小麦Mlo及NBS-LRR类抗病基因同源序列的分离与鉴定

根据GenBank中公布的大麦白粉病抗性控制基因Mlo cDNA序列及一个来源于栽培一粒小麦(Triticum monococcum L.)的假定抗病基因序列分别设计引物,以携带小麦抗白粉病基因的近等基因系为材料进行RT-PCR筛选.结果获得两个表达基因的cDNA克隆.其中一个与大麦白粉病抗性控制基因Mlo的同源性达83%.另一个为非通读序列,含有两个可能的开放阅读框,分别包含抗病基因NBS保守结构域2和3以及与水稻抗稻瘟病基因Pib蛋白末端相似的13个LRR区域,推测该序列属于NBS-LRR类.白粉菌诱导前后,该片段RT-PCR扩增产物存在差异,表明该片段可能与小麦抗病性相关.利用"中国春"缺体-四体系,将该NBS-LRR类序列定位在小麦1D染色体上.     

水稻中大麦Mlo和玉米Hm1抗病基因同源序列的分析和定位

大麦抗病基因Mlo和玉米抗病基因Hm1编码的产物不具有绝大多数植物抗病基因产物所含有的保守结构域。这两个抗病基因的作用机理也不符合基因对基因学说。从水稻中分离克隆了Mlo基因的同源序列OsMlo-1和玉米Hm1基因的同源序列DFR－1。利用水稻分子标记遗传连锁图,将OsMlo-1定位于水稻第六染色体的两俱RZ667和RG424之间;Osmlo-1距离这两个分子标记分别为20．6和6．0cM(centi-Morgan)。将DFR－1定位于水稻第一染色体两个分子标记R2635和RG462之间;DFR－1距离这两个分子标记分别为11．3和23．9cM。参照已发表的水稻分子标记连锁图,发现OsMlo-1和DFR－1的染色体位点分别与两个报道的水稻抗稻瘟病数量性状位点（QTL）有较好的对应关系。结果提示,水稻中与大麦Mlo 和玉米Hml同源的基因可能也参于抗病反应的调控。     

聚苹果酸生产菌出芽短梗霉CCTCC M2012223的全基因组测序及序列分析

【目的】解析出芽短梗霉CCTCC M2012223的基因组序列信息,分析其代谢产物聚苹果酸、黑色素、普鲁兰多糖合成相关基因,为深入研究遗传多样性和代谢工程改造提供序列背景信息。【方法】使用Illumina Hi Seq高通量测序平台对出芽短梗霉CCTCC M2012223菌株进行全基因组测序,并对测序数据进行序列拼接,基因预测与功能注释,COG/GO聚类分析,比较基因组学分析等。下载其他5株出芽短梗霉基因组序列,比较分析6株菌的种内同源基因、全基因组进化以及代谢产物合成相关基因。【结果】出芽短梗霉CCTCC M2012223基因组序列全长30756831 bp,GC含量47.49%,编码9452个基因。比较基因组分析表明出芽短梗霉CCTCC M2012223的基因组组装长度最长,6株菌的同源基因数达到7092个,普鲁兰多糖和聚苹果酸合成相关基因的蛋白序列有很高的保守性。出芽短梗霉CCTCC M2012223和Aureobasidium pullulans var.melanogenum亲缘关系最近,而这2株菌的黑色素合成相关基因的蛋白序列有一些插入和突变。【结论】本研究解析了出芽短梗霉CCTCC M2012223的基因组序列信息,获得黑色素、普鲁兰多糖和聚苹果酸合成相关基因,为后续的代谢机制解析和改造提供相关依据。     

小麦Mlo及NBS—LRR类抗病基因同源序列的分离与鉴定

根据GenBank中公布的大麦白粉病抗性控制基因MlocDNA序列及一个来源于栽培一粒小麦（Triticum monococcumL.)的假定抗病基因序列分别设计引物,以携带小麦抗白粉病基因的近等基因系为材料进行RT-PCR筛选。结果获得两个表达基因的cDNA克隆。其中一个与大麦白粉病抗性控制基因Mlo的同源性达83%。另一个为非通读序列,含有两个可能的开放阅读框,分别包含抗病基因NBS保守结构域2和3以及与水稻抗稻瘟病基因Pib蛋白末端相似的13个LRR区域,推测该序列属于NBS-LRR类。白粉菌诱导前后,该片段RT-PCR扩增产物存在差异。表明该片段可能与小麦抗病性相关。利用“中国春”缺体-四体系,将该NBS-LRR类序列定位在小麦1D染色体上。     

甜瓜STK类R基因同源序列的克隆与分析

以植物丝氨酸/苏氨酸蛋白激酶类( serine-threonine kinase,STK)抗病基因产物催化结构域I和Ⅸ的保守氨基酸序列( FGK/V/L/SVYK/RG,DY/IYSF/YGV/I/M)设计简并引物,对甜瓜(Cucumis melo L.)基因组DNA进行PCR扩增,得到大约500 bp的目的条带,通过重组质粒克隆并经PCR检测后得到12条不同的DNA序列,命名为tg1～tg12,其中tg2、tg5、tg9和tg12(Genbank登录号为JN646853 ～JN646856)可以编码完整的氨基酸序列.Blast分析结果显示:4条序列均具有ATP结合部位、底物结合部位和激酶结构域的活化环(A-loop)等,属于典型的蛋白激酶基因家族,可能是STK类R基因的同源序列片段;4条序列与蓖麻(Ricinus communisL.)的STK同源性均较高.氨基酸序列比对结果显示tg2、tg5、tg9和tg12均具有R基因的9个保守结构域,为STK类候选抗病基因类序列.分子系统树显示tg2、tg5、tg9和tg12与已知的R基因(Pto、Lr10和Lectin)在氨基酸水平上的相似性仅为33.5％ ～53.4％,且4个甜瓜同源序列的氨基酸相似性也较低,表明甜瓜RGAs标记可能具有较高的特异性.     

海岛棉NBS类型抗病基因类似物的起源、多样性及进化

利用已克隆植物的R基因NBS序列中保守模体合成简并引物,以海岛棉品系Pima 90(Gossypium barba—dense)基因组DNA为模板进行PCR扩增,通过T／A克隆、测序和序列比较分析共得到31条RGAs,其中19条具有连续的ORF。利用海岛棉的31条RGAs与GenBank中陆地棉种质系M—249(Gossypium hirsutum)的RGAs进行了比较分析,RGAs可分为两大类：其中第Ⅰ类全部为陆地棉的RGAs;第Ⅱ类分别包括了陆地棉和海岛棉的RGAs。同时对海岛棉RGAs的核苷酸和氨基酸序列进行系统发育树分析,表明海岛棉RGAs可分为TIR(Drosophila Toll or human inter—leukin receptor—1ike)和non—FIR两类,与前人所报道的R基因进化一致。对19条具有连续ORF的RGAs进行了结构分析,结果表明它们包括P—loop、Kin—2、“PLAL”及Meyers等所定义的RNBS—A、B、C3个模体。结果表明,可能海岛棉NBS类型抗病基因类似物和其他物种具有同样的起源和进化机制。     

马链球菌兽疫亚种类M蛋白的基因克隆、序列分析及其在猪源链球菌的检测

根据已发表的马链球菌兽疫亚种 (Streptococcusequisubsp .zooepidemicus)马源株的类M蛋白基因序列 ,设计和合成一对引物 ,以兽疫亚种猪源ATCC35 2 4 6株的基因组DNA为模板 ,通过PCR技术 ,扩增出类M蛋白基因并定向克隆至表达载体pET_32a( )中 ,测定其序列 ,GenBank接收号为AY2 6 3781。类M蛋白基因含一个完整的开放阅读框 ,全长为 1137bp ,编码 379个氨基酸残基。经DNAStar软件分析 ,ATCC35 2 4 6株类M蛋白基因与兽疫亚种马源W6 0株、马亚种的类M蛋白基因及A群化脓链球菌的M蛋白基因的同源性分别为 86 9%、30 8%、2 9 4 % ;推导的氨基酸序列的同源性分别为 84 3%、2 1 9%、2 3 4 %。但ATCC35 2 4 6株类M蛋白的C末端细胞膜锚定区与M蛋白、马亚种类M蛋白高度同源。用上述设计的引物进行PCR试验 ,检测 34株猪源链球菌类M蛋白基因 ,发现所有 16株C群猪源链球菌均能检测出类M蛋白基因 ,而所有猪链球菌 (Streptococcussuis) 1型和 2型菌株及S群、B群、D群链球菌共 13株均不能检出类M蛋白基因 ,而 5株未鉴定的猪源链球菌中 3株能检测出类M基因。     

香蕉抗病种质NBS类RGAs的克隆及相关序列差异分析

根据植物NBS类抗病基因保守氨基酸序列P-loop和疏水氨基酸GLPL保守序列设计简并引物,从香蕉抗镰刀菌枯萎病(4号小种)材料GCTCV-119的基因组DNA及cDNA中扩增获得9个DNA片段和10条cDNA片段,均编码为通读的氨基酸序列,命名为"BR-1"-"BR-19",GenBank登录号依次为EF515833-EF515836, EU123871-EU123885。同源性分析表明,均与已报道的植物抗病基因有不同程度的同源性,具有P-loop(Kinase-1a)、Kinase-2、RNBS-B(Kinase-3a)以及GLPL等保守氨基酸序列,属于non-TIR-NBS类候选抗病基因。其中,BR-5和BR-6与番茄抗镰刀菌枯萎病番茄专化型I2、I2-1和I2-2基因聚为一类,可能与香蕉镰刀菌枯萎病的抗性相关。     

野生稻NBS类抗病基因同源序列的分离与序列分析

为了挖掘野生稻中的抗病资源,根据已克隆的植物抗病基因核苷酸结合位点序列中的保守结构域设计3对简并引物,从疣粒、药用、高秆、宽叶和斑点野生稻基因组DNA中分离出13条NBS类抗病基因类似物,其中11条具有连续的ORF,具有NBS类R基因的保守基元P-loop、kinas-2、kinas-3a和GLPL。在NCBI上进行同源性搜索发现,其中12条RGAs的核苷酸序列与水稻已知的NBS类R基因具有66%～94%的同源性,与其他植物已知R基因具有67%～84%的同源性;其对应的氨基酸序列与水稻已知的NBS类R基因具有43%～93%的同源性,与其他植物已知R基因具有37%～79%的同源性。另外1条的核苷酸序列与水稻假定的NBS类R基因具有76%的同源性,其氨基酸序列与水稻假定的NBS类R基因具有74%的同源性。根据序列分析结果设计6对不同基因特异性引物,并利用RT-PCR技术进行表达分析,结果表明,RN1BD5、RN1BD10、RN1GG2和RN1YY6均能表达,说明这些片段可能是功能性抗病基因的部分序列;而RN1KY9和RN1GG5没有表达,可能是假基因。     

冠状病毒的新成员--SARS-CoV的基因组特性

2003年3月,人类发现一种新的冠状病毒SARS-CoV,这种病毒是非典型性肺炎(SARS)的病原体。SARS-CoV的基因组序列已经由包括中国科学家在内的全世界的科研人员测定完成。该文对国际报道的SARS病源的基因序列进行了收录,阐述了SARS-CoV基因组的基本特性：SARS-CoV的基因组长约28-30kb,与冠状病毒科的基因组长度相符合,其中包括11个编码序列,基因组的组织方式也与其他冠状病毒类似,从表面蛋白(S蛋白)、外膜蛋白(M蛋白)和核蛋白(N蛋白)上看,SARS病毒与其他冠状病毒的对应蛋白进化关系接近。同时发现,在某些区域,SARS病毒的基因序列与其他冠状病毒存在相当大的差异,具有自身比较保守的基因组序列结构。而且氨基酸的序列也与其他冠状病毒有很大程度的不同。基因信息的冗余分析表明,SARS-CoV具有较低的冗余度,即发生变异的可能性比较大。虽然SARS-CoV外表与冠状病毒类似,亲缘关系未超出冠状病毒科界限,但由于蛋白基因与氨基酸的序列与其他冠状病毒有本质不同,因此可能不是其他冠状病毒的变异体,而是一种与冠状病毒类似、但早已独立存在、此前未被人类所认识的新病毒。     

Molecular phylogeny and evolution of the plant-specific seven-transmembrane MLO family

Homologues of barley Mlo encode the only family of seven-transmembrane (TM) proteins in plants. Their topology, subcellular localization, and sequence diversification are reminiscent of those of G-protein coupled receptors (GPCRs) from animals and fungi. We present a computational analysis of MLO family members based on 31 full-size and 3 partial sequences, which originate from several monocot species, the dicot Arabidopsis thaliana, and the moss Ceratodon purpureus. This enabled us to date the origin of the Mlo gene family back at least to the early stages of land plant evolution. The genomic organization of the corresponding genes supports a monophyletic origin of the Mlo gene family. Phylogenetic analysis revealed five clades, of which three contain both monocot and dicot members, while two indicate class-specific diversification. Analysis of the ratio of nonsynonymous-to-synonymous changes in coding sequences provided evidence for functional constraint on the evolution of the DNA sequences and purifying selection, which appears to be reduced in the first extracellular loop of 12 closely related orthologues. The 31 full-size sequences were examined for potential domain-specific intramolecular coevolution. This revealed evidence for concerted evolution of all three cytoplasmic domains with each other and the C-terminal cytoplasmic tail, suggesting interplay of all intracellular domains for MLO function.     

Genome-scale identification of MLO domain-containing genes in soybean (Glycine max L. Merr.)

In plants, powdery-mildew-resistance locus o (Mlo) genes encode proteins that are calmodulin-binding proteins involved in a variety of cellular processes. However, systematic characterization of this gene family in soybean (Glycine max L. Merr.) has not been yet reported. In this study, we identified MLO domain-contained members in soybean and examined their expression under phytohormone treatment and abiotic stress conditions. A total of 20 soybean Mlo genes were identified (GmMlo1-20), which are distributed on 13 chromosomes, and display diverse exon-intron structures. Phylogenetic analysis indicated that the Mlo family can be classified into four subfamilies. Sequence comparison was used to reveal the conserved calmodulin-binding domain (CaMBD) in GmMLO proteins. The expression of GmMlo genes was influenced by various phytohormone treatments and abiotic stresses, suggesting that these Mlo genes have various roles in the response of soybean to environmental stimuli. Promoter sequence analysis revealed an overabundance of stress and/or phytohormone-related cis-elements in GmMlo genes. These data provide important clues for elucidating the functions of genes of the Mlo gene family.     

Isolation of Resistance Gene Candidates (RGCs) and characterization of an RGC cluster in cassava

Plant disease resistance genes (R genes) show significant similarity amongst themselves in terms of both their DNA sequences and structural motifs present in their protein products. Oligonucleotide primers designed from NBS (Nucleotide Binding Site) domains encoded by several R-genes have been used to amplify NBS sequences from the genomic DNA of various plant species, which have been called Resistance Gene Analogues (RGAs) or Resistance Gene Candidates (RGCs). Using specific primers from the NBS and TIR (Toll/Interleukin-1 Receptor) regions, we identified twelve classes of RGCs in cassava ( Manihot esculenta Crantz). Two classes were obtained from the PCR-amplification of the TIR domain. The other 10 classes correspond to the NBS sequences and were grouped into two subfamilies. Classes RCa1 to RCa5 are part of the first subfamily and were linked to a TIR domain in the N terminus. Classes RCa6 to RCa10 corresponded to non-TIR NBS-LRR encoding sequences. BAC library screening with the 12 RGC classes as probes allowed the identification of 42 BAC clones that were assembled into 10 contigs and 19 singletons. Members of the two TIR and non-TIR NBS-LRR subfamilies occurred together within individual BAC clones. The BAC screening and Southern hybridization analyses showed that all RGCs were single copy sequences except RCa6 that represented a large and diverse gene family. One BAC contained five NBS sequences and sequence analysis allowed the identification of two complete RGCs encoding two highly similar proteins. This BAC was located on linkage group J with three other RGC-containing BACs. At least one of these genes, RGC2, is expressed constitutively in cassava tissues.Communicated by M.-A. Grandbastien     

Identification of two cassava receptor-like cytoplasmic kinase genes related to disease resistance via genome-wide and functional analysis

Receptor-like cytoplasmic kinases (RLCKs) play important roles in various developmental processes and stress responses in plants. Whereas, the detailed information of this family in cassava has not clear yet. In this study, A total of 322 MeRLCK genes were identified in the cassava genome, and they could be divided into twelve clades (Clades I-XII) according to their phylogenetic relationships. Most RLCK members in the same clade have similar characteristics and motif compositions. Over half of the RLCKs possess cis-elements in their promoters that respond to ABA, MeJA, defense reactions, and stress. Under Xpm11 infection, the expression levels of four genes show significant changes, suggesting their involvement in Xpm11 resistance. Two RLCK (MeRLCK11 and MeRLCK84) genes potentially involved in resistance to cassava bacterial blight were identified through VIGS experiments. This work laid the foundation for studying the function of the cassava RLCK genes, especially the genes related to pathogen resistance.     

Phylogenetic analysis of AAA proteins

AAA ATPases form a large protein family with manifold cellular roles. They belong to the AAA+ superfamily of ringshaped P-loop NTPases, which exert their activity through the energy-dependent unfolding of macromolecules. Phylogenetic analyses have suggested the existence of five major clades of AAA domains (proteasome subunits, metalloproteases, domains D1 and D2 of ATPases with two AAA domains, and the MSP1/katanin/spastin group), as well as a number of deeply branching minor clades. These analyses however have been characterized by a lack of consistency in defining the boundaries of the AAA family. We have used cluster analysis to delineate unambiguously the group of AAA sequences within the AAA+ superfamily. Phylogenetic and cluster analysis of this sequence set revealed the existence of a sixth major AAA clade, comprising the mitochondrial, membrane-bound protein BCS1 and its homologues. In addition, we identified several deep branches consisting mainly of hypothetical proteins resulting from genomic projects. Analysis of the AAA N-domains provided direct support for the obtained phylogeny for most branches, but revealed some deep splits that had not been apparent from phylogenetic analysis and some unexpected similarities between distant clades. It also revealed highly degenerate D1 domains in plant MSP1 sequences and in at least one deeply branching group of hypothetical proteins (YC46), showing that AAA proteins with two ATPase domains arose at least three times independently.     

Molecular Phylogeny and Evolution of the Plant-Specific Seven-Transmembrane MLO Family

Abstract Homologues of barley Mlo encode the only family of seven-transmembrane (TM) proteins in plants. Their topology, subcellular localization, and sequence diversification are reminiscent of those of G-protein coupled receptors (GPCRs) from animals and fungi. We present a computational analysis of MLO family members based on 31 full-size and 3 partial sequences, which originate from several monocot species, the dicot Arabidopsis thaliana, and the moss Ceratodon purpureus. This enabled us to date the origin of the Mlo gene family back at least to the early stages of land plant evolution. The genomic organization of the corresponding genes supports a monophyletic origin of the Mlo gene family. Phylogenetic analysis revealed five clades, of which three contain both monocot and dicot members, while two indicate class-specific diversification. Analysis of the ratio of nonsynonymous-to-synonymous changes in coding sequences provided evidence for functional constraint on the evolution of the DNA sequences and purifying selection, which appears to be reduced in the first extracellular loop of 12 closely related orthologues. The 31 full-size sequences were examined for potential domain-specific intramolecular coevolution. This revealed evidence for concerted evolution of all three cytoplasmic domains with each other and the C-terminal cytoplasmic tail, suggesting interplay of all intracellular domains for MLO function.     

Molecular evolution of a family of resistance gene analogs of nucleotide-binding site sequences in <Emphasis Type="Italic">Solanum lycopersicum</Emphasis>

Nucleotide-binding site-leucine-rich repeats (NBS-LRR) gene families are one of the major plant resistance genes. Genomic NBS evolution was studied in many plant species for diverse arrays of NBS gene families. In this study, we focused on one family of NBS sequences in an attempt to understand how closely related NBS sequences evolved in the light of selection in domesticated plant species. A phylogenetic analysis revealed five major clades (A–E) and five subclades (A1–A5) within clade A of cloned NBS sequences. Positive selection was only detected in newly evolved NBS lineages in subclades of clade A. Positively selected codon sites were found among NBS sequences of clade A. A sliding-window analysis revealed that regions with Ka/Ks ratios of >1 were in the inter-motifs when paired clades were compared, but regions with Ka/Ks ratios of >1 were found across NBS sequences when subclades of clade A were compared. Our results based on a family of closely related NBS sequences showed that positive selection was first exerted on specific lineages across all NBS sequences after selective constraints. Subsequently, sequences with mutations in commonly conserved motifs were scrutinized by purifying selection. In the long term, conserved high frequency alleles in commonly conserved motifs and changes in inter-motifs were maintained in the investigated family of NBS sequences. Moreover, codons identified to be under positive selection in the inter-motifs were mainly located in regions involved in functions of ATP binding or hydrolysis.     

我国汉坦病毒基因型和基因亚型的分布研究

为了搞清全国汉坦病毒的基因型和亚型的分布情况,广泛收集了全国各地汉坦病毒毒株、阳性病人血清和阳性鼠肺,并应用RT-PCR的方法,应用汉坦病毒型特异性引物,对这些不同来源的阳性标本中汉坦病毒型特异性M和S片段进行扩增和测序,并与其它已知病毒序列进行比较,以明确其型别和亚型及其在全国的分布情况.结果表明:我国HFRS各疫区仍然为HTNV和SEOV两型病毒,但亚型分布差异较大,其中HTNV可分为9个亚型,SEOV则有4～6个亚型.Q32株的部分M和S片段分属于H9和H2亚型,是一个基因重排病毒,而Nc167株在系统发生上与其它HTNV明显不同,比较核苷酸序列发现,其M片段与其它HTNV的同源性在71.3%～76.7%之间,S片段与其它HTNV的同源性只有52.3%～57.8%,可能是一个新型病毒.