沼泽瘦尾虫皮层纤毛器及其附属微管的观察

应用扫描电镜技术、荧光紫杉醇直接荧光标记显示了腹毛目纤毛虫沼泽瘦尾虫(Uroleptus limnetis)的细胞形态和皮层纤毛器的组成模式,以及皮层口围带、额腹横棘毛、左右缘棘毛等纤毛器微管和纤毛器附属微管的建构特征,可为进一步阐明瘦尾虫类纤毛虫的形态学及其系统发育研究提供基础资料。     

Transient gibberellin application promotes Arabidopsis thaliana hypocotyl cell elongation without maintaining transverse orientation of microtubules on the outer tangential wall of epidermal cells

The phytohormone gibberellin (GA) promotes plant growth by stimulating cellular expansion. Whilst it is known that GA acts by opposing the growth-repressing effects of DELLA proteins, it is not known how these events promote cellular expansion. Here we present a time-lapse analysis of the effects of a single pulse of GA on the growth of Arabidopsis hypocotyls. Our analyses permit kinetic resolution of the transient growth effects of GA on expanding cells. We show that pulsed application of GA to the relatively slowly growing cells of the unexpanded light-grown Arabidopsis hypocotyl results in a transient burst of anisotropic cellular growth. This burst, and the subsequent restoration of initial cellular elongation rates, occurred respectively following the degradation and subsequent reappearance of a GFP-tagged DELLA (GFP-RGA). In addition, we used a GFP-tagged α-tubulin 6 (GFP-TUA6) to visualise the behaviour of microtubules (MTs) on the outer tangential wall (OTW) of epidermal cells. In contrast to some current hypotheses concerning the effect of GA on MTs, we show that the GA-induced boost of hypocotyl cell elongation rate is not dependent upon the maintenance of transverse orientation of the OTW MTs. This confirms that transverse alignment of outer face MTs is not necessary to maintain rapid elongation rates of light-grown hypocotyls. Together with future studies on MT dynamics in other faces of epidermal cells and in cells deeper within the hypocotyl, our observations advance understanding of the mechanisms by which GA promotes plant cell and organ growth.     

Exoskeleton anchoring to tendon cells and muscles in molting isopod crustaceans

Specialized mechanical connection between exoskeleton and underlying muscles in arthropods is a complex network of interconnected matrix constituents, junctions and associated cytoskeletal elements, which provides prominent mechanical attachment of the epidermis to the cuticle and transmits muscle tensions to the exoskeleton. This linkage involves anchoring of the complex extracellular matrix composing the cuticle to the apical membrane of tendon cells and linking of tendon cells to muscles basally. The ultrastructural arhitecture of these attachment complexes during molting is an important issue in relation to integument integrity maintenance in the course of cuticle replacement and in relation to movement ability. The aim of this work was to determine the ultrastructural organization of exoskeleton - muscles attachment complexes in the molting terrestrial isopod crustaceans, in the stage when integumental epithelium is covered by both, the newly forming cuticle and the old detached cuticle. We show that the old exoskeleton is extensively mechanically connected to the underlying epithelium in the regions of muscle attachment sites by massive arrays of fibers in adult premolt Ligia italica and in prehatching embryos and premolt marsupial mancas of Porcellio scaber. Fibers expand from the tendon cells, traverse the new cuticle and ecdysal space and protrude into the distal layers of the detached cuticle. They likely serve as final anchoring sites before exuviation and may be involved in animal movements in this stage. Tendon cells in the prehatching embryo and in marsupial mancas display a substantial apicobasally oriented transcellular arrays of microtubules, evidently engaged in myotendinous junctions and in apical anchoring of the cuticular matrix. The structural framework of musculoskeletal linkage is basically established in described intramarsupial developmental stages, suggesting its involvement in animal motility within the marsupium.     

Rapid microwave fixation of cell monolayers preserves microtubule-associated cell structures.

Microwave (MW) fixation has been suggested as a method to rapidly immobilize cellular dynamics for fine structural studies in the electron microscope. To show its suitability for studies on cell monolayers, one has to apply MW fixation systematically in correlation with samples on the light microscopy level. Examples for MW fixation of cell monolayers, however, are still rare. MW-accelerated fixation for relatively long periods of time (1-2 min) has been reported without showing its suitability at the fine structural level. Here, we provide a rapid MW fixation protocol for cell monolayers on a subminute time scale. The impact of the MW-accelerated glutaraldehyde fixation on temperature-sensitive cytoskeletal components such as microtubules was evaluated. For testing the effectiveness of MW-assisted primary fixation, saponin treatment of the monolayers was included. Simultaneous MW-accelerated fixation and extraction by saponin was necessary to achieve a gradual improvement in visualization of cytoskeletal aspects in association with cell junctions, mitochondria, and centrioles. To establish a valuable routine program for fine structural studies of resin-embedded cell models on substrata, a protocol combining MW fixation with automatic processing in a tissue processor is provided.     

Premature cytokinesis in pollen mother cells of transgenic tobacco plants (<Emphasis Type="Italic">Nicotiana tabacum</Emphasis> L.)

For the majority of dicotyledonous plants, cytokinesis in PMC is staged only once, i.e., after the completion of two cycles of caryokinesis. In the article, a cytological picture and the frequency characteristics of anomalies are shown, in which the cytokinesis in the PMCs of transgenic tobacco plants was already initiated after the first meiotic division. It is shown that, in such cells, the basic processes of cytoskeletal reorganization, which is typical for the simultaneous type of cytokinesis, remained unmodified. However, in most cases, premature division of cytoplasm took place with abnormalities, e.g., with the formation of a membranous “tunnel” or “gash.” It has been detected that the initialization of an additional round of cytokinesis is not an obstacle to the performance of the nuclear cycle or cytokinesis after the second meiotic division. Thus, in the presence of this anomaly, there is a change in the type of cytoplasm division, i.e., of simultaneous to successive.     

Microtubule system in endothelial barrier dysfunction: Disassembly of peripheral microtubules and microtubule reorganization in internal cytoplasm

Endothelial cell barrier dysfunction is associated with dramatic cytoskeletal reorganization, the activation of actomyosin contraction, and, finally, gap formation. Although the role of microtubules in the regulation of endothelial cell barrier function is not fully understood, a number of observations allow for the assumption that the reaction of the microtubule is an extremely important part in the development of endothelial dysfunction. These observations have forced us to examine the role of microtubule reorganization in the regulation of the endothelial cell barrier function. In quiescent endothelial cells, microtubule density is the highest in the centrosome region; however, microtubules are also present near the cell margin. The analysis of microtubule distribution after specific antibody staining using the method of measurement of their fluorescence intensity showed that, in control endothelial cells, the reduction of fluorescence intensity from the cell center to its periphery is described by the equation of exponential regression. The edemagenic agent, thrombin (25 nM), caused the rapid increase of endothelial cell barrier permeability accompanied by a fast decrease in quantity of the peripheral microtubules and reorganization of the microtubule system in the internal cytoplasm of endothelial cells (the decrease of fluorescence intensity is described by the equation of linear regress within as little as 5 min after the beginning of treatment). Both effects are reversible; within 60 min after the beginning of treatment, the microtubule network does not differ from the standard one. Thus, the microtubule system is capable of adapting to the influence of a natural regulator, thrombin. The reorganization of microtubules develops more quickly than the reorganization of the actin filaments system responsible for the subsequent changes of the cell shape during barrier dysfunction. Apparently, the microtubules are the first part in the circuit of the reactions leading to the pulmonary endothelial cell barrier compromise.     

Identification and characterization of a novel neural cell adhesion molecule (NCAM)-associated protein from quail myoblasts: relationship to myotube formation and induction of neurite-like protrusions

Abstract We identified a novel neural cell adhesion molecule (NCAM)-associated protein, myo genesis-related and N CAM- a ssociated p rotein (MYONAP), the expression of which increases during the formation of myotubes in quail myoblasts transformed with a temperature-sensitive mutant of Rous sarcoma virus (QM-RSV cells). MYONAP shares homology with PL48 in human cytotrophoblasts and KIAA0386 in human brain. Excess expression of MYONAP in presumptive QM-RSV myoblasts induced long protrusions like neurites in cooperation with microtubules. Suppression of MYONAP by antisense cDNA prevented myotubes from forming in spite of the expression of myogenin, creatine kinase, and myosin, and rendered myoblast membranes resistant to fusion. Yeast two-hybrid screening showed that MYONAP interacted with NCAM specifically. Deletion of the NCAM-associated domain resulted in a loss of the function that induces neurite-like protrusions to form and disturbed the elongation of microtubules. The results suggested that MYONAP influenced the functions of microtubules and was involved in the formation of myotubes via its interaction with NCAM.     

Actin Cytoskeleton and the Shape of the Plant Cell (A Review)

Recent advances in the study of the cytoskeleton, actin cytoskeleton mainly, its involvement in plant-cell growth of various types, the creation of their specific shape, and also the pathways of intra- and extracellular signal transduction to the actin cytoskeleton are briefly considered. More detail information and the review of earlier publications may be found in numerous comprehensive reviews [1–6] and many others.     

Sorting and Transport of Alpha Herpesviruses in Axons

The alpha herpesviruses, a subfamily of the herpesviruses, are neurotropic pathogens found associated with most mammalian species. The prototypic member of this subfamily is herpes simplex virus type 1, the causative agent of recurrent cold sores in humans. The mild nature of this disease is a testament to the complex and highly regulated life cycle of the alpha herpesviruses. The cellular mechanisms used by these viruses to disseminate infection in the nervous system are beginning to be understood. Here, we overview the life cycle of alpha herpesviruses with an emphasis on assembly and transport of viral particles in neurons.     

Virions and the Coat Protein of the Potato Virus X Interact with Microtubules and Induce Tubulin Polymerization In Vitro

A study was made of the in vitro interactions of virions and the coat protein (CP) of the potato virus X (PVX) with microtubules (MT). Both virions and CP cosedimented with taxol-stabilized MT. In the presence of PVX CP, tubulin polymerized to produce structures resistant to chilling. Electron microscopy revealed the aberrant character of the resulting tubulin polymers (protofilaments and their sheets), which differed from MT assembled in the presence of cell MAP2. In contrast, PVX virions induced the assembly of morphologically normal MT sensitive to chilling. Virions were shown to compete with MAP2 for MT binding, suggesting an overlap for the MT sites interacting with MAP2 and with PVX virions. It was assumed that PVX virions interact with MT in vivo and that, consequently, cytoskeleton elements participate in intracellular compartmentalization of the PVX genome.