水稻OsMS2基因在花药发育中的功能分析

拟南芥MS2（MALE STERILITY2）是一个调控花药花粉发育的关键基因。水稻OsMS2（Os03g07140）基因与拟南芥MS2的序列具有高度同源性。利用RNA干扰技术研究OsMS2基因在水稻花药发育过程中的功能。与野生型水稻相比,转基因植株营养生长阶段正常,但雄性育性降低。转基因植株雄性育性降低与RNA干扰引起的OsMS2基因表达水平降低有关。进一步对转基因植株花药进行细胞学观察,结果表明OsMS2基因表达水平的降低导致绒毡层细胞退化延迟,小孢子壁的形成出现异常。扫描电镜观察结果显示,小孢子壁光滑,不能形成正常的外壁。以上结果表明OsMS2基因在水稻花药发育过程中起重要作用。     

水稻DsMS2基因在花药发育中的功能分析

拟南芥MS2（MALE STERILITY2）是一个调控花药花粉发育的关键基因。水稻OsMS2（Os03g07140）基因与拟南芥MS2的序列具有高度同源性。利用RNA干扰技术研究OsMS2基因在水稻花药发育过程中的功能。与野生型水稻相比,转基因植株营养生长阶段正常,但雄性育性降低。转基因植株雄性育性降低与RNA干扰引起的OsMS2基因表达水平降低有关。进一步对转基因植株花药进行细胞学观察,结果表明OsMS2基因表达水平的降低导致绒毡层细胞退化延迟,小孢子壁的形成出现异常。扫描电镜观察结果显示,小孢子壁光滑,不能形成正常的外壁。以上结果表明OsMS2基因在水稻花药发育过程中起重要作用。     

拟南芥RUS4基因沉默对花药药室内壁次生加厚的影响

RUS4是拟南芥DUF647蛋白家族的一个功能未知的成员。沉默RUS4基因引起植株育性严重下降,但育性下降的具体机制尚不清楚。该研究通过观察RUS4基因沉默突变体(称为RUSamiRNA)不同时期花的发育情况,发现其雌蕊发育正常,雄蕊花丝伸长正常,主要缺陷是花药不能正常开裂;通过对RUS4-amiRNA植株花药发育的细胞形态学观察,发现其药室内壁缺乏次生加厚;qRT-PCR分析表明, RUS4-amiRNA花蕾中与植物次生壁加厚相关的转录因子基因NST1、NST2、MYB103和MYB85以及纤维素合成基因IRX1、IRX3、IRX5和IRX8的表达均大幅降低。该研究表明,RUS4可能通过影响次生壁形成相关基因的表达参与花药药室内壁次生壁的形成。     

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。     

TA29—Barnase嵌合基因导入对烟草花药绒毡层及花粉发育的影响

比较研究了烟草(Nicotiana tabacum L.)TA29-Barnase转基因不育植株和正常植株的花药绒毡层及花粉发育的全过程。研究表明,外源基因在花药中特异表达导致绒毡层细胞的提前降解,这种降解一般在减数分裂早期开始,至四分体时期完成,而正常花药绒毡层的降解发生在二细胞雄配子体初期,至花粉发育的后期方才完成。转基因植株花药绒毡层的降解在细胞结构上表现为:最初发生细胞的液泡化,然后细胞核凝聚,最后整个细胞溃解。转基因植株的花粉母细胞则在减数分裂过程中逐渐降解、退化,只有少数花粉母细胞能够顺利完成减数分裂发育成小孢子。观察结果还表明外源基因在花药中的表达是不均一的。对转基因不育和自然败育在细胞结构上的不同表现进行了讨论。     

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。     

植物细胞核雄性不育基因研究进展

植物雄性不育既是研究植物生殖生物学重要的植物学性状也是研究作物杂种优势利用重要的农艺性状,在遗传和分子生物学中具有重要地位。以模式植物拟南芥和水稻为主,对植物雄性不育的控制基因和相关分子机理已有众多进展,按照花药发育时期和雄性败育的表现形式可以归纳为减数分裂异常、胼胝质代谢异常、绒毡层发育异常、花粉壁发育异常、花药开裂异常,以及其它类型的雄性不育。在不育相关基因中,导致胼胝质代谢异常、绒毡层发育异常和花粉壁发育异常的基因往往表现一因多效,一个相关基因的突变会产生复合表型。关于植物雄性不育相关基因的研究表明,雄性器官和小孢子形成过程中的任何相关基因的改变,均可导致雄性不育的产生。本文总结了植物核基因雄性不育的研究进展,以期促进不同物种间雄性不育基因的比较分析,使植物雄性不育研究更加深入。     

羽叶薰衣草雄性不育的细胞学研究

用光镜和电镜观察羽叶薰衣草(Lavandula pinnata L.)雄性不育小孢子发育过程的细胞形态学特征.结果表明:羽叶薰衣草花药4枚,每枚花药通常具4个小孢子囊.花药壁发育为双子叶型,从外向内分为表皮、药室内壁、中层和绒毡层4层细胞.减数分裂形成的四分体为四面体及十字交叉型.小孢子的发育过程可分为造孢细胞期、减数分裂时期、小孢子发育早期、小孢子发育晚期.未观察到二胞花粉期和成熟花粉期.羽叶薰衣草花粉败育主要发生在单核花粉时期,细胞内物质解体并逐渐消失变成空壳花粉或花粉皱缩变形成为各种畸形的败育花粉.在此之前小孢子的发育正常.羽叶薰衣草小孢子不育机制体现在绒毡层过早解体、四分体时期以后各细胞中线粒体结构不正常、胼胝质壁与小孢子母细胞脱离、花药壁细胞中淀粉出现时间异常等. 壁发育为双子叶型,从外向内分为表皮、药室内壁、中层和绒毡层4层细胞.减数分裂形成的四分体为四面体及十字交叉型.小孢子的发育过程可分为造孢细胞期、减数分裂时期、小孢子发育早期、小孢子发育晚期.未观察到二胞花粉期和成熟花粉期.羽叶薰衣草花粉败育主要发生在单核花粉时期,细胞内物质解体并逐渐消失变成空壳花粉或花粉皱缩变形成为各种畸形的败育花粉.在此 前小孢子的发育正常.羽叶薰衣草小孢子不育机制体现在绒毡层过早解体、四分体时期以后各细胞中线粒体结构不正常、胼胝质壁与小孢子母细胞脱离、花药壁细胞中淀粉出现时间异常等. 壁发育为双子叶型,从外向内分为表皮、药室内壁、中层和绒毡层4层细胞.减数分裂形成的四分体为四     

小麦中雄性不育同源序列的分离、鉴定及表达分析

利用拟南芥中已克隆的雄性核不育基因MS2和水稻中假定雄性不育蛋白的保守区域,设计一对简并引物,并在太谷核不育小麦可育株及不育株花药中进行扩增,得到了一条134bp的片段。以该片段为基础,通过电子延伸得到一个长为1604bp的序列,该序列编码的氨基酸包含一段由200个氨基酸组成的雄性不育保守区。RT-PCR结果表明,该雄性不育同源序列只在小麦可育花药中表达,而在小麦败育花药、叶片和根中不表达,说明该雄性不育同源序列为花药发育特异基因。     

香港木兰小孢子发生及雄配子体发育的研究

采用常规胚胎学方法,对香港木兰（Magnolia championii Benth．）小孢子形成及雄配子体发育过程进行了研究。结果显示,香港木兰花药具4个小孢子囊,小孢子囊壁5—6层,其中腺质绒毡层1—2层;小孢子减数分裂时胞质分裂方式为修饰性同时型,四分体排列方式为四面体型或左右对称型,偶为交叉型,成熟花粉粒为二细胞型。在次生造孢细胞、小孢子母细胞、四分体时期都会出现败育,且在很多成熟花药中全部是败育的单核花粉。PAS染色后发现,相对正常发育的小孢子囊,在这种小孢子囊壁中仍有大量淀粉粒残留,可能是药隔中的营养物质不能及时从药隔组织转移到小孢子囊壁以供给小孢子发育所需的营养,使整个药室内的小孢子发育都停滞在单核期。通过不同生境植株花粉萌发率的对比,推断空气湿度是影响香港木兰小孢子正常发育的一个重要因素。     

水稻P0491E01基因调控花药发育的功能分析(简报)

高等植物的花药发育是包含基因不同程度相互作用的复杂发育过程,一般可分为两个阶段。第一个是花药的形态建成阶段,在这一阶段中细胞与组织发生分化,小孢子母细胞进行减数分裂形成四分     

<i>OsMAPK6</i> Affects Male Fertility by Reducing Microspore Number and Delaying Tapetum Degradation in <i>Oryza sativa</i> L.

The mitogen-activated protein kinase (MAPK) cascade is important in stress signal transduction and plant development. In the present study, we identified a rice (Oryza sativa L.) mutant with reduced fertility, Oryza sativa mitogen-activated protein kinase 6 (osmapk6), which harbored a mutated MAPK gene. Scanning and transmission electron microscopy, quantitative RT-PCR analysis, TUNEL assays, RNA in situ hybridization, longitudinal and transverse histological sectioning, and map-based cloning were performed to characterize the osmapk6 mutant. The gene OsMAPK6 was expressed throughout the plant but predominantly in the microspore mother cells, tapetal cells, and microspores in the anther sac. Compared with the wild type, the total number of microspores was reduced in the osmapk6 mutant. The formation of microspore mother cells was reduced in the osmapk6 anther sac at an early stage of anther development, which was the primary reason for the decrease in the total number of microspores. Programmed cell death of some tapetal cells was delayed in osmapk6 anthers and affected exine formation in neighboring microspores. These results suggest that OsMAPK6 plays pivotal roles in microspore mother cell formation and tapetal cell degradation.     

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44 kb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。     

Defective pollen wall is required for anther and microspore development in rice and encodes a fatty acyl carrier protein reductase

Aliphatic alcohols naturally exist in many organisms as important cellular components; however, their roles in extracellular polymer biosynthesis are poorly defined. We report here the isolation and characterization of a rice (Oryza sativa) male-sterile mutant, defective pollen wall (dpw), which displays defective anther development and degenerated pollen grains with an irregular exine. Chemical analysis revealed that dpw anthers had a dramatic reduction in cutin monomers and an altered composition of cuticular wax, as well as soluble fatty acids and alcohols. Using map-based cloning, we identified the DPW gene, which is expressed in both tapetal cells and microspores during anther development. Biochemical analysis of the recombinant DPW enzyme shows that it is a novel fatty acid reductase that produces 1-hexadecanol and exhibits >270-fold higher specificity for palmiltoyl-acyl carrier protein than for C16:0 CoA substrates. DPW was predominantly targeted to plastids mediated by its N-terminal transit peptide. Moreover, we demonstrate that the monocot DPW from rice complements the dicot Arabidopsis thaliana male sterile2 (ms2) mutant and is the probable ortholog of MS2. These data suggest that DPWs participate in a conserved step in primary fatty alcohol synthesis for anther cuticle and pollen sporopollenin biosynthesis in monocots and dicots.     

Conserved metabolic steps for sporopollenin precursor formation in tobacco and rice

The development of pollen wall with proper sporopollenin deposition is essential for pollen viability and male fertility in flowering plants. Sporopollenin is a complex biopolymer synthesized from fatty acid and phenolic derivatives. Recent investigations in Arabidopsis have identified a number of anther‐specific genes involved in the production of fatty‐acyl monomers potentially required for exine formation. The existence of ancient biochemical pathways for sporopollenin biosynthesis has been widely proposed but experimental evidence from plant species other than Arabidopsis is not extensively available. Here, we investigated the metabolic steps catalyzed by the anther‐specific acyl‐CoA synthetase (ACOS), polyketide synthase (PKS) and tetraketide α‐pyrone reductase (TKPR). Using fatty acids as starting substrates, sequential activities of heterologously expressed tobacco enzymes NtACOS1, NtPKS1 and NtTKPR1 resulted in the production of reduced tetraketide α‐pyrones. Transgenic RNA interference lines were then generated for the different tobacco genes which were demonstrated to be indispensable for normal pollen development and male fertility. Similarly, recombinant rice OsPKS1 and OsTKPR1 were shown to function as downstream enzymes of NtACOS1. In addition, insertion mutant lines for these rice genes displayed different levels of impaired pollen and seed formation. Taken together, reduced tetraketide α‐pyrones appear to represent common sporopollenin fatty‐acyl precursors essential for male fertility in taxonomically distinct plant species.     

PERSISTENT TAPETAL CELL1 encodes a PHD-finger protein that is required for tapetal cell death and pollen development in rice

In higher plants, timely degradation of tapetal cells, the innermost sporophytic cells of the anther wall layer, is a prerequisite for the development of viable pollen grains. However, relatively little is known about the mechanism underlying programmed tapetal cell development and degradation. Here, we report a key regulator in monocot rice (Oryza sativa), PERSISTANT TAPETAL CELL1 (PTC1), which controls programmed tapetal development and functional pollen formation. The evolutionary significance of PTC1 was revealed by partial genetic complementation of the homologous mutation MALE STERILITY1 (MS1) in the dicot Arabidopsis (Arabidopsis thaliana). PTC1 encodes a PHD-finger (for plant homeodomain) protein, which is expressed specifically in tapetal cells and microspores during anther development in stages 8 and 9, when the wild-type tapetal cells initiate a typical apoptosis-like cell death. Even though ptc1 mutants show phenotypic similarity to ms1 in a lack of tapetal DNA fragmentation, delayed tapetal degeneration, as well as abnormal pollen wall formation and aborted microspore development, the ptc1 mutant displays a previously unreported phenotype of uncontrolled tapetal proliferation and subsequent commencement of necrosis-like tapetal death. Microarray analysis indicated that 2,417 tapetum- and microspore-expressed genes, which are principally associated with tapetal development, degeneration, and pollen wall formation, had changed expression in ptc1 anthers. Moreover, the regulatory role of PTC1 in anther development was revealed by comparison with MS1 and other rice anther developmental regulators. These findings suggest a diversified and conserved switch of PTC1/MS1 in regulating programmed male reproductive development in both dicots and monocots, which provides new insights in plant anther development.     

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。