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.     

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。     

陆地棉抗病基因同源序列的克隆与分析

根据已知抗病基因NBS保守区的P-loop和GLPL区设计一对简并引物F1/R1,以7个抗黄萎病陆地棉品种和2个感黄萎病品种的基因组DNA为模板进行PCR扩增.在9个品种中均扩增出500 bp左右的条带.对目的条带进行回收,连接、转化克隆得到350个阳性克隆,进行测序.在8个棉花品种中克隆到74条具有完整开放读码框的棉花RGAs序列.这74条序列共有64种不同的基因型,有10条与其他品种中的RGAs序列相同.用MEGA软件对8个棉花品种的74条RGA序列以及12个已知的抗病基因的NBS区域进行聚类分析,可分为4类;4类RGAs之间的相似性较低,各类之内的RGAs虽然来自不同品种,氨基酸序列的相似度却非常高.推测各大类中相似性较高的序列分别属于同一个基因家族,从位点上说可能处于同一个基因簇.     

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。     

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。     

小麦抗赤霉病品种NBS同源序列克隆与分析

根据二穗短柄草NBS-LRR类基因的保守序列设计同源引物,以小麦抗赤霉病品种苏麦3号、宁7840和望水白基因组DNA为模板,通过PCR扩增,得到43条序列,其中4条为非编码序列或结构域不完整;39条与植物抗病基因同源,其中的7条内部存在终止密码子,可能是假基因,经过比对分析,其余32条具有连续的开放阅读框和保守结构域,推导的氨基酸序列均具有Kinase-1a、Kinase-2和Kinase-3a及GLPL区等几个保守区,在GenBank中均能找到与之高度同源的其他物种的核酸序列,并且Kinase-2的最后一个氨基酸均为色氨酸(W),属于non-TIR类NBS基因。32条序列可分为4大类,它们之间核苷酸同源性为64%-98%,编码氨基酸同源性为22%-98%。根据序列分析随机设计5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,7-1、s-3、s-4和w-2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;7-13不表达,再次证明属于假基因。32条序列在之前未被报道过,这些RGA可以作为筛选赤霉病功能性抗病基因的候选序列。     

芒果NBS类抗病基因同源序列克隆与分析

根据已知物种NBS抗病类基因（RGAs）保守序列设计引物,从芒果品种“金煌”基因组DNA中分离得到了10条同源序列（pp-1~10,GenBnak登录号为HM446507~16）。DNA序列分析表明,这些RGAs在200~300bp区间存在较大变异,Pi值都在0.4以上。同源性分析表明这些序列的同源性差异范围从11.0%~98.4%,离散值范围为1.6~100.7, 10条RGAs可以分为两大类。蛋白序列分析表明,pp-1~10都具有开放读码框,编码的蛋白含有典型的NBS抗病类基因所拥有的P-loop和Kinase-2a结构域,通过同源进化分析可将其分为TIR-NBS-LRR和CC-NBS-LRR两类,与已知物种同源性分别为22%~60%。     

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。     

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。     

小麦NBS-LRR类抗病基因同源序列的分离与鉴定

根据已知植物抗病基因的保守区域设计引物,从抗锈病小麦品种西农88基因组DNA扩增出3条与植物抗病基因同源的序列,分别为WRGA1、WRGA2和WRGA14。这三条同源片段均含有典型的NBS-LRR类抗病基因所拥有的保守性结构域Kinase-2a、Kinase-3a和疏水结构域(HD)．它们与部分已知NBS-LRR类抗病基因的氨基酸序列同源性为46．0%-9．9%,三个片段间在氨基酸水平上的同源性为80．7%-56．8%。Northern杂交表明WRGA1在小麦中受水杨酸正调控,属诱导型表达。     

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.     

Isolation of a family of resistance gene analogue sequences of the nucleotide binding site (NBS) type from Lens species.

Most known plant disease-resistance genes (R genes) include in their encoded products domains such as a nucleotide-binding site (NBS) or leucine-rich repeats (LRRs). Sequences with unknown function, but encoding these conserved domains, have been defined as resistance gene analogues (RGAs). The conserved motifs within plant NBS domains make it possible to use degenerate primers and PCR to isolate RGAs. We used degenerate primers deduced from conserved motifs in the NBS domain of NBS-LRR resistance proteins to amplify genomic sequences from Lens species. Fragments from approximately 500-850 bp were obtained. The nucleotide sequence analysis of these fragments revealed 32 different RGA sequences in Lens species with a high similarity (up to 91%) to RGAs from other plants. The predicted amino acid sequences showed that lentil sequences contain all the conserved motifs (P-loop, kinase-2, kinase-3a, GLPL, and MHD) present in the majority of other known plant NBS-LRR resistance genes. Phylogenetic analyses grouped the Lens NBS sequences with the Toll and interleukin-1 receptor (TIR) subclass of NBS-LRR genes, as well as with RGA sequences isolated from other legume species. Using inverse PCR on one putative RGA of lentil, we were able to amplify the flanking regions of this sequence, which contained features found in R proteins.     

PCR-based approach for mining of resistant gene analogues in taro (Colocasia esculenta)

Primers based on the conserved motifs were used to isolate nucleotide-binding sites (NBS) type sequences in taro (Colocasia esculenta). Cloning and sequencing identified three taro NBS-type sequences called resistance gene analogues (RGAs) that depicted similarity to other cloned RGA sequences. The deduced amino acid sequences of the RGAs detected the presence of conserved domains, viz. P-loop, categorising them with the NBS–leucine-rich repeat class gene family. Phylogenetic characterisation of the taro RGAs along with RGAs of other plant species grouped them with the non-toll interleukin receptor subclasses of the NBS sequences. The isolation and characterisation of taro RGAs have been reported for the first time in this study. This will provide a starting point towards characterisation of candidate resistance genes in taro and can act as a reference guide for future studies.     

Isolation, characterization and evolutionary analysis of resistance gene analogs in annual ryegrass, perennial ryegrass and their hybrid

Recently, a number of disease-resistance genes related to a diverse range of pathogens were isolated from a wide variety of plant species. The majority of plant disease-resistance genes encoded a nucleotide-binding site (NBS) domain. According to the comparisons of the NBS domain of cloned R -genes, it has shown highly conserved amino acid motifs in this structure, which made it possible to isolate resistance gene analogs (RGAs) by PCR using degenerate primers. We have designed three pairs of degenerate primers based on two conserved motifs in the NBS domain of resistance proteins encoded by R -genes to amplify genomic sequences from ryegrass ( Lolium sp.). Sixteen NBS-like RGAs were isolated from turf and forage type grasses. The sequence analysis of these RGAs revealed that there existed a high similarity (up to 85%) between RGA sequences among ryegrass species and other plants. The alignment of the predicted amino acid sequences of RGAs showed that ryegrass RGAs contained four conserved motifs (P-Loop, kinase-2, kinase-3a, GLPL) present in other known plant NBS-leucine rich repeat resistance genes. These ryegrass RGAs all belonged to non-toll and interleukin-1 receptor subclass. Phylogenetic analysis of ryegrass RGAs and other cloned R -genes indicated that gene mutation was the predominant source of gene variations, and the sequence polymorphism was due to purifying selection rather than diversifying selection. We further analyzed the source of gene variation in other monocots, rice, barley, wheat, and maize based on the data published before. Our analysis indicated that the source of RGA diversity in these monocots was the same as in ryegrass. Thus, monocots were probably the same as dicots in the source of RGA diversity. Ryegrass RGAs in the present paper represented a large group of resistance gene homologs in monocots. We discussed the origin and the evolution of R -genes in grass species.     

Characterization and linkage mapping of R-gene analogous DNA sequences in pea (Pisum sativum L.)

Pea (Pisum sativum L.) sequences that are analogous to the conserved nucleotide binding site (NBS) domain found in a number of plant disease resistance genes (R-genes) were cloned. Using redundant oligonucleotide primers and the polymerase chain reaction (PCR), we amplified nine pea sequences and characterised their sequences. The pea R-gene analog (RGA)- deduced amino acid sequences demonstrated significant sequence similarity with known R-gene sequences lodged in public databases. The genomic locations of eight of the pea RGAs were determined by linkage mapping. The eight RGAs identified ten loci that mapped to six linkage groups. In addition, the genomic organization of the RGAs was inferred. Both single-copy and multicopy sequence families were present among the RGAs, and the multicopy families occurred most often as tightly linked clusters of related sequences. Intraspecific copy number variability was observed in three of the RGA sequence families, suggesting that these sequence families are evolving rapidly. The genomic locations of the pea RGAs were compared with the locations of known pea R-genes and sym genes involved in the pea-rhizobia symbiosis. Two pea RGAs mapped in the genomic region containing a pea R-gene, Fw, and four pea RGAs mapped in regions of the genome containing sym genes. Received: 4 August 1999 / Accepted: 11 November 1999     

Origin, diversity and evolution of NBS-type disease-resistance gene homologues in coffee trees (Coffea L.)

The majority of plant disease-resistance genes (R-genes) isolated so far encode a predicted nucleotide-binding site (NBS) domain. NBS domains related to R-genes show a highly conserved backbone of amino acid motifs, which makes it possible to isolate resistance gene analogues (RGAs) by PCR with degenerate primers. Multiple combinations of primers with low degeneracy, designed from two conserved motifs in the NBS regions of R-genes of various plants, were used on genomic DNA from coffee trees, an important perennial tropical crop. Nine distinct classes of RGAs of the NBS-like type, representing a highly diverse sample, were isolated from Coffea arabica and C. canephora species. The analysis of one coffee RGA family suggested point mutations as the primary source of diversity. With one exception, coffee RGA families appeared to be closely related in sequence to at least one cloned R-gene. In addition, deduced amino acid sequences of coffee RGAs were identified that showed strong sequence similarity to almost all known non-TIR (Toll/Interleukin 1 Receptor)-type R-genes. The high degree of similarity between particular coffee RGAs and R-genes isolated from other angiosperm species, such as Arabidopsis, tomato and rice, indicates an ancestral relationship and the existence of common ancestors. The data obtained from coffee species suggests that the evolution of NBS-encoding sequences involves the gradual accumulation of mutations and slow rates of divergence within distinct R-gene families, rather than being a rapid process. Functional inferences drawn from the suggested pattern of evolution of NBS-type R-genes is also discussed.     

Cloning,structural features,and expression analysis of resistance gene analogs in Tobacco

Using degenerate primers based on the conserved nucleotide binding site (NBS) and protein kinase domain (PKD), 100 resistance gene analogs (RGAs) were isolated from tobacco variety Nicotiana repanda. BLASTx search against the GenBank database revealed that 27 belong to the NBS class and 73 belong to the protein kinase (PK) class. Cluster analysis and multiple sequence alignment of the deduced protein sequences indicate that RGAs of the NBS class can be divided into two groups: toll/interleukin receptor (TIR) and non-TIR types. Both types possess 6 conserved motifs (P-loop, RNBS-A, Kinase-2, RNBS-B, RNBS-C, GLPL). Based on their sequence similarity, the tobacco RGAs of the PK class were assigned to 8 subclasses. We examined their expression after infection with either Tobacco mosaic virus (TMV) or the tobacco black shank pathogen (Phytophthora parasitica var. nicotianae). The expression levels of 4 RGAs of the PK class were significantly elevated by TMV and 1 RGA of the PK class and 3 RGAs of the NBS class were up-regulated by P. parasitica var. nicotianae. The expression of two RGAs of the PK class was induced by P. parasitica var. nicotianae. Infection by either TMV or P. parasitica var. nicotianae enhanced the expression of NtRGA2, a RGA of the PK class. The present study shows that RGAs are abundant in the tobacco genome and the identification of tobacco RGAs induced by pathogens should provide valuable information for cloning related resistance genes in tobacco.     

Characterization and mapping of NBS-LRR resistance gene analogs in apricot (Prunus armeniaca L.)

Genomic DNA sequences sharing homology with the NBS-LRR (nucleotide binding site-leucine-rich repeat) resistance genes were isolated and cloned from apricot (Prunus armeniaca L.) using a PCR approach with degenerate primers designed from conserved regions of the NBS domain. Restriction digestion and sequence analyses of the amplified fragments led to the identification of 43 unique amino acid sequences grouped into six families of resistance gene analogs (RGAs). All of the RGAs identified belong to the Toll-Interleukin receptor (TIR) group of the plant disease resistance genes (R-genes). RGA-specific primers based on non-conserved regions of the NBS domain were developed from the consensus sequences of each RGA family. These primers were used to develop amplified fragment length polymorphism (AFLP)-RGA markers by means of an AFLP-modified procedure where one standard primer is substituted by an RGA-specific primer. Using this method, 27 polymorphic markers, six of which shared homology with the TIR class of the NBS-LRR R-genes, were obtained from 17 different primer combinations. Of these 27 markers, 16 mapped in an apricot genetic map previously constructed from the self-pollination of the cultivar Lito. The development of AFLP-RGA markers may prove to be useful for marker-assisted selection and map-based cloning of R-genes in apricot.