大豆种子萌发过程中线粒体的发生和发育

从萌发一天的大豆种子中用蔗糖密度梯度离心,不能分离出线粒体,种子萌发两天后,线粒体才开始出现,然后迅速增长。电镜和线粒体标记酶(细胞色素C氧化酶)分析,也证明萌发一天的种子细胞中既不能见到线粒体的结构,也检测不出线粒体酶的活性。种子萌发第2天到第6天线粒体量成百倍地增加,但很少见到线粒体的分裂相,似乎说明线粒体主要不是依靠分裂增殖的。线粒体本身也有一个发育过程,萌发第2天的种子中线粒体结构简单,只有网状膜系统和较大的基质区,萌发第3～4天就开始出现嵴膜,基质区缩小,至第5～6天嵴膜密集,基质区更小,线粒体的出现似乎和氧供应有关,因为线粒体是在种皮破裂的同时出现的。高等植物线粒体在个体发育中似乎并非连续存在,主要也不是以自我分裂方式繁殖,因此推测原质体作为未分化的细胞器既是叶绿体的前体,也是线粒体的前体。     

西瓜种子发育和萌发过程中子叶细胞超微结构的变化

西瓜种子子叶内贮存物质开始积累时,细胞质内有大量核糖体、质体、线粒体,内质网片段和囊泡,种子脱水期至成熟期,细胞器的数量减少,成熟种子子叶细胞的细胞壁不连续,几乎观察不到细胞器的存在,种子萌发过程中内质网,线粒体,质体的数目逐渐增多,叶肉细胞的质体发育成叶绿体,种子形成过程中,在子叶细胞大液泡分隔的同时,膨胀的内质网囊泡内积累蛋白质（直径0.1-0.4μm),这些小的蛋白质球体最终进入液泡形成大的蛋白体（直径1-3μm);萌发种子贮存蛋白质被水解的同时,一些脂体进入液泡并被分解,同时液泡融合;脂类物质开始积累的时间早于蛋白质,积累的量较蛋白质多,但在萌发种子中被彻底水解的时间晚于蛋白质,淀粉粒的数量在种子形成时减少,种子萌发时在表皮细胞和叶肉细胞内都重新合成。     

南湖菱苗端茎轴质体起源与发育的超微结构研究

南湖菱苗端茎轴质体的发育经历了变形、内吞、出芽等变化过程。在苗端茎轴的边缘部位以及幼叶中 ,前质体将发育成为具发达类囊体片层的叶绿体。而在茎轴的中央部位 ,前质体将发生消亡 ,自身水解及液泡内吞是原质体消亡的重要原因。南湖菱苗端的自然发育过程为研究南湖菱质体的起源与分化提供了重要素材。     

萌发玉米种子脱水耐性与胚根细胞超微结构的变化

玉米种子脱水试验表明,25℃下萌发24h种子脱水耐性开始丧失,丧失50％和100％的时间分别为33h、58h。萌发过程中随着吸胀时间增加,玉米种子脱水耐性逐步丧失。显微观察显示,种子吸胀过程中,胚根细胞的贮藏物质逐步减少,线粒体等细胞器的分化程度则不断提高,尤其是脂类物质的分解程度与脱水耐性变化的关系似乎更明显。     

聚乙烯醇预处理提高大豆种子活力和抗冷能力的作用

聚乙烯醇预处理大豆种子和聚乙二醇一样,能明显地提高种子的活力、萌发率和抗冷能力。其主要作用可能是:在整个吸胀过程中减少了吸水速度,使膜的修复作用有足够的时间;启动和改善种子内部的生理代谢过程.保证了生长胚根有更多的物质供应。     

质体

质体是植物细胞特有的一类细胞器,藻类的质体类型比较单一,一般只有叶绿体一种,到了被子植物质体的类型才增多,而且被子植物细胞的发育,很大程度表现在质体的分化上。自从本世纪60年代确证质体含有自己的DNA以来,有人将质体看作是细胞内的细胞,这对理解质体有一定意义。在分生组织中质体呈未分化状态,叫做原质体。随着细胞的分化,原质体的结构和功能都发生深刻的变化,并形成各种质体。按照惠特利(Whatley 1978)的意见,质体大体可分     

烟草叶片外植体脱分化与再分化过程中FtsZ蛋白的表达（简报）

在植物叶肉细胞的脱分化、再分化过程中伴随着叶绿体与质体相互转化的过程。已高度分化的叶肉细胞脱分化为分生状态细胞时．其中的原质体主要由叶绿体出芽生殖产生．偶尔可以看到某些叶绿体分裂或分裂与出芽同时出现的情况。此外,叶绿体在出芽产生原质体的同时自身逐渐被巨大的淀粉粒所充满．从而转变为淀粉体。     

黑节草未成熟种子的形态发育及其在离体培养时的表现

黑节草(Dendrobium candidum Wall ex Lind.)2—6个月种龄的胚均处于球形胚阶段,不同种龄的胚在体积大小、胚细胞数目、胚细胞内的淀粉粒含量和超微结构上有差异。在离体培养条件下黑节草种子萌发率可达95％,种子萌发后形成原球茎,原球茎可以直接发育形成幼苗,又可以由原球茎产生大量愈伤组织,由愈伤组织再分化发育成幼苗。种子萌发过程中,胚顶端分生组织细胞的淀粉逐渐消耗,淀粉的变化与分生组织和子叶的形成有明显的相关性。     

马占相思子叶离体培养中细胞早期变化的研究

用光学和电子显微镜观察马占相思子叶在离体培养中的细胞早期变化,结果表明,未培养的子叶薄壁细胞内充满大量贮藏物质,在脱分化过程中,贮藏物质逐渐减少,细胞核体积增大,液泡蛋白体出现,质体转化为原质体,线粒体,内质网等细胞器数量增加,马脱分化启动后的细胞分裂方式进行了讨论。     

西瓜小孢子发育过程中几种细胞器的变化

用透射电子显微镜观察了西瓜（Ｃｉｔｒｕｌｌｕｓ ｖｕｌｇａｒｉｓ Ｓｃｈｒａｄ．）小孢子发育过程中核糖体、线粒体、质体、内质网、高尔基体等细胞器的变化。核糖体和线粒体变化都有明显的规律性：核糖体密度在四分体时期高,液泡化时期降低,液泡化结束后再回升;线粒体经历一个脱分化与再分化周期,液泡化时期该细胞器数量及其内嵴数目减少而脱分化,液泡化结束后形状多样化、内嵴重新增多而再分化;质体结构不变,但体积变     

Effects of PVA and PEG Pretreatment on Development and Ultrastructure of Plumular Root Mitochondria in Soybean Seed During Low Temperature Imbibition Process

Electron microscope observation revealed that mitochondria in plumular root cells of soy bean seed were invisible at the beginning of seed germination. They were sequentially formed re-differentiated and developed from proplastids during the process of germination. The proplastids in the control plumular root markedly expanded at low temperature imbibition process and did not develop into mitochondria when normal temperature was restored. Even the structure of reticulata membrane was further destroyed and vacuolized. In contrast, mitochondria of soybean seed pretreated with polyvinyl alcohol (PVA) and polythylene glycol-6000 (PEG) continused to develop well under the same conditions, as characterized by a clear structure of bilayered membrane and tube cristae. The results suggest that continuous re-differentiation and development of proplastids into mitochondria at low temperature imbibition process play an important role in the increase of soybean seed vigour and its resistance to chilling injury.     

PVA和PEG(6000)预处理对大豆胚轴生长、蛋白质合成和ATP含量的影响

在低温吸胀阶段,经PVA(聚乙烯醇)和PEG(聚乙二醇6000)预处理的大豆胚轴蛋白质合成和ATP含量均比对照高。在萌发阶段,胚轴生长增快,蛋白质合成明显加快,ATP迅速被消耗,而对照胚轴则相反。试验结果表明,预处理大豆种子萌发和生长与其蛋白质合成、ATP水平和消耗能力有密切关系。     

菜用大豆种子活力与DNA,RNA及蛋白质合成的关系

菜用大豆种子随着其活力的下降,对DNA,RNA和蛋白质前体的吸收,以及合成这些大分子的能力都明显下降,已丧失合成DNA和蛋白质能力的失活种子,仍能进行微弱的RNA合成。高活力种子在吸胀初期DNA合成速率较低,然后增加,至16h达高峰;RNA的合成速率在吸胀一开始就很高,在整个吸胀过程中均保持较高水平;蛋白质的合成速率则在开始较高,并随着吸胀过程呈增强趋势。     

Effect of Low Temperature lmbibition on Mito chondrium Respiration and Phosphorylation of PEG Primed Soybean Seed

Cotyledon mitochondrium respiration and oxidative phosphorylation activity of PEG primed and unprimed (control) soybean seeds which have been exposed to low temperature imbibition before germination are studied. The ADP stimulated respiration rates of control mitochondria are evidently higher than state Ⅲ respiration rates of mitochondria from primed seed when L-Mal, α-Kg and Succ are used as substrates respectively. The mitochondria from the unprimed do not possess respiratory control (RC.) On the contrary, mitochondria from the primed, even after seeds being exposed to 2–3 ℃ imbibition for 24 h, phosphorylate normally. The ADP/O and RC values are consistent with those of theoretical expectation. When NADH is used as substrate, unprimed seed mitochondria still possess oxidative phosphorylation activity, while ADP/O and RC values are obviously lower than those of mitochondria from the primed. The emerging sequence of the activity of the diverse phosphorylation sites during germination is also studied. When a different substrate is used, the emerging sequence of the primed is as follows: 1. NADH (12 h), 2.α-Kg (24 h), 3. L-Mal and Succ (48 h). This corresponds to occurrence sequence of ADP stimulated respiration in control mitochondria. The above results show that low temperature imbibition has an irreversible destructive effect on oxidative phosphorylation activity of control mitochondria, and PEG priming has a protective effect on structure and function of the mitochondria under low temperature imbibition stress. The mechanism of soybean imbibitional chilling injury and protective effect of PEG priming are discussed.     

The Effect of Low Temperature during Imbibition on Germination Characteristics of Tetracentron sinense (Tetracentraceae) Seeds

In this paper, the effects of low temperature, soil moisture and freezing time on the germination of Tetracentron sinense Oliv. seeds were studied by simulating wild environment conditions, and the factors influencing the natural regeneration of Tsinense population were discussed. The results are as follows: (1) The imbibition process of Tsinense seed can be divided into four stages, the water absorbing capacity of Tsinense seed after imbibition would increase with the increase of soil moisture, and the seeds would be fully imbibed under the condition of 30% soil moisture; (2) The germination rate, germination force and water content of Tsinense seed increased with the increase of storage time, and the vigor index gradually decreased after increasing before; (3) At different low temperature, the germination rate of Tsinense seed reached the highest when the soil moisture is 20% or 30%; (4) When treated at 20% soil moisture for 2-4 days or 21-28 days, 0℃ is best for the germination rate of Tsinense seed; when treated at 30% soil moisture for 14-28 days, -7℃ is best fort he germination rate of Tsinense seed; (5) When treated at the same condition of freezing time, the germination rate of seeds in fallen leaves had no significant difference with the decrease of low temperature; under the same condition of low temperature (0℃ low temperature except), the germination rate increased after frozen 28 days. The results showed that there is no significant influence of low temperature during imbibition on germination characteristics of Tetracentron sinense seeds and indicating that low temperature during imbibition is not the main factor influencing the natural regeneration of Tsinense population.     

THE ULTRASTRUCTURE OF DRY AND IMBIBED COTYLEDONS OF SOYBEAN

Ultrastructural observations of parenchyma cells of cotyledons of soybean (Glycine max (L.) Merr.) indicate that a 20-min period of imbibition brings about extensive changes in membranes and organelles. The plasma membrane, which in cells of dry seeds is disorganized and disrupted, becomes relatively intact and continuous. A network of endoplasmic reticulum vesicles and tubules, no evidence of which can be discerned in dry seeds, appears extensively dispersed through the cytoplasm and around the margin of protein bodies. Mitochondria in dry tissue are distorted in shape and nearly devoid of internal structure. In imbibed cells they are round or oval and are bound by an intact membrane enclosing numerous cristae and a dense stroma. Starch grains develop in proplastids. Circular or whorled membranous structures appear in the cytoplasm. The swiftness with which membranes and organelles are structurally altered during imbibition is a reflection of their effectiveness in rapidly modifying solute loss and solvent entry.     

Electron microscopic study on the initiatory cell-activation of procambium at commencement of germination in radish cotyledons

Most fine structural studies of seed germination have been begun at 24 hr after imbibition of water and lasted for several days. However, studies on the initial period beginning with water uptake are few. In the present study, fine structural changes in radish seed cotyledonal tissues which occur within the first 24 hr of germination were investigated. Remarkable morphological and developmental changes of the cell organelles were profound in procambial cells in a matter of hours, while no cytological changes were noticed yet in mesophyll (storage tissue) cells. The endoplasmic reticulum and Golgi bodies were somewhat proliferated, a rapid development even, of proplastids occurred, and the increment of mitochondria in numbers and profiles were particularly noteworthy. From these observations, it was interpreted that, although the procambium accounts for only a small portion of the cotyledons, the initiatory activation of procambial cells, being sensitive to the starting of water uptake, might provide certain facility for leading the activation of the more lethargic storage tissue in the beginning of germination process.     

Ultrastructure of Protein Bodies and Plastids in Cotyledon of Nelumbo nucifera Gaertn.at Seed Germination

The present article deals mainly with the formation and dissolution of protein bodies and development of plastids in cotyledon cells of Nelumbo nucifera during seed germination. Electron microscopic studies reveal that protein bodies are formed after imbibition of the cotyledons before germination. They are produced through accumulation of protein material in small vacuoles delivered from the exudates of endoplasmic reticulum or by fragmentation of endoplasmic reticulum itself. In the period of germination, most of the material in the protein bodies dissolute and they coalesce with each other forming large vacuoles. The protein residue of the vacuoles condenses into small blocks with high electron density adhering to the tonoplast or freely floating in the vacuole. Thus, it suggests that the protein bodies of the germinating N. nucifera cotyledons are originated from vacuoles formed by endoplasmic reticulum. Part of the plastids found in cotyledonous cells of mature N. nucifera seeds exists as proplastids. They develop continuously after imbibition of the cotyledons. During the period of seed germination, many concentric lamellae are developed along the plastid membrane on which they later coalesce with the neighboring concentric lameUae forming loosely organized prolamellar bodies which condense into paracrystalline lattices. No ribosomes are present in the inter spaces of paracrystatline lattice. One to several prolamellar bodies can be developed in one plastid.     

Mitochondrial biogenesis during germination in maize embryos

Mitochondrial biogenesis and metabolism were investigated during maize (Zea mays) seed germination. Mitochondria from dry and imbibed seed exhibited NADH-dependent O(2) uptake that was completely inhibited by KCN and antimycin A. Mitochondria in the dry seed had a lower rate of succinate-dependent O(2) uptake relative to that measured in imbibed and germinated seed. The activities of the tricarboxylic acid (TCA) cycle enzymes, pyruvate dehydrogenase complex, 2-oxoglutarate dehydrogenase complex, NAD-malic enzyme, and citrate synthase, are similarly low in mitochondria from dry seed and this correlates with a lower relative abundance of the mitochondrial matrix-located citrate synthase and pyruvate dehydrogenase complex E1alpha-subunit polypeptides. Electron microscopy revealed that mitochondria in the dry seed have a poorly developed internal membrane structure with few cristae; following 24 h of germination the mitochondria developed a more normal structure with more developed cristae. The mitochondria from maize embryos could be fractionated into two subpopulations by Suc density gradient centrifugation: one subpopulation of buoyant density equivalent to 22% to 28% (w/w) Suc; the other equivalent to 37% to 42% (w/w) Suc. These two subpopulations had different activities of specific mitochondrial enzymes and contained different amounts of specific mitochondrial proteins as revealed by western-blot analysis. Both subpopulations from the dry embryo were comprised of poorly developed mitochondria. However, during imbibition mitochondria in the heavy fraction (37%-42% [w/w] Suc) progressively acquired characteristics of fully functional mitochondria found in the germinated seedling in terms of structure, enzymic activity, and protein complement. In contrast, mitochondria in the light fraction (22% to 28% [w/w] Suc) show no significant structural change during imbibition and the amounts of specific mitochondrial proteins decreased significantly during germination.