The ultrastructure of chemolithoautotrophic Gallionella ferruginea and Thiobacillus ferrooxidans as revealed by chemical fixation and freeze-etching

By using sodium thioglycolate to dissolve the high amount of excreted stalk material in axenic cultures of the chemolithoautotrophic iron bacterium Gallionella ferruginea, the ultrastructure of Gallionella cells from pure cell suspensions could be studied without any loss of viability or disturbance by dense ferric stalk fibers, and compared with Thiobacillus ferrooxidans, also grown chemolithoautotrophically with ferrous iron as energy source. Both organisms were chemically fixed or freeze-etched. Particular structural differences between these iron-bacteria could be ascertained. G. ferruginea possesses intracytoplasmic membranes and soluble d-ribulose-1,5-bisphosphate-carboxylase, whereas T. ferrooxidans contains carboxysomes but no intracytoplasmic membranes; Gallionella forms poly--hydroxybutyrate and glycogen as storage material; T. ferrooxidans produces only glycogen. Both organisms also differ from each other with respect to the freeze fracture behaviour of the cell envelope layers. Whereas the cells of T. ferrooxidans exhibit a characteristic double cleavage, exposing the plasmic fracture face and exoplasmic fracture face of the outer membrane and cytoplasmic membrane, the exceptionally thin multilayered cell envelope of G. ferruginea revealed a particularly intimate association between the layers, resulting in a visualisation of the supramolecular organisation of only the inner fracture face of the cytoplasmic membrane. The results are discussed predominantly in relation to the extremely distinct environments of both organisms.     

Structure and ultrastructure of the frog motor endplate

Summary The frog motor endplate in its simplest form consists of an elongated, slender nerve ending embedded in a gutter-like depression of the sarcolemma. This nerve terminal contains the usual synaptic organelles. It is covered by a thin coating of Schwann cell cytoplasm which embraces the terminal with thin finger-like processes from both sides, thereby sub-dividing it into 300–1000 regularly spaced compartments. The individual synaptic compartments correspond to the strings of varicosities or grape-like configurations of motor nerve terminals in endplates of other species and in the cerebral neuropil of vertebrates.Each compartment contains one or more bar-like densities of the presynaptic membrane, active zones, which are associated with the attachment sites between synaptic vesicles and plasmalemma. Active zones have a regular transverse arrangement and occur at specific loci opposite the junctional folds. The attachment sites for synaptic vesicles are at the edges of the bars which are bilaterally delineated by a double row of 10 nm particles attached to the A-face. The structural appearance of vesicle attachment sites in freeze-etch replicas corresponds to that of micropinocytosis. The active zones are often fragmented and the frequency of their association with vesicle attachment sites is highly variable.The junctional folds are characterized by specific sites in which intramembranous particle aggregations occur at relatively high packing density (7500/m²). These sites are located opposite the active zones at the juxtaneural lips, a location where one would expect ACh-sensitive receptors on the postsynaptic membrane.This work was supported by the Deutsche Forschungsgemeinschaft (Sonderforschungsbereich 38, Projekt N), The Swiss National Foundation for Scientific Research (Grants Nr. 3 82372 and 3 77472) and the Dr. Eric Slack-Gyr Foundation Zürich.     

Junctions in the central nervous system of the cat

Summary Fixed and unfixed astrocytic membranes from the CNS of the cat were studied by means of the freeze-etching technique.A variable number of gap junctions was detected in astrocytic membranes. They are characterized by the well known hexagonal composition of their subunits. Besides this type of highly ordered membrane-bound particles, a second one was found. It is composed of four single particles (diameter 5 nm) which form an orthogonal subunit with a side length of about 10 nm. These membrane-associated orthogonal particle complexes (MOPC) could be observed in different stages of aggregation and expansion. They reveal an accumulation in membranes of the marginal glia layers and in the perivascular astrocytic end-feet. Unfixed, glycerol treated membranes, however, do not show these structures. After glycerol treatment of the unfixed membranes by immersion, the MOPC disintegrate to single particles which form clusters of various extension. The clustering phenomenon is dependent on the length of the time of exposure to glycerol. Shortening of the glycerol treatment by intravasal perfusion of the cryoprotectant agent causes an decrease of the clusters. Fragments and transient forms of the MOPC become visible. By variation of different physico-chemical parameters of the washing solution a similar effect on the MOPC was not achieved. The discussion deals with probable functional aspects of the MOPC. They are considered to act as membrane-bound functional multienzyme complexes which a) might play a role in mediating transmembrane passage of metabolites, or b) are essential for CSF control mechanisms, or c) have a functional relation to the nexus.Presented in part at the IIIth European Congress of Anatomists, Manchester, September 1973.Supported by Deutsche Forschungsgemeinschaft, Sonderforschungsbereich 114(Bionach).     

The microvascular pattern and perivascular linings of the area postrema

Summary The microvasculature and perivascular linings of the area postrema (A.P.) were studied electron microscopically with the ultrathin section and freeze-etching techniques. Special attention was given to the intercellular contacts of the different cellular entities. Two types of microvascular segments were identified. The endothelium of these vascular segments reveals fenestrations and a high pinocytotic activity. There are no significant differences in the frequency and distribution of the endothelial openings between both types of capillaries. The endothelium of the blood vessels, however, is joined by different types of tight junctions. Focal tight junctions occur between pericytes and the endothelium, and between leptomeningeal cellular elements in the perivascular space. The cell membrane of the perivascular glia shows intramembrane particles which are either distributed at random or organized in the form of membrane-associated orthogonal particle complexes (MOPC, Dermietzel, 1974). The significance of these findings is discussed with respect to the modified blood-brain barrier mechanism in the A.P.Supported by a grant of the Deutsche Forschungsgemeinschaft (SFB 114 Bionach) to R. DermietzelThe authors are indebted to Mrs. D. Schünke and Mr. R. Eichner for technical assistance and Mr. A. Stapper for preparing the diagram     

致病性暗色霉的浆膜超微结构分类学意义初探

对致病性暗色霉中的着色霉(Fonsecaea Negroni)外瓶霉(Exophiala Charmichael)瓶霉(Phialophoro Medlar)中的五种真菌浆膜超微结构进行了冰冻蚀刻研究,发现裴氏着色霉(Fonsecaea pedrosoi)和紧密着色霉(F.compacta)的内折长而宽,较深,略有弯曲,数量少,多呈平行或垂直排列。皮炎外瓶霉(Exophiala dermatitidis)的内折数量多,密集而分布均匀,呈圆点状或圆棒状。棘状外瓶霉(Exophiala spinifera)的内折少而表浅,多为圆形。疣状瓶霉(Phialophora verrucosa)的内折数量,排列,形状无一定规律。据上述特征,着色霉可以与外瓶霉,疣状瓶霉区别开来,皮炎外瓶霉也可与棘状外瓶霉区分。浆膜超微结构的性状有一定的分类学意义。     

Gap junctions and impulse propagation in embryonic epithelium of Amphibia

Summary Epithelium of amphibian embryos (Cynops orientalis, Xenopus laevis) was found in preceding experiments to generate and conduct impulses during a limited stage (26–37) of development. In order to elucidate the structural basis of impulse propagation, epithelial cells of four stages were examined by the freeze-etching method: (I) before and (II) during acquisition of conductivity; (III) when propagation was fully established, and (IV) when it was no longer present. Only few gap junctions (GJ) of small size were found in groups I and IV. GJ in epithelia of group III were increased in number and size, and appeared morphologically coupled, i.e., with more loosely arranged connexons. The size of gap-junctional particles did not differ significantly between coupled and uncoupled stages. Zonulae occludentes seemed leaky in stage I, and tight in stages II–IV. Thus, the morphological characteristics of specialized junctions between non excitable cells correlated with the opening and closing of low resistance intercellular current pathways during embryonic development.Gap junctions in particular seem to form an essential link in the non-neural stimulus-response system, which may facilitate the mobility of the embryo during early phases of aquatic life before the reflex pathways have been established. Coupling and uncoupling of gap junctions may also play an important role in the regulation of cell differentiation and morphogenetic movement. The experimental model used in this study provides a useful tool for further investigations of structural correlates of gap junctional permeability under physiological conditions.     

Mesothelial intercellular junctions and pathways

Summary Freeze-etch preparations of mesothelial cells taken from the peritoneum of mouse reveal the presence of vesicles invaginating the apical and the basal cell surfaces. These vesicles are scarcely seen within the cytoplasm. Long tortuous tubular profiles extend for considerable distance within the cytoplasm and are frequently associated with the vesicles. The possible nature and role of the vesicles and the tubules in transport phenomena across the mesothelial barrier, are discussed in relation to the pore theory advanced by physiologists and the stomata concept observed by early German and contemporary anatomists. Occludens junctions of the leaky type are seen though their macular or zonular nature is yet to be established.     

Absence of “void area” in freeze-etched vesicles of the Alnus crispa var. mollis Fern. root nodule endophyte

Nitrogen-fixing root nodules of Alnus crispa var. mollis Fern. were studied by transmission electron microscopy and by freeze-etching technique. Ultrathin sectioning of septate vesicles of the actinomycetal endophyte showed an electron transparent zone, the so-called void area, between the vesicle cell wall and its encapsulation material. This void area was not observed in the freeze-etching replicas of cryoprotected nodular tissue. It is suggested that the void area is the result of the coming-off of the vesicle cell wall from the capsule and that its formation reflects difficulty in fixing the voluminous mature vesicle of the root nodule endophyte.