不结球白菜BcTuRsO基因的克隆及表达

从不结球白菜抗病品种短白梗中克隆到一个抗芜菁花叶病毒(TuMV)相关基因,命名为BcTuRsO(Gen-Bank登录号FJ600376).该基因核苷酸序列全长650 bp,编码194个氨基酸,与已克隆的抗病基因有不同程度的同源性.系统进化树分析表明,该基因在不同物种之间具有保守性.基因组DNA杂交表明,BcTuRsO基因可能以单拷贝形式存在,其表达是组成型的.实时定量PCR检测表明,芜菁花叶病毒能够诱导不结球白菜BcTuRsO基因的转录表达,其在不结球白菜叶片中的表达特征说明它可能参与寄主对病毒的抗性.     

不结球白菜热激蛋白基因克隆及表达

从不结球白菜'暑绿'中克隆到一个受热激诱导的小分子量热激蛋白(sHSP)基因,命名为BcHSP(DDBJ登录号为AB367955),该基因核苷酸序列全长722 bp,编码157个氨基酸,与芜菁、芥蓝、拟南芥等有90%以上的相似性.实时定量检测表明,不结球白菜BcHSP转录表达受热激诱导,以叶片中表达量最高,BcHSP在不结球白菜叶片中表达特征说明它可能与植物叶片的耐热性关系更为密切.     

不结球白菜BcLRK01基因对芜菁花叶病毒及胁迫诱导的响应

通过cDNA-AFLP技术,从芜菁花叶病毒(TuMV)侵染的不结球白菜幼叶中分离到一条差异表达的基因片段,克隆获得其cDNA全长为2 124bp,编码707个氨基酸的富亮氨酸重复类受体激酶,命名为BcLRK01。利用实时定量PCR研究了该基因在TuMV侵染及高盐、冷胁迫、水杨酸(SA)、茉莉酸(JA)、乙烯(ET)等处理下的表达情况,结果显示,TuMV侵染、高盐、冷胁迫、SA、JA和ET等均能诱导BcLRK01不同程度的表达,说明该基因可能是不结球白菜病毒病的病程相关基因,同时也参与高盐和冷胁迫以及SA、JA、ET等的信号途径。     

不结球白菜BcMPK4基因的分离及表达

为了进一步探讨植物MAPKs(mitogen-activated protein kinases)在植物防卫中的作用,该研究从不结球白菜抗病品种‘苏州青’中克隆到一个抗核盘菌(Sclerotinia sclerotiorum)相关基因,命名为BcMPK4(DDBJ登录号AB557751)。该基因核苷酸序列全长1 334bp,编码373个氨基酸,与已克隆的MPK4基因有不同程度的相似性。系统进化树分析表明,该基因在不同物种之间具有保守性。基因组DNA杂交表明,BcMPK4可能属于一个较小的多基因家族,属组成型表达。实时定量PCR检测表明,核盘菌能够诱导不结球白菜BcMPK4基因的转录表达;BcMPK4基因在不结球白菜叶片中的表达特征说明它可能参与寄主对核盘菌的抗性。     

不结球白菜PR4蛋白基因的克隆与诱导表达分析

从不结球白菜抗病品种‘苏州青’中克隆到一个受SA和病原菌诱导的病程相关蛋白4(PR4)基因,命名为BcPR4(DDBJ登录号:AB325873),该基因核苷酸序列全长593 bp,编码140个氨基酸,与其它植物的PR4蛋白基因具有较高的相似性。系统进化树分析表明,该基因在不同物种之间具有保守性。基因组DNA杂交表明BcPR4属于多基因家族。实时定量PCR(qPCR)检测表明,SA和Peronospora parasitica均能诱导不结球白菜BcPR4转录表达,BcPR4在不结球白菜叶片中的表达特征说明它可能参与寄主对病原菌的抗性。     

基于相对密码子频率的芜菁花叶病毒基因组序列的进化分析

现有92株芜菁花叶病毒(TuMV)的全基因组序列已在GenBank报道,据分析报道其中58株不含重组序列。利用系统聚类法对92株TuMV的全基因组序列和58株TuMV全基因组序列的相对密码子频率RSCU值进行聚类分析。同时利用系统发育分析方法分析了这92株和58株TuMV全基因组序列。结果发现,92株芜菁花叶病毒株的密码子偏性聚类树与其系统进化树的一致度很低;而不含重组序列的58株芜菁花叶病毒株的密码子偏性聚类树与其系统进化树的一致度却非常高,且与寄生宿主类型基本对应。这表明在不存在重组的情况下,TuMV密码子频率的偏性可能是宿主内的一种选择压力,影响TuMV基因组的点突变进化方向,促使TuMV适应宿主内环境。     

不结球白菜BcDF1.2基因克隆与诱导表达

利用RACE技术,获得了不结球白菜防卫素基因全长序列,命名为BcDF1.2(DDBJ登录号AB302891).序列分析发现,BcDF1.2全长532 bp包含1个长度为96 bp的内含子区域,该基因编码79个氨基酸残基组成的蛋白质,与其他植物的防卫素基因和抗真菌蛋白基因有较高的同源性.系统进化树分析表明,该基因在不同植物间具有高度保守性.基因组DNA杂交表明BcDF1.2属于较小的多基因家族.水杨酸和霜霉病原菌诱导后,该mRNA不仅在诱导的叶片中转录表达增加,而且在未诱导的系统叶片中表达增加.BcDF1.2在不结球白菜叶片中的转录表达特点表明可能参与对霜霉病的抗性反应.     

不结球白菜Ty1-copia类逆转座子序列的克隆及表达

参照Ty1-copia类逆转座子逆转录酶的保守区设计简并引物,分别从10个不结球白菜(Brassica campestris ssp.chinensis)品种的全基因组中均扩增出260 bp左右的目标条带. 将目的条带回收、克隆和测序后进行分析,DNAstar分析发现,这些序列存在高度的异质性,28个核苷酸序列变化范围为224～278 bp,同源性范围为16.7%～83.0%.28条序列通过核苷酸聚类分为8个家族.推导氨基酸序列有移框突变、终止子突变或二者兼有;与已登录的不同物种同一类型逆转录酶氨基酸系统进化树分析表明,不结球白菜Ty1-copia类逆转座子与芥菜型油菜、拟南芥、芜菁、甜菜可能有共同的起源.半定量和实时定量PCR检测表明,水杨酸(salicylic acid)和Peronospora parasitica均能激活不结球白菜Ty1-copia类逆转座子,逆转座子在不结球白菜叶片中的表达特征说明它可能参与寄主对病原菌的抗性.     

芜菁花叶病毒的3’末端序列克隆与CP基因序列分析

目的:克隆芜菁花叶病毒(Turnip mosaic virus,TuMV)的3'末端序列,并进行CP基因序列分析.方法:以TuMV杭州榨菜分离物(TuMv-HZZC)接种病叶为材料,利用病毒粒子吸附法制备病毒RNA模板,经RT-PCR扩增获得了TuMV-HZZC 3'末端序列,将其克隆到PMD 18-T质粒上进行序列分析.结果:TuMV-HZZC分离物3'末端序列包括部分的Nib基因、完整的TuMVCP基因和3'-UTR,CP基因为864bp,分别编码288个氨基酸,3'-UTR序列(不包括PolyA尾巴)为213bp.经过与其他TuMV分离物的CP基因核苷酸和氨基酸比较,同源性分别达到88.0%～97.6%和91.0%-96.5%.结论:TuMV的系统进化具有典型的地域和寄主关联性.     

不结球白菜细胞质雄性不育相关基因的克隆及表达

从不结球白菜CMS新种质中分离得到的一个cDNA-AFLP差异片段,采用RT-PCR和RACE技术成功克隆了一个α-微管基因的cDNA全长序列,命名为TUBA2(DDBJ登录号为AB445012)。序列分析结果表明,该基因全长1 709 bp,最大开放阅读框为1 353 bp,编码450个氨基酸序列,与已公布的α-微管基因有较高的同源性。系统进化树分析发现,该基因在不同植物间具有高度保守性。Southern杂交表明TUBA2属于不结球白菜多基因家族的一个单一克隆基因。实时定量RT-PCR检测表明,该基因在不育系中的表达量显著低于保持系,同时在不同组织和细胞减数分裂不同时期该基因的表达量也存在明显差异。     

花粉发育相关基因BjMF6的分子克隆及其生物信息学分析

根据白菜花粉特异的多聚半乳糖醛酸酶(PG)基因BcMF6的全长序列设计引物,通过PCR直接扩增的方法从茎瘤芥(BrassicajunceaCzern.etCossvar.tumidaTsenetLee)‘浙桐1号’和分蘖芥(Brassicajunceavar.multicepsTsenetLee)‘雪里蕻’中克隆到了BcMF6的同源基因BjMF6t和BjMF6m。BjMF6t和BjMF6m的序列完全相同,故合称BjMF6。该基因与BcMF6在DNA水平的相似性高达99.6%。Blast分析发现它与拟南芥外切PG基因在氨基酸水平上有很高的相似性,并且具有所有PG基因特有的功能结构域和活性位点,推测BjMF6属于PG基因。通过序列分析和系统树构建进一步证明了该基因可能是与花粉发育相关的PG基因。     

The CACTA transposon Bot1 played a major role in Brassica genome divergence and gene proliferation

We isolated and characterized a Brassica C genome-specific CACTA element, which was designated Bot1 (Brassica oleracea transposon 1). After analysing phylogenetic relationships, copy numbers and sequence similarity of Bot1 and Bot1 analogues in B. oleracea (C genome) versus Brassica rapa (A genome), we concluded that Bot1 has encountered several rounds of amplification in the oleracea genome only, and has played a major role in the recent rapa and oleracea genome divergence. We performed in silico analyses of the genomic organization and internal structure of Bot1, and established which segment of Bot1 is C-genome specific. Our work reports a fully characterized Brassica repetitive sequence that can distinguish the Brassica A and C chromosomes in the allotetraploid Brassica napus, by fluorescent in situ hybridization. We demonstrated that Bot1 carries a host S locus-associated SLL3 gene copy. We speculate that Bot1 was involved in the proliferation of SLL3 around the Brassica genome. The present study reinforces the assumption that transposons are a major driver of genome and gene evolution in higher plants.     

Sequence complexity of the S receptor kinase gene family in Brassica

A genomic library from an S ₂₉/S ₂₉ self-incompatible genotype of Brassica oleracea was screened with a probe carrying part of the catalytic domain of a Brassica S-receptor kinase (SRK)-like gene. Six positive phage clones with varying hybridisation intensities (K1 to K6) were purified and characterised. A 650–700 by region corresponding to the probe was excised from each clone and sequenced. DNA and predicted protein sequence comparisons based on a multiple alignment identified K5 as a pseudogene, whereas the others could encode functional proteins. K3 was found to have lost an intron from its genomic sequence. The six genes display different degrees of sequence similarity and form two distinct clusters in a dendrogram. The 98% similarity between K4 and K6, which extends across intron sequences, suggests that these might be very recently diverged alleles or daughters of a duplication. In addition, K2 showed a comparably high similarity to the probe. Clones K1, K3 and K5 cross-hybridised with an SLG ₂₉ cDNA probe, indicating the presence of upstream receptor domains homologous to the Brassica SLG gene. This suggests that the previously reported S sequence complexity may be ascribed to a large receptor kinase gene family.     

一个新的油菜NHX基因电子克隆及序列分析

基于电子克隆的方法,从甘蓝型油菜中获得一个新的反向转运蛋白基因cDNA序列,暂被命名为BnNHX6。BnNHX6包含一个完整的长为1593bp的开放阅读框架,编码530个氨基酸。BnNHX6蛋白属于跨膜蛋白,有9个跨膜区,含有信号肽,预测在质膜上。通过同源比对和进化分析发现,BnNHX6的氨基酸序列与拟南芥AtNHX5和AtNHX6、西红柿LeNHX2、毛白杨PtNHX2基因所编码的氨基酸序列高度同源,同源性分别为78.4%、92.6%、77.1%、76.9%,亲缘关系较近;但与已报道的油菜BnNHX1同源性仅为24.9%,亲缘关系很远,表明BnNHX6是一个新的油菜反向转运蛋白基因。     

A Brassica cDNA clone encoding a bifunctional hydroxymethylpyrimidine kinase/thiamin-phosphate pyrophosphorylase involved in thiamin biosynthesis

We report the characterization of a Brassica napus cDNA clone (pBTH1) encoding a protein (BTH1) with two enzymatic activities in the thiamin biosynthetic pathway, thiamin-phosphate pyrophosphorylase (TMP-PPase) and 2-methyl-4-amino-5-hydroxymethylpyrimidine-monophosphate kinase (HMP-P kinase). The cDNA clone was isolated by a novel functional complementation strategy employing an Escherichia coli mutant deficient in the TMP-PPase activity. A biochemical assay showed the clone to confer recovery of TMP-PPase activity in the E. coli mutant strain. The cDNA clone is 1746 bp long and contains an open reading frame encoding a peptide of 524 amino acids. The C-terminal part of BTH1 showed 53% and 59% sequence similarity to the N-terminal TMP-PPase region of the bifunctional yeast proteins Saccharomyces THI6 and Schizosaccharomyces pombe THI4, respectively. The N-terminal part of BTH1 showed 58% sequence similarity to HMP-P kinase of Salmonella typhimurium. The cDNA clone functionally complemented the S. typhimurium and E. coli thiD mutants deficient in the HMP-P kinase activity. These results show that the clone encodes a bifunctional protein with TMP-PPase at the C-terminus and HMP-P kinase at the N-terminus. This is in contrast to the yeast bifunctional proteins that encode TMP-PPase at the N-terminus and 4-methyl-5-(2-hydroxyethyl)thiazole kinase at the C-terminus. Expression of the BTH1 gene is negatively regulated by thiamin, as in the cases for the thiamin biosynthetic genes of microorganisms. This is the first report of a plant thiamin biosynthetic gene on which a specific biochemical activity is assigned. The Brassica BTH1 gene may correspond to the Arabidopsis TH-1 gene.     

Sequence complexity of the S receptor kinase gene family in Brassica

A genomic library from an S ₂₉/S ₂₉ self-incompatible genotype of Brassica oleracea was screened with a probe carrying part of the catalytic domain of a Brassica S-receptor kinase (SRK)-like gene. Six positive phage clones with varying hybridisation intensities (K1 to K6) were purified and characterised. A 650–700 by region corresponding to the probe was excised from each clone and sequenced. DNA and predicted protein sequence comparisons based on a multiple alignment identified K5 as a pseudogene, whereas the others could encode functional proteins. K3 was found to have lost an intron from its genomic sequence. The six genes display different degrees of sequence similarity and form two distinct clusters in a dendrogram. The 98% similarity between K4 and K6, which extends across intron sequences, suggests that these might be very recently diverged alleles or daughters of a duplication. In addition, K2 showed a comparably high similarity to the probe. Clones K1, K3 and K5 cross-hybridised with an SLG ₂₉ cDNA probe, indicating the presence of upstream receptor domains homologous to the Brassica SLG gene. This suggests that the previously reported S sequence complexity may be ascribed to a large receptor kinase gene family.     

Bnm1, a Brassica pollen-specific gene

cDNA and genomic clones of a new pollen-specific gene, Bnm1, have been isolated from Brassica napus cv. Topas. The gene contains an open reading frame of 546 bp and a single intron of 362 bp. A comparison of the deduced amino acid sequence with sequences in data banks did not show similarity with known proteins. Northern blot analysis of developing pollen showed that Bnm1 mRNA was first detected in bicellular pollen and accumulated to higher levels in tricellular pollen. Bnm1 mRNA was not detected in leaves, stems, roots, pistils, seeds or pollen-derived embryos. RNA in situ hybridization of whole flower buds confirmed that Bnm1 was pollen-specific and expressed late in development. A promoter fragment of the Bnm1 gene fused to the gusA reporter gene yielded similar patterns of tissue specificity and developmental regulation in transgenic B. napus cv. Westar plants; however, the promoter was also active during the early stages of pollen development. The Bnm1 gene, cloned in this study, was derived from the A genome of the allotetraploid species B. napus (AACC). Southern blot analysis indicated that sequences similar to the Bnm1 gene were found in both A and C Brassica genomes. Related sequences were found in all 10 members of the Brassiceae tribe examined, but were not present in all tribes of the Brassicaceae family.     

A Brassica Self-Incompatibility Gene Is Expressed in the Stylar Transmitting Tissue of Transgenic Tobacco

Tobacco was transformed with a gene coding for an S-locus-specific glycoprotein of Brassica oleracea. The resulting transgenic plants showed tissue-specific and developmentally regulated expression of the introduced gene. Immunolocalization experiments showed that the Brassica gene was expressed in the stylar transmitting tissue of the transgenic plants. The pattern of expression of the introduced gene was more similar to that of the S-associated genes of Nicotiana alata than to expression in Brassica. Self-incompatibility was not conferred by the introduced gene.