利用启动子缺陷型打靶载体敲除五指山小型猪GGTA1基因

目的:获得α-1,3-半乳糖基转移酶(GGTA1)基因敲除的五指山小型猪胎儿,为异种器官移植研究提供基础平台。方法:以新霉素磷酸转移酶基因(neo)为筛选标记基因构建启动子缺陷型打靶载体,打靶载体线性化后用电转染法将其导入胎儿成纤维细胞中,转染后的细胞经G418筛选后,用PCR法检测药物抗性的细胞克隆,对阳性细胞进行核移植构建重构胚胎及胚胎移植。结果:转染后,经筛选共得到176个具有G418抗性的细胞克隆,经PCR检测,其中2个细胞克隆发生了同源重组;以其中1个GGTA1+/-细胞克隆为供体细胞进行核移植,将重构胚移植到2头自然发情的受体母猪中,1头受体妊娠;第37 d将代孕母猪处死,获得2个胎儿,经PCR和Southern印迹鉴定,均为GGTA1单等位基因敲除胎儿。结论:构建了五指山小型猪GGTA1基因部分外显子4区域敲除的启动子缺陷型打靶载体,获得了GGTA1单等位基因敲除的胎儿,为培育GGTA1基因敲除的五指山小型猪奠定了基础。     

猪肌肉生长抑制素基因侧翼区新微卫星标记的鉴定及分析

提取包含猪肌肉生长抑制素基因的BAC克隆,以EcoRⅠ进行酶切并回收其中大于4kh的酶切产物,连接到pGEM-3zf( )载体后得到了亚克隆。测序分析表明,插入片段不属于猪肌肉生长抑制素基因的一部分,但其中包含13拷贝的(TG)n重复。以该重复序列的侧翼设计引物对猪的基因组进行分析,得到了PCR扩增产物。对一个“双肌臀”大白猪家系进行PCR扩增及非变性聚丙烯酰胺凝胶分析的结果表明,该位点以并显性方式遗传,是一个新的微卫星标记。对莱芜猪、长白猪、大白猪、杜洛克、皮特兰、民猪和二花脸7个品种的381个无关个体的检测均显示该基因座只有两个等位基因,重复数分别为13和19,是一种多态性较低的微卫星标记。与包含该基因的序列(AY208121)比对分析表明,该微卫星属于肌肉生长抑制素基因(MSTN)侧翼区的一个分子标记,在猪肉用性状QTL的精细定位和MSTN功能分析中将发挥重要作用。     

不同品种猪肌肉生长抑制素基因单核苷酸多态性分析

用PCR-RFLPs和PCR-SSCP分析方法,对"双肌臀”大白猪、大白猪、长白猪、杜洛克、汉普夏、皮特兰、二花脸、东北民猪、湖北白猪和部分杂交猪等不同品种猪肌肉生长抑制素基因3＇编码区、5＇调控区及内含子1区3个单核苷酸多态性位点(SNPs)进行了分析.结果表明,3＇编码区的SNP发生的频率较低,在274头猪中未检出突变纯合体.对5＇调控区的SNP,引进猪种(大白猪、长白猪、杜洛克、汉普夏和皮特兰)及其杂交猪以等位基因T为主,二花脸和湖北白猪则以等位基因A为主,均偏离Hardy-Weinberg平衡状态(P＜0.01).东北民猪的3种基因型近乎相等,处于Hardy-Weinberg衡状态.对内含子1区的SNP,大白猪及其与长白猪的杂交猪等位基因G占优势,二花脸和湖北白猪则以等位基因A为主,均偏离Hardy-Weinberg平衡状态(P＜0.01);东北民猪和大二猪的等位基因G和A近乎相等,处于Hardy-Weinberg平衡状态."双肌臀”大白猪在5＇调控区和内含子1区这两个位点的A等位基因稍高于普通大白猪.5＇调控区和内含子1区SNPs所产生的等位基因表现出连锁遗传现象.     

肌肉生长抑制素基因在哺乳动物中的最新研究进展

肌肉生长抑制素（myostatin,MSTN）,也称为生长分化因子8（GDF8）,是转化生长因子β（TGF-β）超家族成员,主要在骨骼肌中表达,在负向调控肌细胞的生长发育中起关键作用。本文对MSTN研究的最新进展进行了综述,讨论了MSTN信号通路与其他通路之间的相互关系,重点阐述了试验条件下MSTN对肌肉发育相关基因的作用,介绍了通过基因操作或使用抗体的方法抑制MSTN的表达对于提高动物产肉量、治疗肌肉萎缩等疾病以及延缓衰老的重要意义。     

用Cre/LoxP和CRISPR基因工程技术构建猪肌肉生长抑制素双等位基因敲除细胞系

肌肉生长抑制素 (myostatin,Mstn)基因失活可引起哺乳动物的肌肉增生,但其调控机制尚不清楚,且缺乏可靠的试验材料验证Mstn相关分子通路的变化。本研究所用PK3108细胞系是在野生型PK15细胞系的基础上成功靶向敲除一条等位基因,在其靶位点敲入标记基因,敲除了204 bp的外显子3序列, LoxP锚定在其标记基因两侧。利用Cre/LoxP重组酶删除系统删除插入PK3108Mstn靶位点的标记,借助流式细胞仪和荧光蛋白甄别得到无标记的过渡型细胞系PK3108-2。将Cas9/sgRNA表达载体和供体DNA共转染PK3108-2,借助G418抗性筛选和倒置荧光显微镜挑选出仅带阳性标记的克隆L18,对其基因组进行PCR产物凝胶电泳与PCR产物测序,证明克隆L18在预设位点发生同源重组;对其蛋白质进行Western 印迹实验表明,Mstn被成功地敲除失活。综上结果证明,本研究实现了双等位基因的精准敲除,构建了Mstn双敲除梯度回复表达细胞系。本研究为揭示Mstn的作用机制提供理想的实验材料,也为双等位基因的敲除提供了可借鉴的技术路线。     

猪肌肉生长抑制素基因5′调控区T→A突变与生长性状的关系分析

生长速度是猪育种中选择的主要目标性状之一,鉴定影响生长速度的QTL或基因具有重要的实践意义和理论价值.对猪肌肉生长抑制素基因(myostatin,MSTN)5′调控区TA突变与生长性状的关系进行了分析.突变所产生的基因型的判定采用PCR-RFLP方法进行.猪生长性状的测定指标包括60日龄体重(body weight at 60d,BW60)、前期平均日增重(average daily gain of stage one,ADG1)、后期平均日增重(average daily gain of stage two,ADG2)和全期平均日增重(average daily gain of whole stage,ADG),所采用的记录数分别来自165,276,275和275头无亲缘关系个体.采用SAS软件包的GLM程序对MSTN基因型与猪生长性状的关系进行分析.结果表明,MSTN基因型对猪BW60,ADG1和ADG2的效应不显著(P＞0.1),对ADG2的效应在剔除基因型与品种的互作效应以后几乎达到显著水平(P＝0.0522),突变等位基因的携带者(基因型为TA)具有较高的后期平均日增重.     

猪肌肉生长抑制素基因5‘调控区T→A突变与生长性状的关系分析

生长速度是猪育种中选择的主要目标性状之一,鉴定影响生长速度的QTL或基因具有重要的实践意义和理论价值。对猪肌肉生长抑制素基因（myostatin,MSTN)5‘调控区T→A突变与生长性状的关系进行了分析。突变所产生的基因型的判定采用PCR－RFLP方法进行。猪生长性状的测定指标包括60日龄体重（body weight at 60d,BW60)、前期平均日增重（average daily gain of stage one,ADG1)、后期平均日增重（average daily gain of stage two,ADG2)和全期平均日增重（average daily gain of whole stage,ADG),所采用的记录数分别来自165．276,275和275头无亲缘关系个体。采用SAS软件包的GLM程序对MSTN基因型与猪生长性状的关系进行分析。结果表明,MSTN基因型对猪BW60（P＝0．0522）,突变等位基因的携带者（基因型为TA）具有较高的后期平均日增重。     

用Cre/LoxP和CRISPR基因工程技术构建猪肌肉生长抑制素双等位基因敲除细胞系北大核心CSCD

肌肉生长抑制素(myostatin,Mstn)基因失活可引起哺乳动物的肌肉增生,但其调控机制尚不清楚,且缺乏可靠的试验材料验证Mstn相关分子通路的变化。本研究所用PK3108细胞系是在野生型PK15细胞系的基础上成功靶向敲除一条等位基因,在其靶位点敲入标记基因,敲除了204bp的外显子3序列,LoxP锚定在其标记基因两侧。利用Cre/LoxP重组酶删除系统删除插入PK3108Mstn靶位点的标记,借助流式细胞仪和荧光蛋白甄别得到无标记的过渡型细胞系PK3108-2。将Cas9/sgRNA表达载体和供体DNA共转染PK3108-2,借助G418抗性筛选和倒置荧光显微镜挑选出仅带阳性标记的克隆L18,对其基因组进行PCR产物凝胶电泳与PCR产物测序,证明克隆L18在预设位点发生同源重组;对其蛋白质进行Western印迹实验表明,Mstn被成功地敲除失活。综上结果证明,本研究实现了双等位基因的精准敲除,构建了Mstn双敲除梯度回复表达细胞系。本研究为揭示Mstn的作用机制提供理想的实验材料,也为双等位基因的敲除提供了可借鉴的技术路线。     

鱼类肌肉生长抑制素研究进展

肌肉的分化、生长和发育是动物生长发育的重要环节和过程,肌肉也是动物为人类提供的食品的主要成分。肌肉的生长和发育在不同层次受许多因素的影响,如环境(气候、营养等因素) 、激素和分子水平的调控。       

大黄鱼肌肉生长抑制素基因微卫星序列多态性分析

肌肉生长抑制素(myostatin,MSTN)参与肌肉生长和脂肪发生的调节．本研究在克隆大黄鱼MSTN cDNA的基础上,对3′端非编码区微卫星序列的多态性及其与体长、体重和肌肉脂肪含量的关系进行了分析．结果表明,获得的cDNA长1 886 bp,在3′端非编码区存在微卫星序列（CA）_n．在受检的52个个体中,微卫星序列长度在64～126 bp之间.大部分个体的微卫星序列内存在碱基替换,最常见的碱基替换形式是C→T,属于非完美型微卫星序列．根据该位点微卫星序列长度,在实验群体中共检测到23个等位基因,其中频率为0.019 2的等位基因11个,0.038 5的5个, 0.076 9的3个,0.057 7的2个,0.115 4和0.134 6的各1个．该基因位点的群体杂合度为0.932 7,多态信息含量为0.928 8．微卫星序列长度与大黄鱼体长、体重和肌肉脂肪含量之间的相关系数分别为0.409、0.435和-0.026,P值分别为0.021、0.016和0.878．碱基替换对大黄鱼生长及肌肉脂肪含量均无显著影响．     

Disruption of the Myostatin Gene in Porcine Primary Fibroblasts and Embryos Using Zinc-Finger Nucleases

Myostatin represses muscle growth by negatively regulating the number and size of muscle fibers. Myostatin loss-of-function can result in the double-muscling phenotype and increased muscle mass. Thus, knockout of myostatin gene could improve the quality of meat from mammals. In the present study, zinc finger nucleases, a useful tool for generating gene knockout animals, were designed to target exon 1 of the myostatin gene. The designed ZFNs were introduced into porcine primary fibroblasts and early implantation embryos via electroporation and microinjection, respectively. Mutations around the ZFNs target site were detected in both primary fibroblasts and blastocysts. The proportion of mutant fibroblast cells and blastocyst was 4.81% and 5.31%, respectively. Thus, ZFNs can be used to knockout myostatin in porcine primary fibroblasts and early implantation embryos.     

人工锌指核酸酶突变EGFP基因的功能分析

锌指核酸酶技术在基因定点修饰中具有效率高和特异性好等特点,并成功应用于数十种生物。目前,该技术是否能应用羊上尚未报道。为了敲除转基因山羊标记基因 (EGFP),构建了一对针对EGFP外显子上的锌指核酸酶表达载体,将其电转染至转EGFP基因胎儿成纤维细胞中,研究了锌指核酸酶突变EGFP基因的效率和方式,利用基因显微注射单细胞获得获得的转基因 (EGFP) 细胞系作为锌指核酸酶的靶细胞。结果显示,通过锌指核酸酶的突变作用,转染后的细胞发绿色荧光比例下降,测序结果显示在EGFP外显子中插入1个碱基G,导致编码EGFP基因的阅读框改变,从而起到基因突变的作用。结果表明,文中构建的锌指核酸酶对EGFP基因有突变作用,可以为以后获得无标记基因供核细胞进行体细胞核移植生产克隆羊奠定基础。     

Aberrant methylation of Meg3 in alpha1,3-galactosyltransferase knockout pig induced pluripotent stem cells

Pigs have been used as a good research model for xenotransplantation. Several groups have generated porcine-induced pluripotent stem cells (piPSCs) from differentiated somatic cells. Transgenic pigs with the alpha1,3-galactosyltransferase gene-knockout (GalT-KO) could successfully govern hyper acute rejection of organ transplants into primates. Thus, GalT-KO piPSCs could be a powerful cell resource for agricultural and biomedical applications. This study was performed to generate iPSCs from GalT-KO pigs and characterize their properties. We successfully generated a GalT-KO iPSC from a genetically modified pig using double alpha1,3-galactosyltransferase knockout alterations. Similar to mouse embryonic stem cells, the GalT-KO piPSCs were positive for classical pluripotency markers: POU5F1, NANOG, SOX2 and SSEA1, and were negative for: SSEA3, TRA-1-60 and TRA-1-81. Furthermore, these cells could form an embryoid body that differentiated into three germ layers in vitro, and were highly proliferative under leukemia inhibitory factor culture conditions. However, the methylation status in DMR2 of the Meg3 gene was higher in GalT-KO piPSCs than in porcine ear fibroblast. In conclusion, GalT-KO piPSCs could be successfully generated by six human factors without expression of Gal-epitopes. Although aberrant methylation observed in GalT-KO piPSCs, this cell line maintained pluripotency and had differentiation properties into all three germ layers. Therefore, GalT-KO piPSCs might be a good cell source for biomedical application and basic research.     

The enforced expression of c-Myc in pig fibroblasts triggers mesenchymal-epithelial transition (MET) via F-actin reorganization and RhoA/Rock pathway inactivation

In previous studies from other labs it has been well demonstrated that the ectopic expression of c-Myc in mammary epithelial cells can induce epithelial-mesenchymal transition (EMT), whereas in our pilot experiment, epithelial-like morphological changes were unexpectedly observed in c-Myc-expressing pig fibroblasts [i.e., porcine embryonic fibroblasts (PEFs) and porcine dermal fibroblasts (PDFs)] and pig mesenchymal stem cells, suggesting that the same c-Myc gene is entitled to trigger EMT in epithelial cells and mesenchymal-epithelial transition (MET) in fibroblasts. This prompted us to characterize the existence of a MET in c-Myc-expressing PEFs and PDFs at the molecular level. qRT-PCR, immunofluorescence and western blot analysis illustrated that epithelial-like morphological changes were accompanied by the increased expression of epithelial markers [such as cell adhesion proteins (E-cadherin, α-catenin and Bves), tight junction protein occludin and cytokeratins (Krt8 and Krt18)], the reduced expression of mesenchymal markers [vimentin, fibronectin 1 (FN1), snail1, collagen family of proteins (COL1A1, COL5A2) and matrix metalloproteinase (MMP) family (MMP12 and MMP14)] and the decreased cell motility and increased cell adhesion in c-Myc-expressing PEFs and PDFs. Furthermore, the ectopic expression of c-Myc in pig fibroblasts disrupted the stress fiber network, suppressed the formation of filopodia and lamellipodia, and resulted in RhoA/Rock pathway inactivation, which finally participates in epithelial-like morphological conversion. Taken together, these findings demonstrate, for the first time, that the enforced expression of c-Myc in fibroblasts can trigger MET, to which cytoskeleton depolymerization and RhoA/Rock pathway inactivation contribute.     

Escherichia coli genome-scale metabolic gene knockout of lactate dehydrogenase (ldhA), increases succinate production from glycerol

Genome-scale metabolic model (GEM) of Escherichia coli has been published with applications in predicting metabolic engineering capabilities on different carbon sources and directing biological discovery. The use of glycerol as an alternative carbon source is economically viable in biorefinery. The use of GEM for predicting metabolic gene deletion of lactate dehydrogenase (ldhA) for increasing succinate production in Escherichia coli from glycerol carbon source remained largely unexplored. Here, I hypothesized that metabolic gene knockout of ldhA in E. coli from glycerol could increase succinate production. A proof-of-principle strain was constructed and designated as E. coli BMS5 (ΔldhA), by predicting increased succinate production in E. coli GEM and confirmed the predicted outcomes using wet cell experiments. The mutant GEM (ΔldhA) predicted 11% increase in succinate production from glycerol compared to its wild-type model (iAF1260), and the E. coli BMS5 (ΔldhA) showed 1.05 g/l and its corresponding wild-type produced .05 g/l (23-fold increase). The proof-of-principle strain constructed in this study confirmed the aforementioned hypothesis and further elucidated the fact that E. coli GEM can prospectively and effectively predict metabolic engineering interventions using glycerol as substrate and could serve as platform for new strain design strategies and biological discovery.     

Identification and characterization of hmr19 gene encoding a multidrug resistance efflux protein from Streptomyces hygroscopicus subsp. yingchengensis strain 10-22

[(The over-usage of antibiotics may result in the develop-)]ment of extensive antibiotic resistance in microorganisms[1]. Export of toxic compounds as means of resistancehas been well documented in pathogenic bacteria as wellas antibiotic-producing microorganisms [2,3]. Drugresistance efflux proteins comprise the primary efflux[(system, namely the )58.3(A)106.2(TP-binding cassette \(ABC\) family)][(transporters ener)10.9(gized by )68.1(A)104.5(T)0.8(P)113.8(,)-0.1( and the secondary active)…     

Comparative proteomic analysis of human lung telocytes with fibroblasts

Telocytes (TCs) were recently described as interstitial cells with very long prolongations named telopodes (Tps; www.telocytes.com ). Establishing the TC proteome is a priority to show that TCs are a distinct type of cells. Therefore, we examined the molecular aspects of lung TCs by comparison with fibroblasts (FBs). Proteins extracted from primary cultures of these cells were analysed by automated 2‐dimensional nano‐electrospray ionization liquid chromatography tandem mass spectrometry (2D Nano‐ESI LC‐MS/MS). Differentially expressed proteins were screened by two‐sample t‐test (P < 0.05) and fold change (>2), based on the bioinformatics analysis. We identified hundreds of proteins up‐ or down‐regulated, respectively, in TCs as compared with FBs. TC proteins with known identities are localized in the cytoskeleton (87%) and plasma membrane (13%), while FB up‐regulated proteins are in the cytoskeleton (75%) and destined to extracellular matrix (25%). These identified proteins were classified into different categories based on their molecular functions and biological processes. While the proteins identified in TCs are mainly involved in catalytic activity (43%) and as structural molecular activity (25%), the proteins in FBs are involved in catalytic activity (24%) and in structural molecular activity, particularly synthesis of collagen and other extracellular matrix components (25%). Anyway, our data show that TCs are completely different from FBs. In conclusion, we report here the first extensive identification of proteins from TCs using a quantitative proteomics approach. Protein expression profile shows many up‐regulated proteins e.g. myosin‐14, periplakin, suggesting that TCs might play specific roles in mechanical sensing and mechanochemical conversion task, tissue homoeostasis and remodelling/renewal. Furthermore, up‐regulated proteins matching those found in extracellular vesicles emphasize TCs roles in intercellular signalling and stem cell niche modulation. The novel proteins identified in TCs will be an important resource for further proteomic research and it will possibly allow biomarker identification for TCs. It also creates the premises for understanding the pathogenesis of some lung diseases involving TCs.     

Insights into function and regulation of small heat shock protein 25 (HSPB1) in a mouse model with targeted gene disruption

The mammalian small heat shock protein (sHSPs) family is comprised of 10 members and includes HSPB1, which is proposed to play an essential role in cellular physiology, acting as a molecular chaperone to regulate diverse cellular processes. Whilst differential roles for sHSPs are suggested for specific tissues, the relative contribution of individual sHSP family members in cellular and organ physiology remains unclear. To address the function of HSPB1 in vivo and determine its tissue-specific expression during development and in the adult, we generated knock-in mice where the coding sequence of hspb1 is replaced by a lacZ reporter gene. Hspb1 expression marks myogenic differentiation with specific expression first confined to developing cardiac muscles and the vascular system, and later in skeletal muscles with specific expression at advanced stages of myoblast differentiation. In the adult, hspb1 expression was observed in other tissues, such as stratified squamous epithelium of skin, oronasal cavity, tongue, esophagus, and uterine cervix but its expression was most prominent in the musculature. Interestingly, in cardiac muscle hsbp1 expression was down-regulated during the neonatal period and maintained to a relatively low steady-level throughout adulthood. Despite this widespread expression, hspb1-/- mice were viable and fertile with no apparent morphological abnormalities in tissues under physiological conditions. However, at the cellular level and under stress conditions (heat challenge), HSPB1 act synergistically with the stress-induced HSPA1 (HSP70) in thermotolerance development, protecting cells from apoptosis. Our data thus indicate a nonessential role for HSPB1 in embryonic development and for maintenance of tissues under physiological conditions, but also shows that it plays an important role by acting synergistically with other HSPs during stress conditions to exert cytoprotection and anti-apoptotic effects.