水稻雄蕊成熟导管ATPase的超微结构定位

采用ATPase定位方法研究了水稻农垦58s-SD(可育花药）单核边位至三核期的花丝和药隔成熟导管,单核边位期花丝和药隔成熟导管内无ATPase活性;二核期花丝导管内出现大量的ATPase,导管周围的薄壁细胞中有1-2个优先解体,在导管无次生壁的部位,解体薄壁细胞靠近导管处的质膜ATPase不活跃;二核期药隔导管内也有大量的ATPase活性物,但导管周围细胞解体晚于花丝,三核期花丝和药隔导管内也观察到大量的具或不具ATPase活性的物质,以上结果暗示成熟导管内ATPase活性物（一部分）可能来源于花丝解体细胞。     

小麦花药药壁表皮细胞结构与功能研究

单核花粉粒时期,药壁表皮细胞内具丰富的核糖体,粗面内质网,高尔基体,内嵴发达的线粒体,线粒体嵴具显著的细胞色素氧化酶性,细胞和核仁上具显著的ATP酶性,细胞处于旺盛的生命活动状态,这种旺盛的活性一直维持到花粉粒成熟;二细胞花粉粒时期,药壁表皮细胞中积累大量的来自于药卫细胞的球型颗粒,在药隔薄壁细胞内民看到了同样怕颗粒,且药壁表皮细胞内球型颗粒的数量变化与花粉粒对营养物质的需求呈负相关,初步认为,药壁表皮细胞内的球型颗粒是来自于药隔组织营养物质供大于求剩余物质的积累,药壁表皮细胞在花粉粒 育后期可能具有对来自花药药隔维管组织的营养物质贮存的功能,。     

大麦小穗结构与开花特性研究──雄蕊在开闭花过程中的生长动态和结构变化

开花前,雄蕊花丝细胞中的淀粉等物质水解,细胞水势下降而吸胀,花丝伸长。随着＂小花轴＂中物质的输入,细胞进一步吸水膨大,花丝迅速伸长,花丝维管束中的导管被拉断,薄壁细胞内膜系统崩解,细胞自溶,降解物质＂撤回＂,＂小花轴＂被重新分配利用。开花后,花药表面大量失水,药壁开裂传粉。不育系雄蕊花药药隔小、发育不良,绒毡层发育和行为异常,其花药通常为空药室或花粉败育。用可育系花粉对不育系小花授粉,其小花能逐渐关闭。     

杜仲次生木质部分化和脱分化过程中酸性磷酸酶的超微细胞化学定位

杜仲（EucommiaulmoidesOliv．）次生木质部分化过程中,在形成层刚衍生的木薄壁细胞中,酸性磷酸酶（APase）主要分布于核膜边缘和高尔基体;在分化程度较高的木薄壁细胞中,APase散布于整个核中,进而,在各种细胞器残体上聚集;在成熟的木薄壁细胞中,APase沿细胞壁内侧分布。在未成熟导管分子中,核、质膜及纹孔上明显存在APase聚集,进而,核解体;在即将分化成熟的导管分子中,APase主要集中于初生壁;在已分化成熟的导管分子中,APase集中于次生壁。脱分化过程中,只在细胞质中可见分散的APase活性,而细胞核和细胞壁上未见此酶的分布;更深层的即将分化成熟和已分化成熟的导管分子,未见有细胞分裂,其上APase的分布与剥皮前相同。通过比较分化和脱分化过程中APase的分布,推测不同的APase同工酶可能分别参与了次生木质部细胞程序性死亡过程中原生质体的解体和次生壁的建成。APase的聚集程度可能是决定细胞能否脱分化的一个重要特征。     

金丝桃花药发育的细胞化学研究

花药发育过程中多糖和脂滴物质的代谢具有时空变化特征。不同植物的代谢特征有很大差异。该研究采用组织化学的方法对金丝桃花药发育中多糖和脂滴的动态分布进行观察。结果发现,多糖和脂滴的分布具有一定的规律。在造孢细胞时期,维管束周围的药隔薄壁细胞和花药壁的表皮、药室内壁和中层细胞中积累淀粉多糖,而绒毡层细胞中没有淀粉多糖。在小孢子早期,绒毡层细胞中出现淀粉多糖并且数量逐渐增加;此时,单核中位期小孢子中也出现淀粉多糖。到小孢子晚期,绒毡层细胞中积累的淀粉多糖消失,同时出现脂滴;晚期小孢子中也开始出现脂滴。到二胞花粉时期,绒毡层细胞原位解体,花粉中脂滴数量增加。金丝桃相当数量的花粉在小孢子时期发生异常。开花时,大多数花粉内为空腔,没有淀粉多糖和脂滴积累,花粉败育。发育正常的花粉内充满了淀粉多糖和脂滴。     

湖北光周期敏感核不育水稻花药能量和活性氧的代谢

湖北光周期敏感核不育水稻,在单核早期、单核晚期、二核及三核期的不育花药的细胞色素氧化酶(COD)、ATPase、过氧化物酶(POD)、过氧化氢酶(CAT)、SOD 在每小穗花药中的总活性普遍低于其可育花药,不育花药在发育的后期缺1—5条 COD、1条超氧物岐化酶(POD)和1—2条 Cu-Zn SOD 同工酶带。不育花药具较低的 ATP 含量和较高的 O(?)产生效率,且有 H_2O_2和丙二醛(MDA)的积累。对光敏雄性不育的发生与不育花药中异常的能量和活性氧代谢之内在联系进行了讨论。     

水稻胞质雄性不育系珍汕97A及其保持系珍汕97B绒毡层发育过程中的Ca2+分布变化

利用焦锑酸钾沉淀法研究了野败不育系珍汕97A及其保持系珍汕97B绒毡层细胞的发育过程及其细胞中Ca2 的分布变化。研究发现保持系绒毡层细胞在单核花粉晚期才开始迅速解体,而不育系绒毡层细胞在花粉母细胞时期就开始出现核膜、细胞膜解体,此过程持续到二核花粉时期。珍汕97A绒毡层细胞从花粉母细胞时期开始,细胞质内有少量颗粒状的Ca2 沉淀;减数分裂时期,绒毡层细胞的内切向壁表面有大量大颗粒的Ca2 沉淀;单核花粉时期绒毡层细胞周围集聚一层Ca2 沉淀。而保持系绒毡层细胞遮花粉母细胞时期和减数分裂时期细胞内没有Ca2 沉淀;单核花粉时期绒毡层细胞内的Ca2 沉淀主要分布在解体的细胞质内。推测绒毡层细胞结构发育的异常和Ca2 的异常分布可能与花粉的败育有关。     

水稻胞质雄性不育系珍汕97A及其保持系珍汕97B绒毡层发育过程中的Ca2 +分布变化

利用焦锑酸钾沉淀法研究了野败不育系珍汕97A及其保持系珍汕97B绒毡层细胞的发育过程及其细胞中Ca2 +的分布变化。研究发现保持系绒毡层细胞在单核花粉晚期才开始迅速解体,而不育系绒毡层细胞在花粉母细胞时期就开始出现核膜、细胞膜解体,此过程持续到二核花粉时期。珍汕97A绒毡层细胞从花粉母细胞时期开始,细胞质内有少量颗粒状的Ca2 +沉淀;减数分裂时期,绒毡层细胞的内切向壁表面有大量大颗粒的Ca2 +沉淀;单核花粉时期绒毡层细胞周围集聚一层Ca2 +沉淀。而保持系绒毡层细胞遮花粉母细胞时期和减数分裂时期细胞内没有Ca2 +沉淀;单核花粉时期绒毡层细胞内的Ca2 +沉淀主要分布在解体的细胞质内。推测绒毡层细胞结构发育的异常和Ca2 +的异常分布可能与花粉的败育有关。     

灵武长枣果实ATPase超微细胞化学定位和功能研究

采用ATPase超微细胞化学定位技术,研究灵武长枣果实不同发育阶段韧皮部和果肉库薄壁细胞ATPase分布特征,以明确灵武长枣果实ATPase超微细胞化学定位特征和功能。结果显示:(1)第一次快速生长期SE/CC复合体与周围的薄壁细胞有丰富的胞间连丝,形成共质体连续,韧皮部薄壁细胞之间有丰富的胞间连丝,ATPase反应物在韧皮部各细胞分布较少。(2)缓慢生长期ATPase反应物在韧皮部各细胞分布逐渐增加。(3)第二次快速生长期SE/CC复合体与周围的薄壁细胞缺乏胞间连丝,形成共质体隔离,韧皮薄壁细胞及果肉库薄壁细胞的胞间连丝较少,囊泡和膜泡在筛管、韧皮薄壁细胞和库薄壁细胞中很丰富,质膜、液泡膜、囊泡膜、细胞壁和胞间隙的ATPase活性较高。研究表明,果实在第一次快速生长期同化物从筛分子的卸出主要采取共质体途径,缓慢生长期同化物卸出时可能为共质体和质外体途径共存,第二次快速生长期则主要以质外体途径为主,证明果实不同发育阶段韧皮部同化物卸出路径存在差异。     

水稻马协不育与可育花药ATPase定位(简报)

马协不育系系朱英国等用农家品种“马尾粘”的不育株与“协青早选”测交和回交选育成功的。超微结构研究表明马协不育花药单核边位期绒毡层提前解体,液泡膜破裂;不育花粉外壁基粒棒少,且分布不均匀;线粒体有大的电子透明区,二核期不育花粉中央大液泡崩溃。不育花药绒毡层提前解体可能影响花粉外壁合成及花粉营养供应,大量研究表明绒毡层发育异常与花粉败育密切相关,而液泡膜的破坏会导致水解酶类的泄     

水稻马协不育与可育花药ATPase定位（简报）

Pb3 (po4)2-precipitation was used to study the ATPase activities both in fertile and sterile anthers of rice (Oryza sativa L. cv. Marxie). At big-vacuole pollen stage, tapetum of the fertile anthers showed high ATPase activity in their nuclei. In fertile pollen, ATPase was localized on the outside surface of the exine and in the nucleus both at big-vacuole and at bi-nucleate pollen stage. At late bi-nucleate pollen stage, a large amount of Pb3 (PO4)2 precipitated in endintine of the fertile pollen. In sterile anthers, tapetum was fully degenerated at big-vacuole pollen stage. In sterile pollen, ATPase was localized both on the plasmamembrane and in intine. These phenomena lasted to the bi-nucleate pollen stage. In addition, most of the sterile pollen did not show well-developed endintine. Based on the above results, we suggested that abortive tapetum could not provide enough nutrition for pollen development, and the high ATPase activity both on plasma membrane and in intine would likely result in ATP shortage in sterile anthers.     

洋葱花药发育过程中的细胞化学研究(简报)

高等植物花药结构复杂,其发育更是一个迅速、多变的过程,如小孢子母细胞减数分裂期间的细胞质改组、胼胝质壁的形成与降解、大液泡的形成与消失、花粉内外壁的形成、绒毡层细胞的降解、营养物质的积累与转化等。除了上述花药组成细胞的形态和结构发生明显变化外。花药发育的另一个显著特点是以花粉为中心的营养物质单向运输和转化,尤其是小孢子有丝分裂形成二胞花粉后开始积累大量的营养储存物以供成熟花粉萌发时利用。     

Observation of Androgenesis in Cultured Wheat Anthers at Meiosis,Tetrad, Early Uninucleate and Trinucleate Stage

The obtaining of calluses and plantlets from cultured wheat anthersat the stages from pollen mother cell to trinucleate microspore has been reported previously. Haploids as well as diploids existed among the regenerated plantlets derivedfrom anthers at these stages. Present paper reports the study on androgenesis patter-ns of cultured anthers at meiosis, tetrad, early mid- and late uninucleate and trinucleate stage. Cytological evidence of pollen-origin of calluses produced by anthers atthese stages was given. Observation showed that meiosis of wheat anthers was able tocomplete under culture conditions, resulting in releasing microspores, from which multinucleate and multicellular pollen grains formed. In meiosis anthers, abnormal cells,including syncytium and two kinds of binueleate calls were sometimes observed. Theymight be products of abnormal meiosis and abnormal development of tapetum cells. Itwas noted that failure and/or uncomplction of forming callus wall and/or pollen wallin in vitro anthers at meiosis, tetrad and early uninucleate stage occured often. Itmight lead to the low frequency of callus induction. Mature wheat anthers (trinucleate stage) contained both normal and abnormal pollen grains (pollen dimorphism); onlythe abnormal pollen grains developed into embryoids while all the normai trinucleatepollen grains degenerated rapidly. However, the date of the frequency of equal divisionof microspores suggested that abnormal pollen (N pollen, small pollen) could not be theonly source of androgenic pollens in cultured anthers at late uninucleate and other earlier stages.     

枸杞花药发育过程中脂滴和淀粉粒的分布特征

宁夏枸杞(Lycium barbarurn L．)花药发育过程中,淀粉粒和脂滴两种营养物质的积累和分布具有一定的特点：在造孢细胞时期,药隔薄壁细胞,表皮和药室内壁细胞中开始积累淀粉粒,而造孢细胞、绒毡层细胞和中层细胞中则没有淀粉粒。在四分体时期,绒毡层细胞开始积累脂滴并且数量逐渐增加。到小孢子晚期,绒毡层细胞降解,内含脂滴流入药室中。在小孢子发育过程中既没有淀粉粒也没有脂滴积累,直到二胞花粉的大液泡消失后花粉粒中才开始积累脂滴,然后又开始出现淀粉粒。枸杞成熟花粉中的营养储存物是脂滴和淀粉粒。     

Effect of Photoperiod on Calcium Distribution in Photoperiod-sensitive Cytoplasmic Male-sterile Wheat During Anther Development

Potassium antimontate was used to locate Ca2+ in fertile and sterile anthers of photoperiod-sensitive cytoplasmic male-sterile wheat (Triticum aestivum L.).The quantity and distribution of calcium precipitates change in microspore and pollen during microsporogenesis and pollen development.The calcium precipitates gradually accumulated on the surface of tetraspore or pollen until pollen mature. They were abundant on the surface of the trinucleate pollen,but not in the cytoplasm.Calcium was transported in anther wall and intervening connective tissue via symplast and apoplast system,meeting the need of microspore and pollen development.Abortive pollens were observed in the anthers developed under long daylight exposure. Abundant calcium precipitates were distributed along the edge of the degradatived pollen plasma and in the locular matrix,but little in the anther wall and intervening connective tissue of the early abortive pollen.Calcium precipitates accumulated on the surface of pollen was less than fertile pollen,but abundant calcium appear in the epiderms,endotheciums,middle layers of anther wall and cells of connective tissue.The results indicate that abnormalities in the distribution of calcium correlate with the failure of pollen development in photoperiod-sensitive cytoplasmic male-sterile wheat.     

Small RNAs in pollen

In plants, each pollen mother cell undergoes two rounds of cell divisions to form a mature pollen grain, which contains a vegetative cell(VC) and two sperm cells(SC). As a companion cell, the VC carries the SCs to an ovule by germinating a pollen tube. In-depth sequencing analyses of mature pollen showed that micro RNAs(mi RNAs) and short interfering RNAs(si RNAs) are present in both the VC and SCs. Additionally, epigenetically-regulated transposable elements(TEs) are reactivated in the VC and these TE m RNAs are further processed into 21-nt epigenetically reactivated si RNA(easiR NA) in SCs, which prevent 24-nt si RNA accumulation and sequester mi RNA loading. Small RNAs are thought to move from the VC to SCs, where they regulate gene expression and reinforce TE silencing. Here, we summarize current knowledge of the biogenesis and function of mi RNAs, si RNAs, and easi RNAs in pollen, emphasizing how these different small RNAs coordinately contribute to sperm cell formation and TE silencing.     

细胞质雄性不育水稻幼穗和花粉发育期的蛋白酶活性变化

水稻细胞质雄性不育系珍汕97A,在花粉母细胞形成期以后可溶性蛋白含量迅速降低。单核期仅为花粉母细胞形成期的56％,二核期和三核期分别为花粉母细胞形成期的36．4％和30．3％。保持系珍汕97B虽在花粉母细胞形成期后可溶性蛋白含量降低,但在二核期则有所增高,表现为鞍形变化过程。在花粉母细胞形成期后,珍汕97A的酪蛋白水解酶活性增高,单核期为前一时期的1倍,而珍汕97B的酶活性增幅较小。第一次枝梗分化期珍汕97A的内肽酶活性较珍汕97B高,而雌雄蕊形成期两者的酶活皆降低。整个发育期中珍汕97A的内肽酶活性较珍汕97B高15％至55．5％。珍汕97A在幼穗第一次枝梗分化期时氨肽酶活性较珍汕97B高。第二次枝梗分化期后,不育系和保持系的氨肽酶活性均下降。但花粉母细胞形成期后,珍汕97A的氨肽酶活性迅速增高,三核期达最高水平,这可能意味着此时大量蛋白质被水解。蛋白酶类抑制剂的实验表明,在雌雄蕊形成期后不育系和保持系含有半胱氨酸型氨肽酶和约10％含金属型氨肽酶;而在三核期,保持系的氨肽酶则主要为半胱氨酸型。不育系三核期含有的BAPA内肽酶包括半胱氨酸型、丝氨酸型,以及部分含金属酶类;而保持系三核期的内肽酶仅为丝氨酸型。不育系肽酶类型的变化,可能反映酶基因编码的去抑制。     

萍乡显性雄性核不育水稻超微结构研究

利用电镜技术对萍乡显性核不育水稻可育株和不育株花粉形成及发育过程和药壁组织的基本结构及其发育进行了研究。导致了其不育花粉败育的主要原因有：（1）绒毡层细胞表现为延迟解体,乌氏体不能与小孢子细胞壁的形成,特别是纯合不育株绒毡层细胞存在乌氏体的异位分布;（2）药隔维管束异常,导致营养物质运输缺乏,薄壁细胞液泡化,排列紊乱,杂合不育株薄壁细胞互相融合,出现核转移的独特现象。