云南悬钩子蔷薇NBS-LRR类抗病基因同源克隆与分析

为研究云南野生蔷薇属中的NBS类抗病基因,根据已知抗病基因NBSLRR序列中的保守区域设计简并引物,利用RTPCR技术从云南悬钩子蔷薇中进行体外扩增,获得了对应区域的cDNA片段,回收、克隆这些特异片段,测序分析,共得到4个含有NBSLRR保守结构域的抗病基因同源序列（RGAs）,分别命名为AC9、AC39、AC50和AC68。它们与已报道的11个NBS类抗病基因相应区段的氨基酸序列相似性为5.4%~79.2%,其中这4个RGAs片段与Mi、RPS2、Pib和RPM1基因聚为一类。表明这4条RGAs序列可进一步用作悬钩子蔷薇抗病候选基因的分子筛选及遗传图谱的构建。     

云南悬钩子蔷薇NBS LRR类抗病基因同源克隆与分析

为研究云南野生蔷薇属中的NBS类抗病基因,根据已知抗病基因NBS LRR序列中的保守区域设计简并引物,利用RT PCR技术从云南悬钩子蔷薇中进行体外扩增,获得了对应区域的cDNA片段,回收、克隆这些特异片段,测序分析,共得到4个含有NBS LRR保守结构域的抗病基因同源序列(RGAs),分别命名为AC9、AC39、AC50和AC68。它们与已报道的11个NBS类抗病基因相应区段的氨基酸序列相似性为5.4%~79.2%,其中这4个RGAs片段与Mi、RPS2、Pib和RPM1基因聚为一类。表明这4条RGAs序列可进一步用作悬钩子蔷薇抗病候选基因的分子筛选及遗传图谱的构建。     

植物NBS类抗病基因的进化

NBS(Nucleotide-binding site)类抗病基因是植物中最重要的一类抗病基因, 其进化模式、结构特点和功能调控一直是抗病基因研究领域的热点。这类基因具有保守的结构域, 广泛存在于植物基因组中, 在不同植物基因组中数目差异较大且具有较低的表达量。此外, 同源NBS类抗病基因之间通过频繁的序列交换产生广泛的序列多样性, 且抗病基因位点具有较差的线性。依据基因之间序列交换的频率, 抗病基因可分为TypeⅠ和TypeⅡ两类。文章从抗病基因的结构、数量、分布、序列多样性、进化模式以及表达调控等方面进行了综述, 旨在为后续NBS类抗病基因的相关研究提供参考。     

三浅裂野牵牛NBS类抗病基因同源序列的克隆与分析

NBS类植物抗病基因保守结构域的克隆为利用简并引物扩增抗病基因同源序列提供了可能.根据抗病基因Gro1-4、Gpa2、N等的P-loop和GLPL保守结构域设计简并引物,分离甘薯近缘野生种三浅裂野牵牛NBS类型抗病基因同源序列,共获得6条相关序列,核苷酸序列的相似性为48%~97%,推测氨基酸序列的相似性在25.2%~95.1%之间.系统进化分析表明,6条三浅裂野牵牛RGA序列可分为2个不同的类群:TIR-NBS和non-TIR-NBS.三浅裂野牵牛RGA序列与源自甘薯的RGA序列有很高的相似性,这在一定程度上反映了三浅裂野牵牛与甘薯之间的亲缘关系.分离的6条RGA序列分别命名为ItRGA1~ItRGA6,GenBank登录号分别为DQ849027~DQ849032.     

小麦NBS类抗病基因同源cDNA序列的克隆与特征分析

根据已克隆植物抗病(R)基因NBS保守结构域设计简并引物,采用RT-PCR和cDNA末端快速扩增技术(RACE),在小麦抗叶锈病近等基因系材料TcLr19中进行抗病同源基因cDNA全长的扩增。获得了1个通读的NBS类抗病同源基因S11A11cDNA序列,该序列全长2923bp,编码878个氨基酸序列。生物信息学分析结果表明,该片段含有NB-ARC保守结构域和多个LRR结构域。聚类分析表明,S11A11编码的蛋白与小麦抗叶锈病基因Lr1编码的蛋白亲缘关系较近,而与Lr10亲缘关系较远。半定量RT-PCR分析表明,该基因在小麦叶片中为低丰度组成型表达。本研究在TcLr19小麦中成功获得了抗病基因同源序列,为最终克隆小麦抗叶锈病目的基因奠定了基础。     

植物TIR-NB-LRR类型抗病基因各结构域的研究进展

植物抗病反应是一个多基因调控的复杂过程,在这个过程中R基因发挥了非常重要的作用。根据其氨基酸基序组成以及跨膜结构域的不同,R基因可以分为多种类型,其中NBS-LRR类型是植物基因组中最大的基因家族之一。TIR-NB-LRR类型的抗病基因又是NB-LRR类型中的一大类,也是目前抗病基因研究的热点。该文总结了TIR-NB-LRR类型抗病基因各个结构域的功能和相关的研究进展。相关研究表明,TIR结构域主要通过自身或异源的二聚体化介导抗性信号的转导,但也有部分研究表明,该结构域可能参与病原菌的特异性识别。NBS结构域常被认为具有"分子开关"的功能,它可以通过结合ADP或ATP来调节植物抗病蛋白的构象变化,从而调节下游抗病信号的传导。LRR结构域在植物与病原菌互作的过程中可以通过与病原菌的无毒蛋白直接或间接互作来特异识别病原菌。也有研究发现,LRR结构域具有调节信号传导的功能。这些信息将为研究植物抗病机理提供理论依据,也为将来通过基因编辑技术对作物进行定向抗病育种提供思路。     

甜瓜抗霜霉病基因同源序列克隆与分析

采用RT—PCR扩增的方法,从高抗霜霉病甜瓜品种‘日本安农二号’中克隆到约3kb的cDNA片段（命名为MRGH-D,该基因是一个连续的通读编码框,编码1007个氨基酸。推测的蛋白质分子量为113．7kDa,等电点为7．88,蛋白质预测无跨膜区。根据推测的氨基酸序列,该基因属于TIR—NBS—LRR类抗病基因,具有TIR-NBS—LRR类抗病基因所有的保守结构域。核苷酸序列和氨基酸序列同源性分析结果显示,MRGH-J与甜瓜抗病基因的同源序列MRGHl2及抗霜霉病相关基因mp-19均具有高达99％的同源性,推测该基因可能在甜瓜抗霜霉病中起作用。     

甜瓜抗枯萎病基因同源序列克隆与序列分析

目的:克隆甜瓜抗枯萎病基因同源序列并对其序列分析。方法:根据已发表的甜瓜抗枯萎病基因Fom-2设计引物,从高抗枯萎病甜瓜品种‘日本安农二号’基因组中扩增Fom-2同源序列R-Fom-2。结果:该基因长3307bp,包含一个完整的开放阅读框,编码1073个氨基酸,推测蛋白质分子量123.57kDa,等电点7.06。属于nonTIR-NBS-LRR类抗病基因,在LRR区存在一个可能的CC结构域。但在nonTIR类抗病蛋白中,CC结构域一般位于kin-1a前。氨基酸同源性分析显示,R-Fom-2同Fom-2全长序列具有96%的同源性,对不同甜瓜品种Fom-2的LRR区分析比较,同源性在91%以上。且LRR区的差异主要集中在β-strand/β-turn区域。结论:序列分析揭示Fom-2家族是一个活跃的基因,LRR区可能对Fom-2家族的功能起着重要作用,为进一步研究R-Fom-2基因的结构与生物学功能奠定了基础。     

大豆抗病基因同源序列的克隆与分析

已克隆的植物抗病基因序列存在一些相对保守的结构区域.利用根据核苷酸结合位点(NBS)结构域扩增所获得的大豆抗病基因同源片段为混合探针,进行大豆cDNA文库筛选.通过筛库和5'RACE-PCR扩增后,获得一全长基因KR3.KR3的长度为2353 bp,编码636个氨基酸.KR3蛋白在结构上与烟草抗花叶病毒N基因蛋白有较高的同源性,具有Toll/白细胞介素-1受体(TIR)、NBS等抗病基因的分子特征.Southern杂交显示KR3在基因组中为低拷贝;RT-PCR分析表明,该基因的表达受外源水杨酸的诱导.     

水稻白叶枯病候选抗性基因SHNLR的RGAs克隆及分析

旨在从含有疣粒野生稻抗白叶枯病基因的新种质SH5、SH76基因组中克隆抗病基因。利用RGAs法得到1个NBS-LRR类同源基因,暂命名为SHNLR(登录号为JF934724)。结果表明,SHNLR的开放阅读框长度为3 105 bp,编码1 034个氨基酸,含有CC、NB-ARC与LRR结构域,具备CC-NBS-LRR类植物抗病基因的结构特征。BLASTn和BLASTp比对显示SHNLR是单拷贝基因,未发现同源性较高且功能已知的基因,仅NBS保守域序列与番茄Prf基因的相似度最高。对SHNLR基因电子定位,发现其位于水稻第11号染色体的长臂末端,但与11号染色体上已定位或克隆的8个白叶枯病抗性基因具有不同序列或处于不同的位置。半定量RT-PCR分析表明,SHNLR在抗病新种质叶片中的表达明显受到白叶枯病菌Zhe173的诱导。因此推测SHNLR可能是1个与抗白叶枯病相关的R基因。     

Evolutionary meta-analysis of solanaceous resistance gene and solanum resistance gene analog sequences and a practical framework for cross-species comparisons

Cross-species comparative genomics approaches have been employed to map and clone many important disease resistance (R) genes from Solanum species-especially wild relatives of potato and tomato. These efforts will increase with the recent release of potato genome sequence and the impending release of tomato genome sequence. Most R genes belong to the prominent nucleotide binding site-leucine rich repeat (NBS-LRR) class and conserved NBS-LRR protein motifs enable survey of the R gene space of a plant genome by generation of resistance gene analogs (RGA), polymerase chain reaction fragments derived from R genes. We generated a collection of 97 RGA from the disease-resistant wild potato S. bulbocastanum, complementing smaller collections from other Solanum species. To further comparative genomics approaches, we combined all known Solanum RGA and cloned solanaceous NBS-LRR gene sequences, nearly 800 sequences in total, into a single meta-analysis. We defined R gene diversity bins that reflect both evolutionary relationships and DNA cross-hybridization results. The resulting framework is amendable and expandable, providing the research community with a common vocabulary for present and future study of R gene lineages. Through a series of sequence and hybridization experiments, we demonstrate that all tested R gene lineages are of ancient origin, are shared between Solanum species, and can be successfully accessed via comparative genomics approaches.     

甘薯NBS类抗病基因类似物的分离与序列分析

利用已克隆植物抗病基因NBS（Nucleotide binding site）序列中的保守模体（motif）“P-loop”和“GLPL”合成简并引物,以甘薯（Ipomoea batatas）栽培品种青农2号基因组DNA为模板进行PCR扩增,通过T/A克隆、测序和序列分析,共得到15条具有连续ORF的抗病基因类似物（Resistance gene analogues,RGAs）序列,它们之间核苷酸序列间的相似性系数在41.2%-99.4%之间,而相应推测的氨基酸序列间的相似性系数在20.6%-100%之间,同时对分离的RGAs的核苷酸和氨基酸序列进行系统发育树分析,表明甘薯RGAs可分为TIR（Drosophila Toll or human interleukin receptor-like）和nonTIR两类.对甘薯RGAs和5个已克隆植物NBS的氨基酸序列进行结构分析表明,它们包括“P-loop”、“Kinase-2”、“Kinase-3a”、“GLPL”4个抗病基因所共有的保守模体.这些表明甘薯与其它物种的NBS类RGAs可能具有同样的起源和进化机制.     

L-galactono-gamma-lactone dehydrogenase from sweet potato: purification and cDNA sequence analysis

L-Galactono-gamma-lactone dehydrogenase (EC 1.3.2.3, GLDHase) was partially purified from mitochondria of sweet potato tuberous roots over 600-fold on a specific activity basis, followed by purification of the enzyme protein of 56 kDa by a preparative SDS-PAGE. The absorption spectrum of the hydroxylapatite column-purified GLDH-ase showed peaks at 448 and 373 nm, suggesting the presence of flavin as a prosthetic group. The activity of GLDH-ase was inhibited by lycorine, an alkaloid which inhibits ascorbic acid biosynthesis in vivo. N-terminal partial sequences of four internal polypeptides generated by partial digestion of GLDHase with V8 protease were determined. The deduced nucleotide sequences were used to amplify a cDNA fragment of the GLDHase gene. The clone encoded a polypeptide of 581 amino acid residues with a molecular mass of 66 kDa. The deduced amino acid sequence showed 77% identity with that of cauliflower GLDHase, and significant homology to those of L-gulono-gamma-lactone oxidase (22% identity) from rat and L-galactono-gamma-lactone oxidase from yeast (17% identity), which are enzymes involved in L-ascorbic acid biosynthesis in these organisms. The absorption spectrum and cDNA sequence suggested that the flavin group bound noncovalently. We conclude that GLDHase, L-gulono-gamma-lactone oxidase and L-galactono-gamma-lactone oxidase are homologous in spite of the difference in substrates and electron acceptors. Genomic Southern analysis suggested that GLDHase gene exists as a single copy in the genome of sweet potato.     

Diversity and evolutionary relationship of nucleotide binding site-encoding disease-resistance gene analogues in sweet potato (<Emphasis Type="Italic">Ipomoea batatas</Emphasis> Lam.)

Most plant disease-resistance genes (R-genes) isolated so far encode proteins with a nucleotide binding site (NBS) domain and belong to a superfamily. NBS domains related to R-genes show a highly conserved backbone of an amino acid motif, which makes it possible to isolate resistance gene analogues (RGAs) by degenerate primers. Degenerate primers based on the conserved motif (P-loop and GLPL) of the NBS domain from R -genes were used to isolate RGAs from the genomic DNA of sweet potato cultivar Qingnong no.2. Five distinct clusters of RGAs (22 sequences) with the characteristic NBS representing a highly diverse sample were identified in sweet potato genomic DNA. Sequence identity among the 22 RGA nucleotide sequences ranged from 41.2% to 99.4%, while the deduced amino acid sequence identity from the 22 RGAs ranged from 20.6%to 100%. The analysis of sweet potato RGA sequences suggested mutation as the primary source of diversity. The phylogenetic analyses for RGA nucleotide sequences and deduced amino acids showed that RGAs from sweet potato were classified into two distinct groups--toll and interleukin receptor-1 (TIR)-NBS-LRR and non-TIR-NBS-LRR. The high degree of similarity between sweet potato RGAs and NBS sequences derived from R-genes cloned from tomato, tobacco, flax and potato suggest an ancestral relationship. Further studies showed that the ratio of non-synonymous to synonymous substitution within families was low. These data obtained from sweet potato suggest that the evolution of NBS-encoding sequences in sweet potato occur by the gradual accumulation of mutations leading to purifying selection and slow rates of divergence within distinct R-gene families.     

Evaluating Quantitative Variation in the Genome of ZEA MAYS

Genomic diversity within the species Zea mays has been examined by measuring the variation in the repetitive component of the nuclear genome among North American inbred lines and varieties. This was done by preparing a set of clones of repetitive maize sequences that differ in function, molecular arrangement and multiplicity and then using these as probes for quantitative hybridization to DNA from various maize genotypes. The comparison showed that the majority of repeated sequences are markedly variable in copy number among the ten maize strains tested.The clone sample contained the rDNA and 5S genes, the major repeat of the chromosome knobs, sequences functioning as origins of DNA replication in yeast (ARS sequences) and randomly cloned sequences of unknown function and chromosomal location. The sequences ranged in reiteration frequency from 200 to greater than 10(5) copies and included both tandemly arrayed and dispersed repeats. The copy numbers were measured by hybridizing labeled cloned sequences to aliquots of high molecular weight genomic DNA that were applied to nitrocellulose filters through a slotted template (slot blotting). The hybridization signal on an autoradiogram occurred in a narrow band that could be scored reliably with a densitometer. This provided a rapid method of determining the abundance of particular repeated sequences in individual plants and plant populations. Using this technique, we found that the copy number of repeated sequences of all types generally varied among the strains by two- to threefold, although at least one sequence showed no detectable variation. In contrast to the variability found between strains, individuals within an inbred line or variety were found to be indistinguishable in terms of specific sequence multiplicity. Each genotype has a different pattern of copy numbers for the set of repeated sequence clones, and this pattern is characteristic of all individuals of a particular genotype. The data also show that the copy number of each sequence varies independently. No strains had uniformly high or low copy numbers for the entire set of probes.     

A Major Jasmonate-Inducible Protein of Sweet Potato, Ipomoelin, is an ABA-Independent Wound-Inducible Protein

Treatment of sweet potato plants cultured in vitro with a vaporof methyl jasmonate (MeJA) induced an accumulation in leavesof a large amount of protein with an apparent molecular massof 18 kDa. This protein, designated ipomoelin, was purified,and the amino acid sequences of proteolytic fragments were determined.Screening a cDNA library of MeJA-treated leaves by oligonucleotideprobes designed from the peptide sequences identified a clonethat could code for a polypeptide with 154 amino acids. Thededuced amino acid sequence of ipomoelin showed an overall aminoacid identity of 25% with the salt-inducible SalT protein ofrice. In addition, the C-terminal 70 amino acid sequence ofipomoelin showed about 50% identity with the C-terminal aminoacid sequences of seed lectins from Moraceae. The gene for ipomoelinwas present in a few copies in the genome of sweet potato. ThemRNA for ipomoelin was detected in leaves and petioles, butnot in stems and tuberous roots, of sweet potato plants grownin the field. Mechanical wounding of leaves induced ipomoelinmRNA both locally and systemically, while treatment of leaveswith ABA, salt, or a high level of sucrose did not induce ipomoelinmRNA. By contrast, ABA-inducible mRNA for sporamin was not inducedby MeJA. These results suggest that ipomoelin is involved indefensive reactions of leaves in response to wounding and thatJA-mediated wound-induction of ipomoelin occurs independentlyof ABA. (Received January 6, 1997; Accepted March 13, 1997)