稻瘟菌WD重复功能域中SSR的变异及其对蛋白结构的影响

含WD重复功能域的蛋白能够参与信号传导、转录调控、RNA剪切、细胞的凋亡等多种功能,在病原菌与寄主植物蛋白互作的过程中扮演着重要的角色。本研究分析了稻瘟病菌基因组中94个WD功能域基因编码区和调控区中SSR的组成、分布,并检测了7个蛋白编码区中SSR的变异及其对蛋白二级结构的影响。结果表明,WD功能域基因的编码区和调控区中都含有大量的SSR,但是SSR在这些基因的外显子区、内含子区、5’一UTR和3’一UTR区中SSR的组成和分布均不相同;编码区中三碱基和六碱基SSR分布较多,这些SSR基序大都表现为GC含量较高和其所编码的亲水性氨基酸出现的频率远远高于疏水性氨基酸的特点。且检测的7个WD功能域基因的编码区中的SSR位点均具有丰富的多态性,通过Antheprot（DPM）软件预测发现：SSR的变异对蛋白的二级结构有一定影响。这暗示着SSR的变异对致病相关基因的变异起着十分重要的作用。     

冬虫夏草菌3个细胞核蛋白编码基因的分子进化

【目的】分析3个细胞核蛋白编码基因(csp1、MAT1-1-1和MAT1-2-1)在不同冬虫夏草菌株间的分子进化。【方法】从125个冬虫夏草样品中分别扩增csp1、MAT1-1-1和MAT1-2-1基因序列,比较外显子和内含子间以及2个交配型基因间的序列变异程度,比较基于不同基因或基因区域所构建的系统发育树拓扑结构的差异,分析3个基因承受的选择压力和DNA重组情况。【结果】3个蛋白编码基因外显子区的长度在不同菌株间高度保守,具有4.5%?5.7%的变异位点;内含子区的长度在不同菌株间相同或不同,具有1.8%?22%的变异位点。对于2个交配型基因,MAT1-1-1的碱基变异率低于MAT1-2-1。基于外显子与内含子构建的系统发育树的拓扑结构,以及基于2个交配型基因外显子构建的系统发育树的拓扑结构都存在明显差异。3个蛋白编码基因都经历着净化选择作用。基因内部的不同DNA位点间有重组,但3个基因片段之间没有明显的重组发生。【结论】由于冬虫夏草菌不同基因以及基因的不同区域表现出进化上的差异,所以在开展冬虫夏草菌进化相关的研究时,应该联合使用多个不同的基因片段。     

簸箕柳AP3同源基因SsMADS的克隆与特性分析

用cDNA末端快速扩增(rapid-amplification of cDNA ends,RACE)方法从簸箕柳雄花序中克隆了一个AP3同源基因的cDNA,长826 bp,包括完整的编码区、5′-UTR和3′-UTR,并将其相应的基因命名为SsMADS。该基因由7个外显子和6个内含子组成,编码区长723 bp,编码241个氨基酸,其N-端具有典型的MADS保守结构域。序列分析表明,SsMADS编码的氨基酸序列与毛果杨(Populus trichocarp)AP3同源蛋白有95.7%相似性,与其他几种柳属植物的AP3同源蛋白相似性达96.1%～99.6%。实时定量RT-PCR表明,SsMADS在叶、茎和根中表达量极低,在花序中表达量较高,并且其表达量在花器官的早中期发育阶段逐步提高,说明该基因在簸箕柳花器官的发育中起作用。     

稻曲病菌PMK1类同源基因克隆及在稻瘟病菌遗传互补中的功能验证

[目的]克隆稻曲病菌PMK1类MAPK(Mitogen-activated protein kinase)同源基因.[方法]根据丝状真菌MAPK蛋白保守性设计简并引物扩增稻曲病菌MAPK基因部分片段,进而利用TAIL-PCR进行染色体步移和RT-PCR获得UVMK1基因全长和cDNA全长.构建互补载体,交叉互补稻瘟病菌APMK1突变体菌株nn78进行功能验证,包括附着胞分化和致病性测定.[结果]UVMK1基因全长1435 bp,包含3个内含子,编码355氨基酸的蛋白.UVMK1推导蛋白与丝状真菌Magnaporthe grisea PMK1,Fusarium oxysporum FMK1,Fusarium solani FSMAPK,Colletotrichumlagenarium CMK1,Botrytis cinerea BMK1,Claviceps purpurea CMPK1等编码蛋白高度同源.转化稻瘟病菌菌株nn78,获得5个转化子.其中选取的转化子恢复了稻瘟病菌正常的附着胞分化和对大麦叶片的致病能力.[结论]本研究成功分离了首个稻曲病菌MAPK基因,而且UVMK1基因是稻瘟病菌PMK1的同源基因.     

血红密孔菌(Pycnoporussanguineus)漆酶基因的克隆与序列分析

为克隆血红密孔菌 (Pycnoporussanguineus)漆酶基因 ,根据真菌漆酶氨基酸序列保守区设计了 1对简并引物 .以血红密孔菌基因组DNA为模板 ,PCR扩增出长 12 2 7bp的漆酶基因片段 .以此序列为基础 ,通过 5′及 3′RACE技术克隆出漆酶全长cDNA序列 ,序列长为 190 2bp ,其 5′端和 3′端非编码区长分别为 5 1bp和 2 97bp ,开放阅读框长 15 5 4bp ,编码 5 18个氨基酸的蛋白 .该蛋白具有 4个铜离子结合区域 ,预测其相对分子量为 5 6 313 2 ,等电点为 5 5 9,其氨基酸序列与Pycnoporuscinnabarinus漆酶 (lcc3 2 )的同源性最高 ,为 96 % .以该cDNA编码区的两端序列为引物 ,PCR扩增得到漆酶的长度为 2 15 4bp的全长DNA序列 ,序列中包括 10个内含子序列 ,长为 5 2～ 70bp     

球孢白僵菌种内比较线粒体基因组学分析

【目的】明确球孢白僵菌种内线粒体基因组的分化程度。【方法】从GenBank下载已知的球孢白僵菌6个菌株线粒体基因组序列,详细分析基因组的组成结构,比较外显子区、内含子区和基因间区的碱基变异情况,分析菌株间的系统发育关系。【结果】球孢白僵菌不同菌株的线粒体基因组大小为28.8–32.3 kb,都有14个常见的核心蛋白编码基因、2个rRNA基因和25个tRNA基因,具有很强的共线性关系。但是,不同菌株含有的线粒体内含子数目存在差异(2–5个/菌株),在cox1、cox2和nad1基因中表现出内含子插入/缺失多态性,这是导致线粒体基因组大小变化的主要因素。对外显子、内含子和基因间区的碱基变异情况进行分析,发现内含子和基因间区相对变异较大,而外显子区相对变异较小。系统发育分析发现,这些球孢白僵菌菌株以很高的支持度聚在一起,具有相同内含子分布规律的菌株也具有较近的聚类关系。【结论】本研究首次报道球孢白僵菌因内含子数目不同、插入缺失突变和单核苷酸变异等在线粒体基因组上表现出较大程度的遗传分化,为认识真菌种内线粒体基因组分化提供了新的证据。     

绵羊钙调蛋白调节基因Calponin h1 的分子克隆

在一项研究中我们发现雌激素体在胚胎发育后期对绵羊子宫平滑肌Calponin (CaP) 基因的活动有明显上调作用,而CaP一直被作为观察其他基因表达水平变化的基准参照基因（Reference Gene）。迄今为止, 绵羊CaP尚未完整克隆,为进一步了解其结构和功能,根据人、小鼠和家猪的同源保守区序列设计锚定寡核苷酸引物,通过5′-RACE及3′-RACE方法克隆了绵羊子宫平滑肌组织全长CaP h1 cDNA (GenBank登录号： AY327118), 在cDNA序列的基础上, 又通过PCR-SSP方法获得了CaP h1基因除内含子1、2之外的其余4个内含子全部序列 （GenBank登录号分别为：AY771807,AY771808, AY771809, AY771810） 。DNA序列测定和分析表明,绵羊子宫平滑肌CaP h1 cDNA全长1499bp, 编码297个氨基酸,5′-UTR及3′-UTR分别为79bp和529bp。CaP h1基因组DNA的克隆和序列分析表明,绵羊CaP全长约8kb,由 7个外显子和6个内含子组成。 同源序列比较发现,该基因外显子在不同物种间相对保守;与人类、野猪、小鼠、大鼠和鸡Calponin mRNA同源性分别为88％、92％、81％、79％和81％,但不同物种间内含子存在较大差异(>50%)。本研究填补了绵羊CaP基因分子克隆的空白,为进一步研究该基因的功能及子宫平滑肌收缩的调节机理奠定了基础。     

小鼠基因组中的微卫星重复序列的数量、分布和密度

作者分析了老鼠基因组中各染色体及其内含子、外显子和基因间区上各种类型的微卫星(1-6个碱基的重复序列)的数量及其密度。SSR约占老鼠基因组的2.85%,其中46.2%存在于基因间区,4.75%存在于外显子,49.05%在内含子区域,即非编码区富含微卫星。微卫星的数量与染色体或基因区域的大小有关,但密度与染色体或基因区域的大小的关系并不十分密切。第4染色体的外显子区域中6种类型的SSR含量都比其它区域少。A,T,AC,AG,AT,AAC,AAG,AGG,AAAC,AAAG,AAAT,AACC,AAAAC,AAAAG,AAAAT,AAACC,AAAGG,AAGAG,AAAAAC,AAAAAG,AAAAAT,AAAGAG,ACACAT,ACAGAG,ACAGGC,ACATAT是老鼠基因组中主要的SSR类型,而一些5碱基重复单元的SSR在老鼠基因组的某一条甚至某几条染色体都不存在     

球毛壳菌（Chaetomium globosum）过氧化物膜蛋白过敏原基因克隆、序列分析及原核表达

以球毛壳菌cDNA文库中获得过氧化物膜蛋白（pero）基因片段（GenBank Accn:BP099709）为基础,用RACE 技术获得该基因的全长cDNA序列。序列长747bp,由412bp的3′RACE产物和508bp的5′RACE产物拼接而成。开放阅读框501bp,编码166个氨基酸,蛋白分子量为17.5kD,理论等电点为5.75。利用cDNA两侧非编码区序列作引物克隆出该基因的DNA序列,序列分析表明该基因由2个内含子和3个外显子组成。ClustalX多序列比对表明：该基因与粗糙脉孢菌（Neurospora crassa）的过氧化物膜蛋白过敏原同源性最高（83%）。将pero基因编码区克隆到原核表达载体pET28a中,构建成表达质粒pET28a-pero并转化大肠杆菌BL21,IPTG诱导后SDS-PAGE检测表达情况,结果发现在21kD处有一特异性融合蛋白带,大小与预期相符,说明该基因已经在大肠杆菌中表达。克隆的cDNA序列、DNA序列及推测的氨基酸序列在GenBank登录(登录号分别为AY555771,AY584753,AAS66898)。     

牦牛α-乳清蛋白基因的克隆与序列分析

根据奶牛α－乳清蛋白基因序列设计引物,用PCR方法扩增并克隆了牦牛（Poephagens grunnieus）α－乳清蛋白基因的全序列。结果表明,在671－2689bp之间,共有4个外显子和3个内含子,牦牛α－乳清蛋白基因共编码142个氨基酸,其中第1－19氨基酸之间的短肽为信号肽序列。牦牛的α－乳清蛋白基因有较高水平的表达可能与基因内非编码序列碱基突变引起的回文结构消失有关。该基因5′侧翼序列在结构上牦牛和牛基本相同,只有MGF因子识别位点稍有差别。且牦牛的该序列更符合Groenen等1994年总结的该因子识别位点的模式序列,因此牦牛的该基因5′调控区可能更适于进行组织特异性表达的转基因动物的制作研究。     

Molecular cloning of a dehydration-responsive protein gene (MRD22) from mulberry,and determination of abiotic stress patterns of MRD22 gene expression

A full-length cDNA sequence coding for dehydration-responsive protein gene of mulberry tree, which we designated was MRD22 (GenBank accession number: JQ804833) was cloned based on mulberry expressed sequence tags (ESTs). MRD22 is 1503 bp long, contains a 334 bp 5′-UTR (untranslated region) and a 563 bp 3′-UTR, encodes 201 amino acids with a predicted molecular weight of 54.28 kDa and an isoelectric point of 9.35. Phylogenetic analysis based on MRD22 sequences from different species showed that mulberry has close relationship with Populus trichocarpa, Ricinus communis, Camellia sinensis, Gossypium hirsutum, Gossypium barbadense and so on. The expression level of the MRD22 gene under conditions of drought, low temperature and salt stresses was quantified by qRT-PCR. The results show that the expression level changed significantly under the stress conditions compared to the normal growth environment. It helps us to get a better understanding of the molecular basis for signal transduction mechanisms underlying the stress response in mulberry.     

Evolutionary pressures on simple sequence repeats in prokaryotic coding regions

Simple sequence repeats (SSRs) are indel mutational hotspots in genomes. In prokaryotes, SSR loci can cause phase variation, a microbial survival strategy that relies on stochastic, reversible on-off switching of gene activity. By analyzing multiple strains of 42 fully sequenced prokaryotic species, we measure the relative variability and density distribution of SSRs in coding regions. We demonstrate that repeat type strongly influences indel mutation rates, and that the most mutable types are most strongly avoided across genomes. We thoroughly characterize SSR density and variability as a function of N→C position along protein sequences. Using codon-shuffling algorithms that preserve amino acid sequence, we assess evolutionary pressures on SSRs. We find that coding sequences suppress repeats in the middle of proteins, and enrich repeats near termini, yielding U-shaped SSR density curves. We show that for many species this characteristic shape can be attributed to purely biophysical constraints of protein structure. In multiple cases, however, particularly in certain pathogenic bacteria, we observe over enrichment of SSRs near protein N-termini significantly beyond expectation based on structural constraints. This increases the probability that frameshifts result in non-functional proteins, revealing that these species may evolutionarily tune SSR positions in coding regions to facilitate phase variation.     

特异种质烟草HZNH的Fe-SOD基因的克隆与表达

超氧化物歧化酶(superoxidedismutase,SOD)是一种广泛存在于动物、植物、微生物体内的金属酶,按其结合的金属性离子可分为Fe SOD、Mn SOD和CuZn SOD三种,它们通过催化超氧阴离子自由基O·-2发生歧化反应,达到清除O·-2的效果,具有防御氧毒性、增强机体抗辐射损伤能力、防衰老,治疗某些肿瘤、炎症、自身免疫疾病等功效,在农业、医药、食品、化工等产业中的应用前景广阔,因此广受国内外科研工作者的关注和重视[1].而试图通过转SOD基因技术来培育高抗逆农作物新品种和基因克隆与表达技术来实现SOD的大规模发酵生产,已成为国内外SOD…     

鸡含锰超氧化物歧化酶cDNA克隆及序列分析

 为弄清鸡含锰超氧化物歧化酶 (manganese containingsuperoxidedismutase ,MnSOD)的cDNA序列 ,以开展动物锰营养学的深入研究 ,根据已知鸡MnSOD的N端氨基酸序列设计简并引物 ,应用 3′RACE(rapidamplificationofcDNAends)技术 ,扩增克隆了鸡心肌MnSOD 990bp的 3′cDNA片段 .再根据 3′RACE片段测序结果设计引物进行 5′RACE ,结果获取了一个与 3′RACE片段相互重叠的鸡心肌MnSOD 52 1bp的 5′RACE片段 ,并对其进行了克隆测序 .最后根据 3′RACE片段和 5′RACE片段序列信息进行拼接 ,从而获取鸡MnSODcDNA的全序列信息 .研究结果表明 :鸡MnSODcDNA全长为 110 8个核苷酸 ,其中 5′非翻译区 2 5个核苷酸 ,编码区 675个核苷酸 ,3′非翻译区 4 0 8个核苷酸 ,编码一个长 2 2 4个氨基酸残基的蛋白质前体 .其中信号肽长 2 6个氨基酸残基 ,成熟肽长 198个氨基酸残基 ,分子量为 2 2kD .与人、大鼠、线虫、果蝇等真核生物MnSOD氨基酸序列的同源性分别为82 4 %、84 .7%、62 .4 %、59.3% .     

Genomic distribution of simple sequence repeats in Brassica rapa

Simple Sequence Repeats (SSRs) represent short tandem duplications found within all eukaryotic organisms. To examine the distribution of SSRs in the genome of Brassica rapa ssp. pekinensis, SSRs from different genomic regions representing 17.7 Mb of genomic sequence were surveyed. SSRs appear more abundant in non-coding regions (86.6%) than in coding regions (13.4%). Comparison of SSR densities in different genomic regions demonstrated that SSR density was greatest within the 5'-flanking regions of the predicted genes. The proportion of different repeat motifs varied between genomic regions, with trinucleotide SSRs more prevalent in predicted coding regions, reflecting the codon structure in these regions. SSRs were also preferentially associated with gene-rich regions, with peri-centromeric heterochromatin SSRs mostly associated with retrotransposons. These results indicate that the distribution of SSRs in the genome is non-random. Comparison of SSR abundance between B. rapa and the closely related species Arabidopsis thaliana suggests a greater abundance of SSRs in B. rapa, which may be due to the proposed genome triplication. Our results provide a comprehensive view of SSR genomic distribution and evolution in Brassica for comparison with the sequenced genomes of A. thaliana and Oryza sativa.     

Nucleotide sequence and genetic organization of the polyoma late region: features common to the polyoma early region and SV40.

The nucleotide sequence of the late region of the polyoma genome has been determined. It consists of 2366 bp and encodes the virion capsid proteins VP1, VP2 and VP3. Extensive open reading frames identify the possible coding sequences of VP2 and VP3 toward the 5′ end of the late region, and of the major capsid protein VP1 toward the 3′ end of the late region. The 5′ end of the sequence encoding VP1 overlaps the 3′ VP2/VP3 region by 29 nucleotides and is in a different reading frame. The predicted amino acid sequences for all three known capsid proteins show extensive homology with the analogous capsid proteins of SV40 throughout most of their length. The VP2/VP3 amino acid homology between the two viruses is 34%, while the major capsid protein VP1 is much more highly conserved, showing 54% homology. These homologies together with the extent of open reading frames help to define the extent of the coding sequences. The VP2 initiator begins at position 269 and the coding region extends to the first termination codon beginning at 1226. The predicted size of VP2 is 35,007 daltons. A probable VP3 initiator is within the VP2 coding sequence at position 614 and is in the same frame as VP2. This coding sequence can also utilize the terminator at position 1226, and the predicted size of the VP3 translation product is 22,979 daltons. The VP1 coding region begins at position 1197 and continues in a frame different from that of VP2/ VP3 to a termination point at 2349. The molecular weight of VP1 is predicted to be 42,834 daltons. The 5′ untranslated region contains sequences that resemble a potential ribosomal binding site and a possible mRNA capping sequence similar to those found in other eucaryotic systems. There is also a sequence (5′-TCAAGTAAGTGA-3′) almost identical to one found in two regions containing potential splice sites in the early region of polyoma. The 5′ untranslated region does not show the extensive repeated sequences found in the similar region of SV40. The 3′ untranslated region contains the sequence 5′-AATAAA-3′, thought to represent a polyadenylation signal. As in the early region of polyoma, the extensive nucleotide and deduced amino acid homology with SV40 indicate a close evolutionary relationship between the two viruses, and help to identify regions of common and important structure-function relationships.