青花菜雄性不育相关基因BoDHAR的克隆与表达分析

以一个与甘蓝显性核不育相关的差异表达片段的序列为信息探针,通过在NCBI与TAIR网站数据库中进行同源EST序列搜索,经人工拼接、RT-PCR、PCR克隆与序列分析,获得了青花菜脱氢抗坏血酸还原酶DHARdehydroascorbatereductase基因的cDNA与DNA全长序列,命名为BoDHAR。并利用双链接头介导PCR的染色体步行技术(genomewalking)克隆了其上游644bp的5′端序列。所获的BoDHAR基因全长1486bp,存在两个内含子,DNA编码区序列633bp,编码210个氨基酸;序列分析表明BoDHAR与同源基因AT1G19570.1cDNA序列有82.3%的一致性,推导的氨基酸序列有79.6%的一致性;编码的水溶性蛋白存在多个磷酸化位点;5′端上游区存在明显的转录调控序列。半定量RT-PCR结果表明BoDHAR在可育系花蕾中的表达量明显高于不育系花蕾,在花药中的表达明显高于其它部位。     

棉花细胞核雄性不育两用系差异表达基因分析

应用cDNA-AFLP对棉花ms5ms6双隐性核雄性不育两用系的不育株和可育株花粉发育的3个时期—造孢细胞时期、花粉母细胞时期和花粉粒时期进行对比分析,共得到17个差异表达片段,它们分别属于11种表达模式,其中14个片段可以在NCBI数据库中找到同源序列,功能分析表明这些片段所编码的基因可能参与了信号转导、转录、能量代谢、细胞壁发育等相关过程。Northern杂交结果证明检测片段的表达模式与cDNA-AFLP结果吻合。同时还在可育花药中发现了与玉米T型细胞质雄性不育恢复因子RF2基因高度同源的育性恢复因子类基因。     

Cloning and Characterization of the Microspore Development-Related Gene BcMF2 in Chinese Cabbage Pak-Choi (Brassica campestris L. ssp. chinensis Makino)

For the sake of providing some important information relevant to the study of the molecular mechanism of genic male sterility in plants, gene differential expression in flower buds at different developmental stages, as well as in rosette leaves, florescence leaves, and scapes was analyzed using cDNA amplified fragment length polymorphism (cDNA-AFLP) in the genic male sterile A and fertile B line of Chinese cabbage pak-choi. Following amplification of 125 pairs of primer combinations, 11 differential fragments were obtained, of which eight were from the B line and the other three were from the A line. Of 11 differential fragments, four were verified by Northern hybridization that were expressed preferentially in fertile flower buds. Results of GenBank BLAST showed that one fragment was with unknown function,whereas the other fragments have strong nucleotide sequence similarities with the polygalacturonase (PG)gene, the pectinesterase (PE) gene, and the polygalacturonase inhibitory protein (PGIP4) gene. Only fulllength cDNA from the differential fragment BcMF-A18T16-1 was amplified by rapid amplification of cDNA ends (RACE) and Northern analysis showed that this fragment was expressed only in medium and largesized flower buds of the B line. The full-length cDNA, designated as BcMF2 (Brassica campestris Male Fertile 2), was 1 485 bp long and was composed of a 1 263-bp open reading frame, which had 83% nucleotide similarity to a PG gene from Arabidopsis encoding polygalacturonase. Analysis of the basic structure of the protein revealed that it had one polygalacturonase active site (RVTCGPGHGLSVGS) at 256th site of amino acids and was classified as being a member of family 28 of the glycosyl hydrolases. The role of the BcMF2 gene on microspore development is discussed in the present paper.     

Cloning and Characterization of the Microspore Development-Related Gene BcMF2 in Chinese Cabbage Pak-Choi （Brassica campestris L. ssp. chinensis Makino）

For the sake of providing some important information relevant to the study of the molecular mechanism of genic male sterility in plants, gene differential expression in flower buds at different developmental stages, as well as in rosette leaves, florescence leaves, and scapes was analyzed using cDNA amplified fragment length polymorphism (cDNA-AFLP) in the genic male sterile A and fertile B line of Chinese cabbage pak-choi. Following amplification of 125 pairs of primer combinations, 11 differential fragments were obtained, of which eight were from the B line and the other three were from the A line. Of 11 differential fragments, four were verified by Northern hybridization that were expressed preferentially in fertile flower buds. Results of GenBank BLAST showed that one fragment was with unknown function, whereas the other fragments have strong nucleotide sequence similarities with the polygalacturonase (PG) gene, the pectinesterase (PE) gene, and the polygalacturonase inhibitory protein (PGIP4) gene. Only fulllength cDNA from the differential fragment BcMF-A 18T 16-1 was amplified by rapid amplification of cDNA ends (RACE) and Northern analysis showed that this fragment was expressed only in medium and largesized flower buds of the B line. The full-length cDNA, designated as BcMF2 (Brassica campestris Male Fertile 2), was 1 485 bp long and was composed ofa 1 263-bp open reading frame, which had 83% nucleotide similarity to a PG gene from Arabidopsis encoding polygalacturonase. Analysis of the basic structure of the protein revealed that it had one polygalacturonase active site (RVTCGPGHGLSVGS) at 256th site of amino acids and was classified as being a member of family 28 of the glycosyl hydrolases. The role of the BcMF2gene on microspore development is discussed in the present paper.     

利用cDNA-AFLP技术分析旱作促进水稻种子根伸长过程中的基因表达

短期旱作促进水稻种子根的伸长。利用cDNA—AFLP技术分析种子根根尖在旱作条件下差异表达的基因,同时比较这些基因在种子根尖、侧根和不定根原基区的表达差异。在1640个片段中,70个在种子根根尖中受旱作诱导,其中24个被克隆并测序。2个基因分别编码丙酮酸脱氢酶激酶(PDK)和腺嘌吟转磷酸核糖基酶(APRT),并用电子拼接技术获得水稻的APRT全长cDNA;另一个经cDNA末端快速扩增法延长后仍无同源序列。Northern杂交验证了这3个基因的cDNA—AFLP表达谱。这是首次报告使用cDNA—AFLP技术研究水稻根组织的差异表达基因。     

Meiotic abnormality in dominant genic male sterile Brassica napus

Rs1046AB is a dominant genic male sterile (DGMS) Brassica napus line derived from Yi-3A. Until now the molecular mechanism of its male sterility is still unknown. In this paper, cytological observations demonstrated that all cells in sterile plants contained condensed nuclei at the beginning stage of meiosis; this implied that meiotic cells were degenerating. Although 31% (93/300) cells escaped from the state of nuclei condensation in buds about 3 mm in length (in such length, normal plants are at tetrade stage), no cells could pass the pachytene stage. Then pachytene or zygotene like chromatin/chromosomes sometimes congregated into two or more groups with different size, which resulted in the formation of micronuclei. Nucleoplasmic bridge could also be found in some meiotic cells. Even when the "microspore's analogue" appeared in sterile buds about 4 mm in length (in such length, mature pollens could be detected in normal buds), the nuclei condensation and escaped cells with pachytene like chromosome still could be found in the sterile anthers. So it could be concluded that male sterility was caused by meiotic abnormality. According to our previous research, four genes related to cell cycle/DNA processing were identified in fertile plants. RT-PCR further confirmed that three DNA repair genes were partially or completely repressed in the sterile plants, and were only expressed in the early stage fertile flower buds, i.e. the buds <3 mm in length. Therefore, DGMS of rapeseed was probably caused by the abnormality in DNA damage repair system during meiosis. According to these results, some possible mechanisms of fertility control were discussed.     

Meiotic abnormality in dominant genic male sterile <Emphasis Type="Italic">Brassica napus</Emphasis>

Rs1046AB is a dominant genic male sterile (DGMS) Brassica napus line derived from Yi-3A. Until now the molecular mechanism of its male sterility is still unknown. In this paper, cytological observations demonstrated that all cells in sterile plants contained condensed nuclei at the beginning stage of meiosis; this implied that meiotic cells were degenerating. Although 31% (93/300) cells escaped from the state of nuclei condensation in buds about 3 mm in length (in such length, normal plants are at tetrade stage), no cells could pass the pachytene stage. Then pachytene-or zygotene-like chromatin/chromosomes sometimes congregated into two or more groups with different size, which resulted in the formation of micronuclei. A nucleoplasmic bridge could also be found in some meiotic cells. Even when the “microspore’s analogue” appeared in sterile buds about 4 mm in length (in such length, mature pollens could be detected in normal buds), the nuclei condensation and escaped cells with a pachytene-like chromosome still could be found in the sterile anthers. So it could be concluded that male sterility was caused by meiotic abnormality. According to our previous research, four genes related to cell cycle/DNA processing were identified in fertile plants. RT-PCR further confirmed that three DNA repair genes were partially or completely repressed in the sterile plants and were only expressed in the early stage fertile flower buds, i.e., the buds <3 mm in length. Therefore, DGMS of rapeseed was probably caused by the abnormality in the DNA damage repair system during meiosis. According to these results, some possible mechanisms of fertility control were discussed.