拟南芥雄性不育相关基因LDAD1&2的遗传定位(英文)

利用EMS诱变筛选手段分离到一株拟南芥类似花药不开裂雄性不育突变体(like-defective in anther de-hiscence,ldad),其果荚干瘪,花药不能开裂且花粉败育。遗传分析表明,突变体的表型受2个隐性基因控制;细胞学观察发现,在花药发育过程中伴随着小孢子的降解;通过图位克隆初步对ldad的2个突变位点分别定位,一个定位在1号染色体上SSLP标记F22L4与端粒之间171 kb的区间,另一个定位在5号染色体上SSLP标记T10O8与端粒间150 kb的区间内;生物信息学分析显示此区间内未见育性相关的已知基因。该研究的结果对进一步克隆LDAD1&2基因及探讨其在花药发育中的功能具有重要意义。     

调控拟南芥花粉发育突变体zy1511的基因定位及特征分析

为了进一步研究花药花粉发育过程,我们通过EMS诱变,筛选到拟南芥雄性不育突变体zy1511。遗传分析表明,zy1511为隐性单位点突变。细胞学观察表明．突变体花药中小孢子从四分体释放出后绒毡层并没有开始退化,花药发育后期绒毡层依然部分存在。说明突变体花药绒毡层退化比野生型的要迟,因此,小孢子不能发育成正常花粉粒。利用图位克隆的方法将zv1511定位于第一条染色体上分子标记F25P12和T8L23之间134．kb的区间内。本项工作为zy1511基因的克隆及对花粉发育功能分析奠定了基础。目前尚未见到该区间内雄性不育基因的报道。因此,zy1511是控制花粉发育的尚未发现的关键基因。     

MS1521是拟南芥花药发育的必需基因

通过对3个拟南芥（Arabidopsis thaliana）雄性不育突变体（ms1521,st350,st454）的分析,研究了MS1521基因在花药发育过程中的功能。ms1521是通过EMS诱变野生型拟南芥得到的一株突变体,遗传分析表明ms1521是隐性单核基因控制的。利用图位克隆的方法对不育基因MS1521进行了定位,结果将MS1521定位于拟南芥第一条染色体上26kb的区间内,该定位区间内有一个影响花器官形态建成的基因UFO。测序结果表明在ms1521突变体中UFO基因编码区的958bp处发生了单碱基突变,导致MS1521该位点的氨基酸由天冬酰胺变成了天冬氨酸。另外两个表型与ms1521相似的突变体st350和st454来自T-DNA插入突变体群体。测序结果表明突变体st350和st454分别在UFO基因编码区发生了提前终止突变。等位分析表明它们与MS1521基因是等位的。3个突变体营养生长期发育正常,但生殖生长发育出现异常：有的雄蕊只有花丝没有花药;或者有花药但花丝变短;或者雄蕊有正常的花丝和花药,花药中有可育的花粉,但药室不能开裂;最终导致突变体不育的表型。进一步细胞学观察发现药室不能开裂是由于药室内壁细胞纤维化和木质化增厚不明显造成的。以上这些结果表明MS1521基因在花药发育过程中起重要作用。     

拟南芥雄性不育突变体fne的遗传与定位分析

在T-DNA插入突变体Salk_118481株系的群体中,筛选到一株雄性不育突变体,用T-DNA序列上的一对引物进行PCR鉴定表明其基因组中没有T DNA插入。通过背景纯化与遗传分析发现该雄性不育突变体是由单个隐性基因控制的,引起不育的主要原因是在花药发育的第13~14期,花丝不能伸长以完成授粉,故该突变体命名为fne （filament no elongation）。利用图位克隆的方法对FNE基因进行了定位,结果表明FNE基因位于第五条染色体上分子标记MBD2和MMG4之间的97kb区间内。目前该区间内尚未见到控制花丝伸长基因的报道,因此,FNE基因是一个控制花丝伸长的新基因。     

拟南芥白化突变体心口的基因定位与分析

EMS30是拟南芥经甲基磺酸乙酯（EMS）诱变得到的白化突变体。该突变体的叶绿体结构存在严重缺陷,同时伴随叶绿素缺失。遗传分析显示EMS30突变体的突变表型受隐性单基因控制。采用图位克隆的方法对EMS30突变基因进行定位的结果显示,该基因位于拟南芥第一条染色体的分子标记F21M12和F14N23之间的96kb区间内,该区间包含25个基因。通过生物信息学分析发现,该区间内有3个基因定位在叶绿体或与叶绿体发育相关。这些结果有助于该基因的克隆,为阐释叶绿体发育提供线索。     

拟南芥雄性不育突变体ms1502的遗传及定位分析

通过EMS诱变、背景纯化与遗传分析,从拟南芥（Arabidopsis thaliana）中筛选到了一棵隐性单基因控制的雄性不育突变体ms1502。细胞学观察发现,突变体在小孢子从四分体释放出后花药绒毡层过早衰亡,小孢子的内容物不正常地凝聚,最终无法形成正常的花粉粒。利用图位克隆的方法对该基因MSl502进行了定位,结果表明MS1502位于第4条染色体上分子标记F25124和T12H20之间105kb区间内。目前该区间内尚未见到花药发育必需基因（不育基因）的报道,因此MS1502是一个控制花粉发育的新基因。     

拟南芥雄性不育突变体ms1142的遗传定位与功能分析

经EMS诱变野生型拟南芥（Arabidopsis thaliana）群体筛选得到一株雄性不育突变体ms1142,突变体的果荚短小,不含种子。细胞学观察和扫描电镜结果表明,突变体花药发育过程中,花药中小孢子外壁异常、破裂,最后没有花粉形成。遗传分析表明,该突变体为隐性单核基因突变所致;利用图位克隆的方法将MS1142基因定位于第1条染色体的BAC克隆F16P17上44kb区间内,目前尚未见该区间内有雄性不育基因的报道。以上结果结合生物信息学分析表明,MS1142是一个新的调控花药发育的关键基因。该工作为花药发育关键基因MS1142的克隆及功能分析奠定了基础。     

拟南芥基因的图位克隆技术

综述了拟南芥作为模式植物的优势,图位克隆技术的三大飞跃及其原理,简要地分析了图位克隆技术应用于拟南芥时所注意的问题及二者结合的应用前景。     

拟南芥表皮毛发育突变体abt3-1的基因定位及表型分析

在发掘和鉴定调控植物表皮毛发育的新因子过程中,获得了一个表皮毛发育异常的拟南芥隐性突变体abt3-1(aberrantly branched trichome 3-1)。与野生型拟南芥(Col-0)相比,其表皮毛分支数目明显增加。另外,abt3-1还表现出植株小、叶形宽、叶色发灰、主根短等发育缺陷。利用图位克隆技术将该突变基因ABT3定位在1号染色体上,分子标记在F28G11#3与F4N21#1之间,物理距离为134kb。该研究将为进一步克隆ABT3基因及研究其在调控植物生长发育过程中的作用奠定基础。     

拟南芥网状突变体E-210基因精细定位

通过甲基磺酸乙酯(EMS)诱变与遗传分析,从拟南芥(Arabidopsis thaliana)中筛选到一株隐性单基因控制的网状突变体E-210.该突变体植株生长缓慢,叶脉呈绿色,叶肉呈黄色.通过透射电镜观察,发现野生型植株和突变植株在叶绿体结构上差异不大,猜测该突变体E-210基因与叶绿体的发育可能没有直接关系,而很可能同叶绿素或叶绿体的生物合成有关.通过图位克隆的方法,将该突变体的突变基因定位在第5条染色体上的MRBl7和MBG8-5的分子标记之间,精确到87.130 kb.对MRB17和MBG8-5的分子标记之间的22个基因进行了分析,预测突变体E-210基因可能是At5g54770,编码THI1,即噻唑合成酶.     

拟南芥AST基因的精细作图

拟南芥(Arabidopsis thaliana(L.)Heynh.)ast(anthocyanin spottedtesta)突变体是由碳离子辐射诱导产生的与花青苷生物合成有关的基因突变体,受单隐性核基因控制.根据拟南芥数据库中的SNPs(single nucleotide polv-mophisms)序列和插入/缺失多态性(insertion/deletion polymorphisms)序列,设计了一系列分子标记.采用图位克隆策略,应用这些分子标记完成了对拟南芥AST基因的精细作图,成功地将AST基因定位到BAC克隆T13M11上,初步认为该BAC克隆中的基因T13M11.8可能是AST基因.该基因的DNA序列长1432bp,含有6个外显子和5个内含子,编码的蛋白与花青苷生物合成途径中的二氢黄酮醇-4-还原酶有较高的同源性.将进一步通过功能互补实验验证图位克隆的结果.     

拟南芥AST基因的精细作图

拟南芥（Arabidopsis thaliana(L.)Heynh)ast(anthocyanin spotted testa)突变体是由碳离子辐射诱导产生的与花青苷生物合成有关的基因突变体。受单隐性核基因控制。根据拟南芥数据库中的SNPs(single nucleotide poly-mophisms)序列和插入/缺失多态性（insertion/deletion polymorphisms)序列,设计了一系列分子标记,采用图位克隆策略。应用这些分子标记完成了对拟南芥AST基因的精细作图,成功地将AST基因定位到BAC克隆T13M11上,初步认为该BAC克隆中的基因T13M11.8可能是AST基因。该基因的DNA序列长1432bp。含有6个外显子和5个内含子,编码的蛋白与花青苷生物合成途径中的二氢黄酮醇-4-还原酶有较高的同源性。将进一步通过功能互补实验验证图位克隆的结果。     

Identification of a Gene Involved in the Control of the Root System Development in Arabidopsis thaliana

Genetic and molecular genetic analysis of a lethal root mutant of Arabidopsis thaliana was carried out. The mutant was obtained from a collection created earlier by means of insertion mutagenesis. The mutation was found to be recessive. It was caused by an insertion of the T region of vector pLD3 used for transformation of germinating seeds when creating the collection of insertion mutants. A 118-bp DNA fragment flanking the left border of the insertion was isolated using the TAIL PCR technique, and its nucleotide sequence was determined. Computer analysis of this DNA region demonstrated that it was located in exon 32 of the YUP8H12R.44 gene in chromosome 1.     

Characterization of a Small Auxin-Up RNA (SAUR)-Like Gene Involved in Arabidopsis thaliana Development

The root of Arabidopsis thaliana is used as a model system to unravel the molecular nature of cell elongation and its arrest. From a micro-array performed on roots that were treated with aminocyclopropane-1-carboxylic acid (ACC), the precursor of ethylene, a Small auxin-up RNA (SAUR)-like gene was found to be up regulated. As it appeared as the 76th gene in the family, it was named SAUR76. Root and leaf growth of overexpression lines ectopically expressing SAUR76 indicated the possible involvement of the gene in the division process. Using promoter::GUS and GFP lines strong expression was seen in endodermal and pericycle cells at the end of the elongation zone and during several stages of lateral root primordia development. ACC and IAA/NAA were able to induce a strong up regulation of the gene and changed the expression towards cortical and even epidermal cells at the beginning of the elongation zone. Confirmation of this up regulation of expression was delivered using qPCR, which also indicated that the expression quickly returned to normal levels when the inducing IAA-stimulus was removed, a behaviour also seen in other SAUR genes. Furthermore, confocal analysis of protein-GFP fusions localized the protein in the nucleus, cytoplasm and plasma membrane. SAUR76 expression was quantified in several mutants in ethylene and auxin-related pathways, which led to the conclusion that the expression of SAUR76 is mainly regulated by the increase in auxin that results from the addition of ACC, rather than by ACC itself.     

ST273是拟南芥绒毡层和小孢子发育的必需基因

绒毡层在拟南芥花药花粉发育过程中具有重要作用,包括分泌降解胼胝质的胼胝质酶、为花粉壁的形成提供原料以及为小孢子发育提供营养物质.本文通过对拟南芥雄性不育突变体st273的分析,研究了ST273基因在花药花粉发育过程中的功能.st273是通过T-DNA插入诱变野生型拟南芥得到的一株突变体,遗传分析表明st273是单隐性核基因控制的.利用图位克隆的方法对不育基因ST273进行了定位,结果表明ST273基因与拟南芥第三条染色体上分子标记CIW11连锁.生物信息学分析发现该分子标记附近有一个调控花粉发育的基因TDF1.测序分析结果表明在st273突变体中,TDF1基因第三个外显子上459位的碱基发生了由G459变成了A459的单碱基变化,导致ST273基因该位点提前终止突变.等位分析结果表明st273与tdf1是等位突变体.st273突变体营养生长期发育正常,但生殖生长发育出现异常.亚历山大染色结果显示st273突变体花药中没有花粉.组织切片观察结果表明,突变体花药绒毡层异常肥大且空泡化,四分体不能正常释放小孢子,最终无法形成花粉.这些结果揭示了ST273蛋白质参与调控了绒毡层和小孢子发育过程.     

ST273 Is Essential for Tapetum and Microspore Development in Arabidopsis thaliana*

In Arabidopsis, the tapetum plays important roles in anther and pollen development by providing enzymes for callose dissolution, materials for pollen wall formation, and nutrients for microspore development. This paper describes the functional analyses of the ST273 gene in anther and pollen development by using Arabidopsis male sterile mutant st273. Mutant st273 was identified from a T DNA insertion mutant population, and genetic analysis showed that st273 mutant was controlled by a single recessive nuclear gene. A map based cloning approach was used, and ST273 gene was mapped to be linked to a molecular marker CIW11 on chromosome 3. Bioinformatics analysis revealed that there is a TDF1 gene near the marker CIW11. Sequencing analysis indicated that st273 mutant had a G459 to A459 base pair change in the third exon of TDF1 gene, which resulted in premature termination mutation in this region. Allelism test indicated that ST273 and TDF1 belong to the same locus. The mutant plant grows normally during the vegetative growth stage, but show developmental defects at the reproductive growth stage. Alexander staining showed that there was no pollen in the mature anther locule. Cytology observation indicated that the mutant tapetum was enlarged and vacuolated, the tetrads could not release the microspores timely, and finally no pollen was formed in the anther. These results demonstrated that ST273 protein plays an important role in tapetum and microspore development.     

MS1516是拟南芥四分体形成和小孢子发育的必需基因

以前报道了雄性育性下降突变体ms1516,而且图位克隆的方法已将突变基因MS1516定位到拟南芥基因组第3条染色体上28kh的区间内。本文通过进一步的生物信息学分析,发现该定位区间内有一个与减数分裂有关的基因AtATM,而且等位实验结果表明rns1516和nfm0是等位突变体。细胞学分析结果表明,ms1516突变体在花药发育过程中产生多个不均等的小孢子,而且大多数的小孢子不能发育成成熟的花粉。DAPI染色的结果显示小孢子母细胞减数分裂过程中,染色体不能正常分离,对成熟花粉的扫描电镜观察结果发现突变体多数花粉形态异常。以上结果说明MS1516基因在小孢子形成和发育过程中具有重要作用。     

The RHG Gene Is Involved in Root and Hypocotyl Gravitropism in Arabidopsis thaliana

In higher plants, shoots show negative gravitropism and rootsshow positive gravitropism. To elucidate the molecular mechanismsof root and hypocotyl gravitropism, we segregated the secondmutation from the original phyB-1 mutant line which impairedboth root and hypocotyl gravitropism and characterized thisnovel mutation named rhg (for root and hyzypocotyl gravitropism).The rhg is a single recessive nuclear mutation and it is mappedon the lower part of the chromosome 1. Analyses on the gravitropicresponses of the rhg mutant indicate that root and hypocotylgravitropism are severely impaired but inflorescence stem gravitropismis not affected by the rhg mutation. In the rhg mutant seedlings,amyloplasts (statoliths for gravity-perception) were presentin the presumptive statocytes of roots and hypocotyls. Phototropismby roots and hypocotyls was not impaired in the rhg mutant.These results suggest that the RHG gene product probably actson the gravity-perception and/or the gravity-signal transductionin root and hypocotyl gravitropism. This is the first reportabout the genetic locus specifically involved in both root andhypocotyl gravitropism but not inflorescence stem gravitropism,supporting our hypothesis that the mechanisms of gravitropismare genetically different between hypocotyls and inflorescencestems. (Received March 11, 1997; Accepted April 17, 1997)