木姜子油细胞发育的超微结构研究

利用超薄切片法和透射电镜研究了木姜子（Litsea pungens Hemsl.）油细胞的发育过程。油细胞3层细胞壁的发育可分为4个阶段,阶段1：油细胞仅有初生纤维素壁层,又可分为原始细胞和细胞 泡化两个时期。此阶段质体具透明小泡和黑色嗜锇物质,并与液泡融合。阶段2：木栓质化壁层的形成,片层状木栓质不断叠加在初生纤维素壁内侧,其细胞结构与前期相似,阶段3：内纤维素壁层的形成,较厚而松散的内纤维素壁层叠加在木栓质化壁层的内侧,在内纤维素壁层中可见黑色嗜锇物质,胞间连丝成为被阻塞的特化结构,此时大液泡被嗜锇油脂充满,成为油囊。阶段4：油细胞成熟及细胞质解体,杯形构造由内纤维素壁层向细胞腔内突起形成,油囊由液泡膜包被连接到杯形构造上,油呈浅灰色嗜锇状态,其细胞质和细胞器解体,变得电子不透明或呈杂乱状态。     

白刺胚乳早期发育的超微结构研究

白刺(Nitraria sibirica)胚乳发育经历游离核阶段、细胞化阶段和被吸收解体阶段。游离核胚乳沿胚囊壁均匀排列为一层,胞质浓厚,其中有丰富的质体、线粒体、高尔基体、内质网和各种小泡等细胞器。珠孔区域的胚囊壁具发达的分枝状壁内突,而周缘区域的胚囊壁具间隔的钉状内突,内突周围的细胞质中具多数线粒体和小泡。胚乳细胞化时,初始垂周壁源于核有丝分裂产生的细胞板。在细胞板两端开始壁的游离生长,一端与胚囊壁相连接,另一端向心自由延伸。壁的游离生长依赖于小泡的融合。早期胚乳细胞具大液泡,具核或无核,细胞质中有大量的线粒体,质体缺乏,其壁仍由多层膜结构组成。     

北柴胡分泌道的超微结构及其挥发油分泌的研究

利用透射电子显微镜技术研究了北柴胡营养器官中分泌道的发育以及挥发油的积累.并重点探讨了挥发油的分泌机制.结果显示.分泌道细胞的质体、细胞基质以及线粒体参与挥发油或其前体物质的合成,而内质网参与挥发油向分泌道腔隙的转运.在分泌道发育的后期,大量小泡与分泌细胞相邻壁的质膜融合,并将其内的物质释放入此部分细胞壁中,与此同时,此部分壁在靠近腔隙的位置结构变得松散.然后围绕腔隙的壁在相邻两分泌细胞相接的位置面向腔隙外突形成许多小泡,并将小泡释放入腔隙中.由此可见.北柴胡分泌道中挥发油主要以胞吐方式被排入分泌道的腔隙中.     

小麦雄配子体的超微结构 Ⅰ.营养细胞和生殖细胞的形成

小孢子分裂的末期产生的成膜体,经离心的扩展后形成一个与内壁连结的细胞板,而后形成分隔营养细胞和生殖细胞的壁。由于胞质分裂高度的不均等性,形成大小悬殊的营养细胞和生殖细胞。在初期的生殖细胞和营养细胞的细胞质中,细胞器是没有差异的,包括线粒体、质体、内质网、高尔基体和核糖体。只有在胞质分裂初期看到微管。生殖细胞形成后,进一步的发育是逐渐脱离花粉粒的壁而成为游离的细胞,浸没在营养细胞的细胞质中。与此同时壁物质消失,变为一个被二层质膜所包围的裸细胞。当生殖细胞发育至游离的裸细胞时期,与营养细胞比较,显示明显的异质性,表现为生殖细胞中的质体不发育或退化,其它细胞器没有什么变化。相反,营养细胞中的质体和线粒体在数量上和大小上显著增长,在质体中迅速积累淀粉。对小麦生殖细胞暂时出现细胞壁的意义以及和营养细胞的异质性进行了讨论。     

花椒果实分泌囊发育过程的超微结构研究

电镜观察结果表明,花椒(Zanthoxylum bungeanum Maxim.)果实分泌囊是由裂生方式形成,由鞘细胞、上皮细胞和油腔构成。对分泌囊的原始细胞、油腔发生和扩大以及发育成熟3个时期的超微结构研究表明,其精油是在分泌囊油腔发生时开始积累,以油滴形态存在于上皮细胞的质体内及其周围的细胞质中。根据各细胞器的变化规律分析,质体是精油合成的主要场所,内质网参与精油的合成和转运,线粒体为上述活动提供能量。上皮细胞内积累的精油可能通过两种途径排出细胞,分泌至油腔内贮存。鞘细胞内也积累精油,其主要合成场所也与质体有关,以后转运至上皮细胞内。成熟分泌囊的质体由于功能改变,其内出现蛋白质结晶和淀粉粒。     

红盖鳞毛蕨孢子囊早期发育与质体分化的研究

利用光学显微镜和透射电子显微镜观察了红盖鳞毛蕨(Dryopteris erythrosora(Eaton)O.Ktze.)孢子囊的发育及在此期间质体的分化过程。研究表明:(1)红盖鳞毛蕨孢子囊的发育类型属于薄囊蕨型;(2)绒毡层为混合型,即内层绒毡层为原生质团型,外层绒毡层为腺质型;(3)孢子囊原始细胞中的质体通过3条路径分化,其一,原始细胞中含淀粉粒的质体通过分裂分配到下方细胞,继而进入孢子囊柄;其二,原始细胞分裂产生的新生质体被分配到上方细胞,进而被分配到除顶细胞外的原基细胞中,顶细胞将含淀粉粒的质体通过分裂分配到外套层原始细胞中;其三,顶细胞也将具淀粉粒的质体通过分裂分配到内部细胞,使分裂产生的孢原细胞和绒毡层原始细胞具新生质体;造孢细胞和孢子母细胞的质体具淀粉粒,孢子母细胞还具油体,新生孢子中具造粉体和油体;两层绒毡层具新生质体,随着退化外层绒毡层出现造粉体,内层绒毡层出现油体;(4)红盖鳞毛蕨与少数被子植物小孢子发育阶段质体分化模式类似,由前质体分化为造粉体再到油体。研究结果为蕨类植物质体在孢子囊发育过程不同组织细胞中的差异分化提供了新观察资料,为蕨类植物发育生物学和系统演化研究提供科学依据。     

锦橙汁囊的超微结构

用常规电镜方法观察了锦橙［Ｃｉｔｒｕｓｓｉｎｅｎｓｉｓ （Ｌ．） Ｏｓｂ．］汁囊从原始细胞到发育为一个具柄的成熟汁囊的过程中,汁囊构成细胞超微结构的变化。锦橙汁囊原始细胞及发育为球状体时的构成细胞以及柱状结构顶端的细胞都是一种典型的分生组织细胞。在细胞质中有包括线粒体、质体、内质网、核糖体等丰富的细胞器,但没有观察到高尔基体。这些分生细胞分裂一段时期后就停止活动,逐渐分化为适应贮藏功能的液泡化薄壁细胞。分生细胞开始分化时,在细胞中出现许多小液泡和高尔基体。这些小液泡逐渐地融合,同时细胞质变少,最后形成一个有中央大液泡的薄壁细胞,在紧贴细胞膜的薄薄的一层细胞质中有线粒体、质体、高尔基体以及含有许多脂滴的杂色体。但成熟果实中汁囊的薄壁细胞中几乎没有任何细胞器。     

栽培甜菜花粉发育过程的超微结构

利用透射电镜技术对栽培甜菜(Beta vulgaris)花粉发育过程进行了超微结构观察。结果表明, 在小孢子母细胞减数分裂期间, 细胞内发生了“细胞质改组”, 主要表现在核糖体减少, 质体和线粒体结构发生了规律性变化。末期I 不形成细胞板,而是在2个子核间形成“细胞器带”。“细胞器带”的存在起到类似细胞板的作用, 暂时将细胞质分隔成两部分。四分体呈四面体型, 被胼胝质壁包围。小孢子外壁的沉积始于四分体晚期, 至小孢子晚期外壁已基本发育完全。单核小孢子时期, 细胞核大, 细胞器丰富。二细胞花粉发育主要表现在生殖细胞壁的变化上, 生殖细胞壁上不具有胞间连丝。成熟花粉为三细胞型, 含有1个营养细胞和2个精细胞。精细胞具有短尾突, 无壁, 为裸细胞, 每个精细胞通过2层质膜与营养细胞的细胞质分开。生殖细胞与精细胞里缺乏质体。     

栽培甜菜花粉发育过程的超微结构

利用透射电镜技术对栽培甜菜（Beta vuigaris）花粉发育过程进行了超微结构观察。结果表明,在小孢子母细胞减数分裂期间,细胞内发生了“细胞质改组”,主要表现在核糖体减少,质体和线粒体结构发生了规律性变化。末期1不形成细胞板,而是在2个子核间形成“细胞器带”。“细胞器带”的存在起到类似细胞板的作用,暂时将细胞质分隔成两部分。四分体呈四面体型,被胼胝质壁包围。小孢子外壁的沉积始于四分体晚期,至小孢子晚期外壁已基本发育完全。单核小孢子时期,细胞核大,细胞器丰富。二细胞花粉发育主要表现在生殖细胞壁的变化上,生殖细胞壁上不具有胞间连丝。成熟花粉为三细胞型,含有1个营养细胞和2个精细胞。精细胞具有短尾突,无壁,为裸细胞,每个精细胞通过2层质膜与营养细胞的细胞质分开。生殖细胞与精细胞里缺乏质体。     

玉竹雄配子的发育——着重阐明质体在生殖细胞和营养细胞中的分布和变化

玉竹(Polygonatum simizui Kitag)小孢子在分裂前,质体极性分布导致分裂后形成的生殖细胞不含质体,而营养细胞包含了小孢子中全部的质体。生殖细胞发育至成熟花粉时期,及在花粉管中分裂形成的两个精细胞中始终不含质体。虽然生殖细胞和精细胞中都存在线粒体,但细胞质中无DNA类核。玉竹雄性质体的遗传为单亲母本型。在雄配子体发育过程中,营养细胞中的质体发生明显的变化。在早期的营养细胞质中,造粉质体增殖和活跃地合成淀粉。后期,脂体增加而造粉质体消失。接近成熟时花粉富含油滴。对百合科的不同属植物质体被排除的机理及花粉中贮藏的淀粉与脂体的转变进行了讨论。     

Ultrastructure and development of oil cells in Laurus nobilis L. leaves

The oil cell development in Laurus nobilis leaves has been studied. At the early developmental stage, when the cell wall consists of the outer cellulose wall only, the oil cells differ from the neighbouring mesophyll cells in their larger size, lower starch content and in their plastid organization. After the deposition of the lamellated suberin layer and the inner cellulose layer, a wall protuberance (cupule) is formed on the periclinal wall facing the epidermis. From its reaction with periodic acid-hexamine-silver nitrate, it is suggested that the cupule is cellulosic. The portion of the inner cellulose wall layer bearing the cupule seems to contain patches of suberin. Plasmodesmata occur in special wall protuberances and appear to become occluded with age. The oil produced inside the protoplast is secreted to the outside of the plasmalemma, and accumulates as a drop at the place predetermined by the cupule. Except at the cupule, the oil drop is surrounded by the plasmalemma.     

Ultrastructural Studies on the Development of Oil Cells in Litsea pungens

The developmental process of oil cells in the shoot of Litsea pungens Hemsl. has been studied with transmission electron microscopy. According to the development of the three layers of cell wall, the developmental process could be divided into 4 stages. In stage 1, the cell wall consisted only of a primary (the outmost) cellulose layer, which might further be divided into two substages, the oil cell initial, and the vacuolizing oil cell. During this stage, there were some small electron translucent vesicles and dark osmiophilic droplets of variant sizes in the different-shaped plastids. It was observed that some dark and gray osmiophilic materials coalesced to vacuoles in the cytoplasm. In stage 2, a lamellated suberin layer accumulated inside the primary cellulose layer. In stage 3, a thicker and looser inner cellulose wall layer was formed gradually inside the suberin layer. Some dark osmiophilic droplets have been observed in this loose inner cellulose wall layer. The plasmodesmata were blocked up and became a special structure. Then, the big vacuole, which is the oil sac, was full of osmiophilic oil. In stage 4, the oil cell became matured and the cytoplasm disintegrated. The oil sac enveloped from plasmalemma was attached to the cupule, which was formed by the protuberance of the inner cellulose wall layer into the lumen. After the maturity of oil cell, the ground cytoplasm began to disintegrate and became electron opaque or exhibited in a disordered state, and the osmiophilic oil appeared light gray.     

Ultrastructure and Development of Oil Idioblasts in Annona muricata L.

The ultrastructure and development of oil idioblasts in theshoot apex and leaves in Annona muricata L. are described, andthree arbitrary developmental stages are distinguished: cellsin which no additional cell wall layers have been depositedagainst the initial primary cell wall, possessing an electron-translucentcytoplasm and distinct plastids which lack thylakoids (stage1); cells in which a suberized layer has been deposited againstthe primary wall (stage 2, the cytoplasm resembles that of thepreceding stage), and cells in which an additional inner walllayer has been deposited against the suberized layer, whichincreases in thickness with development (stage 3). In this stagean oil cavity is formed, surrounded by the plasmalemma, andattached to a bell-like protrusion of the inner wall layer,the cupule. A complex membranous structure occurs next to thecupule. Smooth tubular endoplasmic reticulum (ER), appearingas linearly arranged tubules, and groups of crystalline bodieswith an almost hexagonal outline are present. The final stagewas further subdivided into three subgroups (a, b, c) basedon the extent of the oil cavity, its contents, and the compositionof the cytoplasm, and increasing thickness of the inner walllayer. The oil is probably synthesized in the plastids, releasedinto the cytoplasm, and then passed through the plasmalemmasurrounding the oil cavity. Oil idioblasts, Annona muricata L., suberized layer, inner wall layer, oil cavity, cupule, smooth tubular ER, crystalline bodies     

鹅掌楸油细胞的发育解剖学研究

鹅掌楸油细胞比相邻组织细胞分化,因而在叶肉细胞未完全分化的叶原基、幼叶以及未完全分化的幼茎中,都可看到已分化的油细胞。通常,在第二叶原基中可发现油细胞原始细胞,由于其染色深、细胞核大而易与周围组织的细胞相区别。以后,油细胞逐步液泡化,直至形成一个大的液泡,此时,细胞核呈扁平状,并与细胞质一起成为一薄层围绕着大液泡。当油细胞发育成熟后,细胞质及核开始解体,整个油细胞的腔由大液泡充满,成为油囊,在部分     

油樟油细胞和粘液细胞的发育解剖学研究

利用薄切片法对油樟茎叶油细胞和粘液细胞发育的研究结果表明,油细胞最早发生于第二叶原基以及茎端皮层和髓的基本分生组织中。未出现油细胞以前,在上述器官的基本分生组织和原分生组织中,难以区分油细胞的原始细胞与周围细胞,当油细胞原始细胞呈现出体积较大,液泡化程度较低,细胞核大而明显的特征才明显可辨,以后经过液泡融合,油细胞成熟和油细胞的细胞质解体阶段而成为一贮油的囊,而且油囊连接在杯形构造上,粘液细胞的早期发育过程与油细胞的相同,而在细胞液泡化的后期,靠近大液泡的细胞质中产生粘液物质。并扩散到大液泡中,粘液物质不断产生,变浓,占据整个细胞腔,细胞质解体后而成为完全成熟的粘液细胞,因此可见,油细胞和粘液细胞是同源的,也可能粘液细胞是由油细胞转化而来的。     

洋葱花药发育中钙离子分布特征

采用焦锑酸钾沉淀钙离子技术,对洋葱（Alliumcepa）花药发育中Ca^2＋分布进行了研究。在小孢子母细胞时期,小孢子母细胞中的钙沉淀颗粒很少,但绒毡层细胞的内切向壁已出现明显的钙沉淀颗粒。在四分体时期,四分体小孢子的胼胝质壁中出现较多的钙沉淀颗粒;绒毡层细胞内切向壁的钙沉淀颗粒消失,而在外切向壁和径向壁部位的钙沉淀颗粒增加。在小孢子早期,小孢子中也出现了钙沉淀颗粒,而绒毡层细胞内切向壁表面出现了很多絮状物,其上附有细小钙沉淀颗粒。到小孢子晚期,小孢子中出现一些小液泡,细胞质中的钙沉淀颗粒有所下降。此时绒毡层细胞已明显退化,但在绒毡层膜上仍有一些乌氏体和钙沉淀颗粒。在二胞花粉早期,营养细胞中的液泡收缩、消失,细胞质中又出现了较多的钙沉淀颗粒,在质体和其内部的淀粉粒表面上附有较多的钙沉淀颗粒。到二胞花粉晚期,花粉中的钙沉淀颗粒已明显下降,仅在花粉外壁中还有一地钙沉淀颗粒．     

木姜子油细胞的发育解剖学研究

利用薄切片法对木姜子茎叶油细胞的发育以及油细胞分布的研究结果表明：油细胞最早发生于第一叶原基以及茎端皮层和髓的基本分生组织中,在未出现油细胞以痛,上述器官的基本分生组织和原分生组织,难以区分油细胞的原始细胞与周围细胞。当油细胞原始细胞呈现出体积较大,液泡化程度较低,细胞核大而明显的特征才明显可辩,以后经过液泡融合,油细胞成熟和油细胞细胞质解体阶段而成为一贮油的囊,油细胞中未出现杯形构造。叶和茎中,     

Differentiation and Ultrastructure of the Protophloem Sieve Elements of Minor Veins in the Maize Leaves: Changes in the Protoplast

Protophloem sieve element differentiation in the minor veins of the maize ( Zea mays L. ) leaves was first evidenced as an increase of the wall thickness, which began in the comers of the cell and then extended to other parts of the wall, and the appearance of long rough endoplasmic reticulum cistemae distributed throughout the cytoplasm, and then the presence of characteristic crystalloid inclusions within the plastids. As differentiation progressed, long cisternae of rough endoplasmic reticulum appeared to transform into shorter forms and eventually aggregated into small stacks, losing their ribosomes during the process. The nuclei degenerated, although frequently persisted until very late in differentiation the stages of maturation, as darkly stained amorphous aggregates surrounded by double nuclear envelope or only inner membrane of nuclear envelope. Subsequently, the nuclear envelope collapsed and became discontinuous. At the beginning of nuclear degeneration the perinuclear spaces were partly dilated and sometimes the outer nuclear envelope in the dilated portions then ruptured, and was accompanied by the disappearance of the cytoplasmic portion near it. During the peried of nuclear degeneration, in addition to the endoplasmic reticulum, plastids and mitochondria underwent structural modification, while components such as ribosomes, cytoplasmic ground substances, vacuoles and dictyosomes disintegrated and disappeared. At maturity, the surviving protoplasmic components, including plasmalemma, mitochondria, small stacked smooth endoplasmic reticulum and P-type plastids with crystalloids, became parietal in position. As differentiation of adjacent metaphloem sieve elements proceeded, the protoplasmic components of the mature protophloem sieve elements progresively degenerated and finally obliterated.