红豆草根瘤侵染细胞核在细胞凋亡中的超微结构变化

用透射电镜观察红豆草根瘤侵染细胞核在细胞凋亡过程中的超微结构,以探讨红豆草根瘤侵染细胞核在发育过程中的超微结构变化及其与细胞凋亡的关系.结果表明,红豆草根瘤侵染细胞核的超微结构随细胞发育程度不同而不同.在幼龄侵染细胞中,细胞核体积较大,近似圆形.在即将成熟和成熟的侵染细胞中,细胞核膜有内陷现象,其核仁常具有核仁泡和核仁联合体.在早期凋亡的侵染细胞中,细胞核体积减小,形状变得不规则,核膜出现大量内陷,在其表面形成许多大的突起和深的沟槽,有时还有内质网、线粒体、小液泡和细菌等位于核膜的内陷处,而且核仁也开始裂解.在后期凋亡的侵染细胞中,除细菌解体外,还出现核仁消失,核膜破裂,核质外流,并在细胞质中形成一些电子密度很高,无一定形状的团块状物质.     

PHB颗粒在红豆草根瘤细菌发育中的动态变化

红豆草根瘤胞间隙和侵入线中另有个别细菌含有PHB颗粒,而且数量很少,一个细菌通常仅有一个。随着细菌被从侵入线中释放到寄主细胞中,这些PHB颗粒立即消失。幼龄细菌不含PHB颗粒,成熟细菌一般也不含这种内含物。当细菌衰老时,它们又再度出现,并大量增加,而后很快减少,直至完全消失。从未发现这种颗粒存在于解体细菌中,尽管它们处于各种不同的解体状态。PHB颗粒在细菌发育中的变化表明,它的多少不仅与根瘤细菌发育密切有关,而且也受制于根瘤品种。     

豌豆根瘤胞间细菌的扩展及其“前途”

中国张家川豌豆根瘤是一种很特殊的根瘤,它的侵入线体积较大,数量很多,在所确发育阶段的寄主细胞中几乎都存在。此外,它还有许多基质丰富,含细菌很少,通常没有壁的类侵入线结构,有时它们的膜、壁和基质还分别与附近侵入线的膜、壁和基质连在一起。在这种根瘤中,胞间细菌不仅能以侵入线方式向新形成的分生细胞扩展,而且也能通过胞间层和胞间隙向根瘤端部白色区域移动。虽然多数侵入线能向寄主细胞释放细菌,但有的直到寄主细胞衰败也无细菌释放,即使细菌在侵入线壁解体后有机会进入这些衰败细胞,它们也很快被细胞中的酶所消化。     

羊奶果根瘤侵入线和被侵染细胞的亚显微结构

羊奶果根瘤的侵入线,总是在几个相邻细胞的细胞间隙中出现。在根瘤发生部位未出现根毛的变形。侵入线似一囊状物,其内含物有丝状物和基质,侵入线的壁部分或全部加厚,并与周围的寄主细胞壁相连。侵入线呈多种形态,在被侵染细胞中,细胞核膨大,并分叉变成指状核。随着细胞的衰老,被侵染细胞中的内生菌、细胞器也逐渐消失。     

箭舌豌豆根瘤液泡中细菌周膜来源的研究

电镜观察结果表明,幼龄箭舌豌豆根瘤侵染细胞的细胞质较少,中央是一些体积较大的液泡。细胞质中侵入线经常可见,由侵入线释放出来的细菌均有细菌周膜。这些细菌只位于细胞质中,不出现在液泡里面。成熟根瘤中的侵染细胞与此不同,它们中有大量的成熟侵染细胞,细胞质丰富,里面充满大量细菌,中央常有一个大液泡。当中央液泡发育到一定程度时,位于其附近的细菌可通过液泡膜内吞、液泡膜与细菌周膜融合及液泡膜破裂3种途径进入液泡,后一种途径常伴有寄主细胞质。液泡中的细菌绝大部分裸露在外,只有个别细菌具有细菌周膜且多位于液泡膜的破损处附近,因此细菌周膜可能是原来就有的。     

羊奶果根瘤侵入线和被侵染细胞的亚显微结构

羊奶果根瘤的侵入线总是在几个相邻细胞的细胞间隙中出现。在根瘤发生部位未根毛的变形。侵入线似一囊状物,其内含物有丝状物和基质,侵和主线的壁部分或全部加厚,并与周围的寄主细胞壁相连。侵入线呈多种形态,在被侵染细胞中,细胞核膨大,并分叉变成指状核。     

小麦类根瘤中胞间细菌的运动及其对细胞壁的影响

用电子显微镜和光学显微镜观察了小麦类根瘤,以探讨小麦类根瘤中胞间细菌的运动及其对细胞壁的影响.结果表明:(1)小麦类根瘤由薄壁细胞、分生细胞和侵染细胞组成,它们中有许多胞间隙,其中一些还含有大量细菌;它们的胞间层常常彼此分离,形成间隙,间隙中有时也有细菌存在;(2)小麦类根瘤中没有侵入线,细菌运动主要在胞间进行;具有细菌的胞间隙和胞间层大小不等、形状各异,其细胞壁还常常出现不同程度的变化,变化的大小一般与它们中的细菌有关,且随细菌数量的增加而增加.     

小麦矮腥黑粉菌在小麦体内侵染过程的显微观察

小麦矮腥黑粉菌可导致小麦矮腥黑穗病,是麦类黑粉病中危害最大、极难防治的国际重要检疫性病害之一.本研究结合扫描电子显微镜、透射电子显微镜及激光共聚焦显微镜观察该真菌在小麦(Triticum aestivum)体内的侵染过程.经观察发现,被该真菌侵染后的小麦叶片细胞超微结构发生了显著变化,如叶肉细胞畸形、质膜内陷和断裂、细胞核结构破坏及细胞器的基质电子密度下降;细胞间隙出现空细胞和纤维状膜状物等;菌丝随生长点移动;寄主小麦子房及花药被侵染导致无法成功受精.该真菌侵染小麦后不但影响小麦的正常生理,且在寄主小麦的根、茎、旗叶以及看似正常的成熟籽粒中均发现冬孢子.     

细菌周膜与液泡膜和液泡内含物的关系

箭舌豌豆根瘤中有丰富的侵入线,从侵入线释放出来的细菌都有细菌周膜。有时液泡中也有细菌,但它们中的绝大多数没有细胞周膜,只有个别例外,而且结构较清晰。细菌结构越好,它的细菌周膜就越完整。因此,液泡中细菌所具有的细菌周膜并非由液泡膜和液泡内含物形成。     

根瘤菌在大麦和水稻根上形成拟瘤的细胞结构

用3种方法使紫云英根瘤菌(Rhizobium astragali Huikui)、田菁根瘤菌(R.sesbania sp.)分别入侵大麦(hordeum vulgare L.)和水稻(Oryza sativa L.),形成拟瘤状组织。一是用一定磁场强度处理根瘤菌和植物,并接种培养。二是用含有水稻幼苗根提取物的培养基培养根瘤菌,接种水稻。三是重复别人用2,4-D外源激素处理植物,接种根瘤菌。镜检观察,用紫云英根瘤菌接种形成的大麦根拟瘤细胞结构非常精细,保持各种细胞器。有侵入线结构和根瘤菌从侵入线释放。根瘤菌被宿主细胞来源的膜包围,成为拟菌体。这些形态结构与豆科根瘤细胞相似,有共生状态特征,但拟菌体有泡状化现象。田菁根瘤菌入侵水稻根形成的拟瘤,在细胞间隙和细胞内都有细菌分布。受侵染的细胞结构粗糙,根瘤菌裸露,无胞膜包围。用2,4-D处理接种根瘤菌的拟瘤细胞结构也如此,但在维管系统内有大量密集的细菌存在。这种结构完全不同于豆科根瘤细胞结构,细菌与植物细胞的形态学相互关系是一种非共生联合作用。     

The Structure of Nitrogen Fixing Root Nodules on the Aquatic Mimosoid Legume Neptunia plena

Nodules of the aquatic mimosoid legume Neptunia plena (L.) Benth.were always found associated with roots but not stems. Theyappeared macroscopically 10 and 20 d after inoculation on plantsgrown hydroponically and in vermiculite, respectively. The developmentof nitrogen-fixing cells occurred in a series of stages notyet reported in legume nodule formation: initial infection wasapparently intercellular and rhizobia spread between cells andthrough intercellular spaces before penetrating individual hostcells by means of infection threads. Subsequently nodule developmentwas broadly similar to that described for indeterminate papilionoidnodules. The infection threads of Neptunia and pea nodules containeda matrix with a common epitope, which was, in Neptunia, extrudedfrom the infection thread at the point of bacterial release. The central tissue contained infected and interstitial cellsand was surrounded by a three-layered cortex and a phellem.Bounding the infected region was a layer two to three cellsthick with large, unoccluded intercellular spaces. Externalto this was a layer, one or more cells thick, in which the cellwalls were interlocked, reducing the number of radially orientedintercellular spaces. The outer layer, several cells thick,contained intercellular spaces many of which were occluded.These features did not vary with growth conditions in a waywhich might influence oxygen diffusion characteristics. However,the phellem of water-cultured nodules was much more aerenchymatousthan that of vermiculite-grown nodules. Aquatic legume, Neptunia plena, nitrogen fixation, oxygen, root nodules, Rhizobium     

Early stages of nodulation in roots of Oxytropis arctobia (Leguminosae) induced by the arctic rhizobial strain N31

Early stages of nodulation of roots of the arctic legume Oxytropis arctobia by the arctic rhizobial strain N31 was characterized under controlled conditions. Root hair deformation occurred as a result of inoculation of seedlings. Infection threads were seen invading target cells in the root cortex of the newly formed nodule tissue. In emergent nodules, bacteria remained surrounded by a moderately electron-dense matrix, within the intercellular space. The target cells were rich in lipid bodies, proplastids, mitochondria and polyribosomes. Fibrillar material, microfilaments and small vesicles were present at the point of bacterial release, where the infection thread was devoid of its wall. Bacteria were found to be encircled by plasmalemma invaginations forming "symbiosomes". Lipid bodies were present near the membrane of the infection thread, close to the site of bacterial release, and in close association with plasmalemma.     

The development and structure of root nodules on bambara groundnut [Voandzeia (Vigna)subterranea]

The infection of Vigna subterranea (formerly Voandzeia subterranea) by Bradyrhizobium strain MAO 113 (isolated from V. subterranea) was examined by light and transmission electron microscopy. Bacteria accumulated on the epidermis close to root hairs, and subsequently entered the latter via infection threads. Most of the steps involved in nodule formation were generally characteristic of determinate nodules, such as those which form on the closely related V. radiata. For example, nodule meristems were induced beneath the root epidermis adjacent to infected root hairs, but prior to infection of the meristem by rhizobia. Moreover, after the infection of some of the meristematic cells by the infection threads, and the release of the rhizobia into membrane-bound vesicles, the infection process ceased and dissemination of the rhizobia was by division of already-infected host cells. However, there were some aspects of this process in V. subterranea which have been more commonly described in indeterminate nodules. These include long infection threads entering a number of cells within the meristems simultaneously and a matrix within infection threads which was strongly labelled with immunogold monoclonal antibodies, MAC236 and MAC265, which recognize epitopes on an intercellular glycoprotein. The MAC236 and MAC265 antibodies also recognized material in the unwalled infection droplets surrounding bacteria which were newly-released from the infection threads. The amount of labelling shown was more characteristic of the long infection threads seen in indeterminate nodules such as pea (Pisum sativum) and Neptunia plena. The structure of mature V. subterranea nodules was similar to that described for other determinate nodules such as Glycine max, Vigna unguiculata and V.radiata, i.e. they were spherical and the infected zone consisted of both infected and uninfected cells. Surrounding the infected tissue was an inner cortex of uninfected cell layers containing the putative components of an oxygen diffusion barrier (including glycoprotein-occluded intercellular spaces), and an outer cortex with cells containing calcium oxalate crystals.     

The development and structure of root nodules on bambara groundnut [Voandzeia (Vigna)subterranea]

The infection of Vigna subterranea (formerly Voandzeia subterranea) by Bradyrhizobium strain MAO 113 (isolated from V. subterranea) was examined by light and transmission electron microscopy. Bacteria accumulated on the epidermis close to root hairs, and subsequently entered the latter via infection threads. Most of the steps involved in nodule formation were generally characteristic of determinate nodules, such as those which form on the closely related V. radiata. For example, nodule meristems were induced beneath the root epidermis adjacent to infected root hairs, but prior to infection of the meristem by rhizobia. Moreover, after the infection of some of the meristematic cells by the infection threads, and the release of the rhizobia into membrane-bound vesicles, the infection process ceased and dissemination of the rhizobia was by division of already-infected host cells. However, there were some aspects of this process in V. subterranea which have been more commonly described in indeterminate nodules. These include long infection threads entering a number of cells within the meristems simultaneously and a matrix within infection threads which was strongly labelled with immunogold monoclonal antibodies, MAC236 and MAC265, which recognize epitopes on an intercellular glycoprotein. The MAC236 and MAC265 antibodies also recognized material in the unwalled infection droplets surrounding bacteria which were newly-released from the infection threads. The amount of labelling shown was more characteristic of the long infection threads seen in indeterminate nodules such as pea (Pisum sativum) and Neptunia plena. The structure of mature V. subterranea nodules was similar to that described for other determinate nodules such as Glycine max, Vigna unguiculata and V.radiata, i.e. they were spherical and the infected zone consisted of both infected and uninfected cells. Surrounding the infected tissue was an inner cortex of uninfected cell layers containing the putative components of an oxygen diffusion barrier (including glycoprotein-occluded intercellular spaces), and an outer cortex with cells containing calcium oxalate crystals.     

Initial stages in the morphogenesis of nitrogen-fixing stem nodules of Sesbania rostrata.

Morphogenesis of stem nodules in Sesbania rostrata was studied over a period of 6 days after inoculation with an appropriate species of Rhizobium. Nodulation sites were initially slightly raised, circular areas 0.3 to 0.6 mm in diameter and 4 to 5 mm apart in vertical rows along the length of the stem. Each site was underlaid by an adventitious root primordium. A site became susceptible to infection by a specific Rhizobium sp. when the root primordium broke through the epidermis, leaving a fissure. Rhizobia multiplied within this fissure and colonized the exposed intercellular spaces. The infection extended inward as narrow, branched intercellular threads moved into a cortical meristematic zone, where cell division was initiated, and invagination of infection thread branches into adjacent plant cells followed. Rhizobia were released into the plant cells and surrounded immediately by plant membrane. Intracellular rhizobia divided actively, leading to bacteroid-filled cells. Infected areas enlarged and coalesced as the nodule matured.     

Electron Microscopic Observation on the Infected Cells During Pea (Pisum sativum L.) Nodule Senescence

Ultrastructural changes of the infected cells have been observed by transmission electron microscopy during pea root nodule senescence. The infected cells and bacteroids of pea nodules ultimately senesce, their senescence has certain laws and features. Firstly, peribacteroid membrane were loosened, leaving a large electron-empty space with fibrillar and vesicular material. Then bacter0id cytoplasm lost features and aggregated into some clustered electron- dense material. At next stage bacteroids were structurally emtpy and appeared like “ghost” cells. Companying bacteroid senescence, host cytoplasm changed from dark to light in electron density and cell organelles gradually decreased. After the host cell tonoplasts and plasmalemma broke down, the infected cells showed a chaotic state of bacteroids and host cell debrises. Finally, infected cells disintegrated completely. Sometimes some young bacteria were seen in the intercellular spaces surrounded by degenerating cells, in the degenerating cytoplasm. A few infection threads were also found among the disintegrated bacteroids, even some of them were releasing the bacteria into the degenerating host cytoplasm.     

Development of N2-fixing nodules on the wetland legume Lotus uliginosus exposed to conditions of flooding

Seeds of the wetland legume, Lotus uliginosus , were germinated and grown in vermiculite which was either continuously flooded or well-drained. Plants from both treatments were infected by Mesorhizobium loti strain DUS341 via a 'classical' root hair pathway, although some flooded plants appeared to be infected via enlarged epidermal cells. Subsequent to infection by M. loti , nodule meristems, which had developed within the root outer cortex, were penetrated by infection threads that released bacteria into the meristematic cells. The infection threads and infection droplets were immunogold labelled with monoclonal antibodies (MAC265 and MAC236) that recognize epitopes (at approx. 155/170 and 170/210 kDa, respectively) on a glycoprotein component of the matrix that surrounded the bacteria within the threads or droplets. Although labelling of infection threads or infection droplets with MAC236 was stronger than that with MAC265, both antibodies strongly labelled material occluding intercellular spaces in the cortices of developing nodules that had not yet expressed nitrogenase (as determined by a lack of signal after immunogold labelling with an antibody raised against nitrogenase component II). After 60 d, nitrogenase activity, shoot and root dry weights, and nodule fresh weight per plant did not differ between the treatments. After a further 30 d submergence, the flooded stems developed extensive aerenchyma and there was profuse development of (nodulated) adventitious roots. Nodules also formed at the junction of adventitious roots and the subtending stem and these were connected vascularly to a small stalk of tissue which gave rise to both a nodule and an adventitious root. The flooded nodules had prominent lenticels, and possible air pathways from the atmosphere to the nitrogen-fixing bacteroids are discussed.     

Structure of nitrogen-fixing nodules formed by Rhizobium on roots of Parasponia andersonii Planch.

The structure of nitrogen-fixing nodules produced by Rhizobium infection of the non-legume Parasponia andersonii was examined by light and electron (both SEM and TEM) microscopy. Comparisons were made with the nodules previously described on P. rugosa. Like the nodules on different non-legumes formed by other types of endophytes, the Rhizobium nodules on Parasponia resembled modified roots by having a central vascular bundle surrounded by an endophyte-infected zone. The intimate association between the Rhizobium and the host nodule cell was compared with the Rhizobium association found in legumes. The rhizobia were not released from the infection thread as happens in the legume. The infection thread, which propagates the Rhizobium infection to new cells, was transformed within a nodule cell from a darkly stained (light microscopy) or very electron-dense (TEM) structure to a number of thread types. The walls of the threads varied greatly in thickness and often the thread structures were without rigid walls and were only enclosed by a plasma membrane. If the rhizobia are transformed into bacteroids, as in the legumes, it would have to occur when the threads had reached their mature size, when bacterial division had ceased. Nitrogen fixation was considered to occur in all thread types.     

Effects of Boron on Rhizobium-Legume Cell-Surface Interactions and Nodule Development

Boron (B) is an essential micronutrient for the development of nitrogen-fixing root nodules in pea (Pisum sativum). By using monoclonal antibodies that recognize specific glycoconjugate components implicated in legume root-nodule development, we investigated the effects of low B on the formation of infection threads and the colonization of pea nodules by Rhizobium leguminosarum bv viciae. In B-deficient nodules the proportion of infected host cells was much lower than in nodules from plants supplied with normal quantities of B. Moreover, the host cells often developed enlarged and abnormally shaped infection threads that frequently burst, releasing bacteria into damaged host cells. There was also an over-production of plant matrix material in which the rhizobial cells were embedded during their progression through the infection thread. Furthermore, in a series of in vitro binding studies, we demonstrated that the presence of B can change the affinity with which the bacterial cell surface interacts with the peribacteroid membrane glycocalyx relative to its interaction with intercellular plant matrix glycoprotein. From these observations we suggest that B plays an important role in mediating cell-surface interactions that lead to endocytosis of rhizobia by host cells and hence to the correct establishment of the symbiosis between pea and Rhizobium.