lower intracortical porosity early in life, may be a mechanism by which African Americans, especially females, maintain adequate bone mass in older ages, which buffers them from bone loss and related fragility fractures despite higher rates of intracortical remodeling and endosteal expansion later in life. These results suggest that both genetic and environmental factors are responsible for the differences in bone remodeling and bone mass observed between these samples.     

Three routes to suppression of the neurodegenerative phenotypes caused by Kinesin heavy chain mutations

Kinesin-1 is a motor protein that moves stepwise along microtubules by employing dimerized kinesin heavy chain (Khc) subunits that alternate cycles of microtubule binding, conformational change, and ATP hydrolysis. Mutations in the Drosophila Khc gene are known to cause distal paralysis and lethality preceded by the occurrence of dystrophic axon terminals, reduced axonal transport, organelle-filled axonal swellings, and impaired action potential propagation. Mutations in the equivalent human gene, Kif5A, result in similar problems that cause hereditary spastic paraplegia (HSP) and Charcot-Marie-Tooth type 2 (CMT2) distal neuropathies. By comparing the phenotypes and the complementation behaviors of a large set of Khc missense alleles, including one that is identical to a human Kif5A HSP allele, we identified three routes to suppression of Khc phenotypes: nutrient restriction, genetic background manipulation, and a remarkable intramolecular complementation between mutations known or likely to cause reciprocal changes in the rate of microtubule-stimulated ADP release by kinesin-1. Our results reveal the value of large-scale complementation analysis for gaining insight into protein structure-function relationships in vivo and point to possible paths for suppressing symptoms of HSP and related distal neuropathies.