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。     

观光木的小孢子发生及雄配子体发育的研究

采用石蜡切片法对观光木(Tsoongiodendron odorum Chun)的小孢子发生和雄配子体发育进行了解剖学研究.观光木的花药由花药原基发育而来,具4个小孢子囊,花药壁由表皮、药室内壁、2～3层中层和1～2层绒毡层组成.中层在小孢子四分体时期开始解体,最终消失;绒毡层为腺质绒毡层,细胞具1～2核,在花药发育过程中不断分泌各种物质,提供小孢子发育,直到花粉成熟绒毡层才自溶消失.初生造孢细胞分裂形成次生造孢细胞,次生造孢细胞再转化为小孢子母细胞,小孢子母细胞减数分裂的胞质分裂为修饰性同时型,四分体排列方式为交叉型、对称型或"T"型(极少),成熟花粉粒二细胞型,开花时散出.观光木的成熟花粉粒存在严重的败育现象.     

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     

含笑小孢子的发生、雄配子体的发育及其系统学意义

含笑的花药具4个小孢子囊,花药壁由表皮、药室内壁、3～6层中层和绒毡层组成。绒毡层细胞在发育后期由单核分裂为2核,原位解体,为腺质型;小孢子母细胞在减数分裂过程中胞质分裂为同时型,小孢子四分体为四面体型,也有左右对称型的;成熟花粉为3细胞型。在前人对含笑小孢子发生和雄配子体发育的观察描述基础上,丰富了含笑的胚胎学资料,并对其系统学意义进行了探讨。     

越南篦齿苏铁小孢子发生及其系统学意义

运用常规石蜡切片方法,结合显微荧光技术对越南篦齿苏铁Cycas elongata 小孢子发生和花粉个体发育进行了研究。结果表明：其小孢子叶球5月中下旬开始萌动,小孢子囊着生在小孢子叶远轴面,且3-5小孢子囊以辐射状排列方式聚生成聚合囊。小孢子囊壁由6-7层细胞组成,包括表皮、中层及绒毡层。绒毡层来源于成熟造孢组织的外围细胞,其退化形式为分泌型。6月中旬,小孢子母细胞进入减数分裂I,至6月下旬形成四分体。母细胞减数分裂后胞质分裂的方式与其他苏铁类植物不同,具有连续型与同时型两种类型。7月中旬,小孢子经过2次有丝分裂后,形成3细胞的成熟花粉粒。7月下旬进入散粉状态。在花粉发育过程中,母细胞内淀粉粒的积累及其壁上胼胝质的沉积均呈现规律性变化。     

太白红杉小孢子的发生和雄配子体的发育

太白红杉(Larix chinensis Beissn)的雄球花7月初开始分化。小孢子囊壁一般包括5～6层细胞：表皮、药室内壁、2～3层中层和绒毡层。绒毡层属于周原质团型。造孢细胞在7月下旬形成,8月上旬形成小孢子母细胞,8月下旬开始减数分裂,于10月上旬进入双线期,并以双线期渡过休眠。翌年3月下旬解除休眠继续进行减数分裂,4月中旬形成四分体,4月下旬到5月初小孢子从四分体内释放出来,小孢子经过连续4次有丝分裂后,于5月中旬形成5-细胞型的成熟花粉粒(雄配子体)并开始散粉。小孢子母细胞发育表现出不同步现象,部分小孢子母细胞在发育过程中出现退化,在小孢子囊内形成空腔。     

青阳参小孢子发生和雄配子体发育

利用常规石蜡制片技术、荧光显微技术、光镜细胞化学技术、电子显微镜技术对青阳参小孢子发生和雄配子体发育进行了详细观察。结果显示,小孢子孢原细胞起源于皮下组织并在两个地方分化;孢原细胞平周分裂形成初生壁层和初生造孢层,初生壁层细胞再经过平周分裂形成2层细胞,其中最内一层即为绒毡层,绒毡层为分泌型绒毡层,既为小孢子发育提供营养来源,又分泌分泌物形成包围花粉粒的膜;初生造孢层细胞直接行使小孢子母细胞的功能;成熟花粉粒中含有大量淀粉粒、蛋白质、内质网、叶绿体、脂体和大液泡;包围花粉粒的膜和花粉粒之间的膜含有蛋白质成分和脂类成分;小孢子细胞核分裂形成营养细胞和生殖细胞,营养细胞和生殖细胞间没有细胞板形成,生殖细胞呈透镜型、比营养细胞小。     

太白红杉小孢子的发生和雄配子体的发育

太白红杉(Larix chinensis Beissn)的雄球花7月初开始分化。小孢子囊壁一般包括5～6层细胞：表皮、药室内壁、2～3层中层和绒毡层。绒毡层属于周原质团型。造孢细胞在7月下旬形成,8月上旬形成小孢子母细胞,8月下旬开始减数分裂,于10月上旬进入双线期,并以双线期渡过休眠。翌年3月下旬解除休眠继续进行减数分裂,4月中旬形成四分体,4月下旬到5月初小孢子从四分体内释放出来,小孢子经过连续4次有丝分裂后,于5月中旬形成5-细胞型的成熟花粉粒（雄配子体）并开始散粉。小孢子母细胞发育表现出不同步现象,部分小孢子母细胞在发育过程中出现退化,在小孢子囊内形成空腔。     

狗脊孢壁发育超微结构的研究

鳞毛蕨型孢子类型众多,初步研究表明形态相似的孢子类型其孢壁发育特征存在差异,因此有必要对各代表类群的孢壁发育进行深入地研究。该文利用透射电镜对乌毛蕨科(Blechnaceae)狗脊(Woodwardia japonica)孢壁结构和发育的超微结构进行研究。结果表明:(1)狗脊孢子囊的结构由外向内分别为孢子囊壁细胞、两层绒毡层细胞和孢子母细胞;(2)狗脊孢子具乌毛蕨型(Blechnoid type)外壁,表面光滑,由两层构成,裂缝区域具辐射状的槽;(3)周壁属于空心型(cavity type),由四层构成,从内向外分别为P1、P2、P3和P4层,前三层叠合在一起,层间有不同程度的空隙,P4层与前三层之间具有明显而连续的空腔,并隆起形成片状褶皱纹饰;(4)有小球体和小杆共同参与孢子周壁的形成,周壁部分或全部来源于孢子囊壁细胞。综上所述,狗脊孢子与同属于鳞毛蕨型的贯众(Cyrtomium fortunei)和朝鲜介蕨(Dryoathyrium coreanum)孢壁的发育在周壁结构、周壁各层的发育顺序、周壁来源和参与成壁的特征物质等方面存在差异。该研究有利于进一步理解蕨类植物孢壁所蕴含的分类和演化上的科学意义和价值。     

西瓜小孢子囊发育及雄配子体发生的观察

西瓜(Citrullus lanatus)小孢子囊的孢原细胞出现在雄花原基出现后4—6天,孢原细胞数目推测只有一列;初生造孢细胞经过2—3次分裂,形成次生造孢细胞。开花前7—8天,小孢子囊发育健全,小孢子母细胞进入减数分裂期。同一花药不同花粉囊相同一药室,花粉母细胞减数分裂和小孢子的发育,并不是高度同步的。绒毡层为异型细胞,腺质绒毡层。雄配子体的发育开始于开花前6—7天,充分成熟的西瓜花粉已分裂为三细胞花粉。     

Ontogeny of strobili, sporangia development and sporogenesis in Equisetum giganteum (Equisetaceae) from the Colombian Andes

Studies on the ontogeny of the strobilus, sporangium and reproductive biology of this group of ferns are scarce. Here we describe the ontogeny of the strobilus and sporangia, and the process of sporogenesis using specimens of E. giganteum from Colombia collected along the Rio Frio, Distrito de Sevilla, Piedecuesta, Santander, at 2200m altitude. The strobili in different stages of development were fixed, dehydrated, embedded in paraffin, sectioned using a rotatory microtome and stained with the safranin O and fast green technique. Observations were made using differential interference contrast microscopy (DIC) or Nomarski microscopy, an optical microscopy illumination technique that enhances the contrast in unstained, transparent. Strobili arise and begin to develop in the apical meristems of the main axis and lateral branches, with no significant differences in the ontogeny of strobili of one or other axis. Successive processes of cell division and differentiation lead to the growth of the strobilus and the formation of sporangiophores. These are formed by the scutellum, the manubrium or pedicel-like, basal part of the sporangiophore, and initial cells of sporangium, which differentiate to form the sporangium wall, the sporocytes and the tapetum. There is not formation of a characteristic arquesporium, as sporocytes quickly undergo meiosis originating tetrads of spores. The tapetum retains its histological integrity, but subsequently the cell walls break down and form a plasmodium that invades the sporangial cavity, partially surrounding the tetrads, and then the spores. Towards the end of the sporogenesis the tapetum disintegrates leaving spores with elaters free within the sporangial cavity. Two layers finally form the sporangium wall: the sporangium wall itself, with thickened, lignified cell walls and an underlying pyknotic layer. The mature spores are chlorofilous, morphologically similar and have exospore, a thin perispore and two elaters. This study of the ontogeny of the spore-producing structures and spores is the first contribution of this type for a tropical species of the genus. Fluorescence microscopy indicates that elaters and the wall of the sporangium are autofluorescent, while other structures induced fluorescence emitted by the fluorescent dye safranin O. The results were also discussed in relation to what is known so far for other species of Equisetum, suggesting that ontogenetic processes and structure of characters sporoderm are relatively constant in Equisetum, which implies important diagnostic value in the taxonomy of the group.     

扁绒泡菌孢子形成过程超微结构

诱导扁绒泡菌显型原质团形成子实体并观察在形成过程中孢囊的超微结构,结果表明,全部原质团参入形成孢子及孢丝;孢子形成初期原质团聚缩使原生质密度加大,脂滴密度也增加;液泡联合形成液泡网体分割原质团,孢子及孢丝一同形成;相邻孢子初始形成的孢子壁可见吻合的突起和凹陷,这是孢子成熟后的表面纹饰部分;孢子壁随孢囊发育逐渐达到适宜位置,孢子壁由透明内层及电子密度较大的外层组成;随后可见外有疣突,内含脂滴的圆形孢子。     

The developmental patterns of lysosomal enzyme activities during Ca++-induced sporangium formation in Achlya bisexualis

The present paper describes intracellular changes in α-mannosidase specific activity during Ca⁺⁺-induced sporangium formation in the water mold Achlya bisexualis. The enzyme, which is concentrated in a cellular fraction with lysosome-like characteristics, undergoes a four-fold increase during sporangium differentiation. Addition of cycloheximide (100 μg/ml) or actinomycin D (10 μg/ml) at any time during the developmental sequence prevents further increase in the enzyme activity. These data suggest that coincident RNA and protein synthesis are essential for the accumulation of enzyme activity. Mixing of cell extracts from different developmental stages provides evidence that activators or inhibitors of the enzyme activity are not responsible for the enzyme activity evident at the different stages.     

Ultrastructure of excretory system in <Emphasis Type="Italic">Bothrioplana semperi</Emphasis> (Platyhelminthes,Turbellaria)

The ultrastructure of flame bulbs and epithelium of excretory canals in Bothrioplana semperi (Turbellaria, Seriata) have been studied. The flame bulbs consist of two cells, the terminal cell and the proximal canal cell. The weir is formed by two rows of longitudinal ribs. The ribs of the internal row originate from the flame cell, external ribs are formed by the proximal canal cell. Each external rib has a remarkable bundle of microfilaments, originating in the cytoplasm of the first canal cell distally to the bases of external ribs. Membrane of internal ribs is marked by small electrondense granules, separate or fused to an electron-dense layer, continuous to dense “membrane,” connecting both external and internal ribs. Sparse internal leptotrichs originate from the bottom of the flame bulb cavity. External leptotrichs are lacking. Septate junction is present only in proximal canal cell at the level of tips of cilia. The apical surface of the canal cell bears rare short microvilli. The basal membrane of canal cells forms long invaginations that may reach nearly the apical membrane. The epithelium of excretory canals lacks the cilia. The ultrastructure of flame bulbs and epithelium of the excretory canals in B. semperi shares representatives of suborder Proseriata (Seriata). The contradiction exists in interpretation of the structure of flame bulbs in Proseriata. Ehlers and Sopott-Ehlers assumed that the external ribs are derivatives of the proximal canal cell and internal ones are outgrowths of the terminal cell, while Rohde has found conversely: the external ribs are outgrowths of the terminal cell, the internal ones are outgrowths of the proximal canal cell. However, the illustrations provided by Rohde do not enable to ascertain what cells the internal and external ribs derive from, while illustrations provided by Ehlers justify his interpretation. The order of weir formation in B. semperi confirms the viewpoint of Ehlers. The implication of ultrastructure of flame bulbs in Proseriata, especially of the order of flame bulb formation, in the Platyhelminthes phylogeny has been discussed.     

The endobiotic thallus ofPhysoderma maydis,the causal agent ofPhysoderma disease of maize

Summary The endobiotic thallus ofPhysoderma maydis is characterized by the presence of an extremely fine rhizomycelium which passes through the host cell wall, allowing the spread of the disease, and irregularly shaped turbinate cells, which may be septate or nonseptate and which are in close association with developing resting sporangia. The formation of the resting sporangium wall is first seen as localized depositions on the rounded surface of the sporangium and only later on the flattened surface of the sporangium which will form the operculum. The substructure of the resting sporangium wall is typical for members of theBlastocladiales. The resting sporangium is contiguous with the rhizomycelium during development and is finally sealed-off from the rhizomycelium by a further deposition of wall material. After the sealing-off of the resting sporangium from the rhizomycelium the content of the sporangium is compartmentalized and the two inner wall layers are deposited. The centre of the sporangium is filled with an electron dense accretion. At the periphery of the sporangium is a layer of lipid bodies. Between the lipid bodies and the central electron dense accretion is a thin layer of cytoplasm which contains the nuclei. The outer surface of the resting sporangium is smooth.     

Zur vergleichenden Morphologie der CyanophyceeClastidium setigerum und verwandter Gattungen

InClastidium setigerum the mature plant consists of the contents of the endosporangium, the sporangium itself is represented only by a basal cup-shaped cell wall. This cup-shaped wall originates, while the sporangium contents grow out during a very juvenile stage. The spores are homologous to the endospores of related genera but they are not “endo” spores in the literal sense, because they are never surrounded by a common wall. Sporogenesis occurs belated, that is only after the emergence of the sporangium contents, and is effected by centripetally growing-in of the delicate special wall (Eigenwand) of the sporangium contents.Clastidium therefore represents a very remarkable derived member ofDermocarpaceae, but also shows close relationship toCyanophanon. In this connection the systematic position ofGeitleribactron is thoroughly discussed: The morphological peculiarities of this genus, newly created as aChroococcacea byKomárek, are better understood, if the genus is considered as an extremely derived member ofDermocarpaceae with total suppression of a sporangium in the strict sense.     

Nonselective Incorporation into Sporangium of Either “Older” or “Younger” Chromosome of the Vegetative Cell During Sporulation in Bacillus cereus

Employing Bacillus cereus strain 2, we examined the fate of two chromosomes contained in vegetative cells in the course of sporulation. Cytological observations and quantitative estimation of deoxyribonucleic acid (DNA) confirmed the earlier observations that, during the course of sporulation, one of two chromosomes of the vegetative cell was incorporated into the sporangium and the other disappeared into the medium as the result of cell lysis. Log-phase cells, labeled completely with thymine-2-(14)C in the presence of deoxyadenosine, were cultured in the "cold" glucose-glutamate-glycine-salts medium, and culture samples, taken at intervals at successive generations, were subjected to sporulation in glutamate-salts medium. The percentage of radioactivity in the spores separated from each culture remained almost unchanged at nearly 50% and was independent of the number of generations of the preceding culture in the "cold" medium. This suggests that the selective incorporation into the sporangium of either the "older" or "younger" chromosome of a vegetative cell does not occur in the course of spore formation. Some examples of the selective and nonselective behavior of DNA molecules in cellular events in microorganisms are cited.     

沙棘根瘤内生菌的多型性

用透射电子显微镜观察了春、夏、秋、冬四个季节的沙棘根瘤,以及瘤瓣上、中、下三个部位。结果表明,不同季节,不同部位的瘤瓣内,根瘤内生菌有7种不同形态。即侵染菌丝体、繁殖菌丝体、营养菌丝体、春孢子及春孢子囊、泡囊,冬孢子及冬孢子囊和类菌体。在多年生珊瑚状的根瘤中,它们的世代交替是:春夏季以侵染菌丝、繁殖菌丝、营养菌丝、春孢子囊及春孢子、泡囊为主;秋冬季以衰退的营养菌丝、衰老泡囊、冬孢子囊和冬孢子、类菌体为主。冬孢子和类菌体是休眠体。     

The internal pH of the forespore compartment of Bacillus megaterium decreases by about 1 pH unit during sporulation.

Previous work has shown that the internal pH of dormant spores of Bacillus species is more than 1 pH U below that of growing cells but rises to that of growing cells in the first minutes of spore germination. In the present work the internal pH of the whole Bacillus megaterium sporangium was measured by the distribution of the weak base methylamine and was found to decrease by approximately 0.4 during sporulation. By using fluorescence ratio image analysis with a fluorescein derivative, 2',7'-bis(2-carboxyethyl)-5 (and -6)-carboxyfluorescein (BCECF), whose fluorescence is pH sensitive, the internal pH of the mother cell was found to remain constant during sporulation at a value of 8.1, similar to that in the vegetative cell. Whereas the internal pH of the forespore was initially approximately 8.1, this value fell to approximately 7.0 approximately 90 min before synthesis of dipicolinic acid and well before accumulation of the depot of 3-phosphoglyceric acid. The pH in the forespore compartment was brought to that of the mother cell by suspending sporulating cells in a pH 8 potassium phosphate buffer plus the ionophore nigericin to clamp the internal pH of the cells to that of the external medium. We suggest that at a minimum, acidification of the forespore may regulate the activity of phosphoglycerate mutase, which is the enzyme known to be regulated to allow 3-phosphoglyceric acid accumulation during sporulation.