Periodic Oscillations of Myosin-II Mechanically Proofread Cell-Cell Connections to Ensure Robust Formation of the Cardiac Vessel

1. Download : Download high-res image (184KB)
2. Download : Download full-size image

     

Sperm cell surface characteristics of Plumbago zeylanica L. in relation to transport in the embryo sac

Myosin associated with the male germ cells of angiosperms interacts with actin, promoting transport of the non-motile generative and later sperm cells in the pollen tube. Myosin localizing on the sperm cell plasma membrane seems negligible in Plumbago, as reflected by the absence of: (i) anti-myosin labeling using immunoelectron microscopy, (ii) sperm motility on actin matrices, and (iii) electrophoretic movement changes after addition of antibody. Sperm cells injected directly into actively streaming Nitella internodal cells, however, follow actin bundles and their movement is sensitive to ATP and Mg²⁺. This may be based on simple charge binding since negatively charged latex beads also migrate on actin, whereas neutral or positively-charged latex beads do not. Sperm cells are negatively charged according to capillary microelectrophoresis, whereas killed sperm cells, which are positively charged do not migrate. The sperm cell that normally fertilizes the egg has a higher calculated charge (8.277 × 10³ esu/cm²) compared with the sperm cell that fuses with the central cell (6.120 × 10³ esu/cm²). Received: 15 December 1998 / Accepted: 21 January 1999     

Localization of myosin in the cytoskeleton of brush border cells using monoclonal antibodies and confocal laser-beam scanning microscopy

Monoclonal antibodies binding to the rod portion of brush border myosin were used to localize myosin in chicken intestinal brush border cells by indirect immunofluorescence. Isolated cells, or cells still attached in a sheet, were analyzed by conventional epifluorescence microscopy, which showed that most of the immunoreactive myosin is localized in the apical brush border (terminal web), and in a basal region. In addition, a weak, diffuse granular and rod-like labeling was detected throughout the cell body. Using the laser-scanning confocal microscope (White et al., 1987), a more precise localization of the myosin within the terminal web and the cell body was obtained. In the terminal web, most of the myosin was concentrated in a circumferential ring, below the plasma membrane, and the remaining myosin was found in the inter-rootlet area. These two populations of myosin were topologically strictly related, since they were found in the same optical sections. In the cell body, as well as in the basal region, the myosin was found to be associated with the outer limiting membrane of the cell, in a cortical location, whereas essentially no myosin was detected in the cytoplasm.     

Morphological changes during fiber type transitions in low-frequency-stimulated rat fast-twitch muscle

This study investigates morphological adaptations of rat extensor digitorum longus muscle to chronic low-frequency stimulation (10 Hz, 10 h/d, up to 61±7d). During the early stimulation period (2–4 d), increased basophilia and accumulation of RNA were seen predominantly in type-IIB fibers. Putative satellite cell activation, as indicated by ³H-thymidine incorporation, was also evident during this phase. By 12 d, fiber composition remained unaltered, but there was a decrease in the cross-sectional area of the type-IIB fibers. Following 28 d of low-frequency stimulation, the percentage of type-IIB fibers decreased from 43±3% to 0%, while type-IID fibers increased from 30±3% to 60±6%. The fraction of type-IIA fibers tended to increase (controls 19±3%; stimulated 29±4%), whereas that of the type-I fibers was unaltered (4±1%). At this time, the cross-sectional area of type-IID fibers was unaltered, but that of type-IIA and type-I fibers increased. Further stimulation resulted in a return of type-IID fibers to control levels (23±5%), and a marked increase in type-IIA fibers (45±8%). The percentage of type-I fibers increased from 4±1% to 8±1%. Throughout each stage of chronic stimulation, there was no histological evidence of fiber degeneration and regeneration. These results indicate that, in contrast to the rabbit, chronic low-frequency stimulation-induced fiber conversion in the rat extensor digitorum longus muscle is entirely due to fiber transformation.     

Mapping Interactions between Myosin Relay and Converter Domains That Power Muscle Function

Intramolecular communication within myosin is essential for its function as motor, but the specific amino acid residue interactions required are unexplored within muscle cells. Using Drosophila melanogaster skeletal muscle myosin, we performed a novel in vivo molecular suppression analysis to define the importance of three relay loop amino acid residues (Ile⁵⁰⁸, Asn⁵⁰⁹, and Asp⁵¹¹) in communicating with converter domain residue Arg⁷⁵⁹. We found that the N509K relay mutation suppressed defects in myosin ATPase, in vitro motility, myofibril stability, and muscle function associated with the R759E converter mutation. Through molecular modeling, we define a mechanism for this interaction and suggest why the I508K and D511K relay mutations fail to suppress R759E. Interestingly, I508K disabled motor function and myofibril assembly, suggesting that productive relay-converter interaction is essential for both processes. We conclude that the putative relay-converter interaction mediated by myosin residues 509 and 759 is critical for the biochemical and biophysical function of skeletal muscle myosin and the normal ultrastructural and mechanical properties of muscle.     

Immunocytochemical localization of myosin in the brush border region of the intestinal epithelium

Summary Myosin was localized in rat intestinal epithelium by means of indirect immunofluorescence and immunoelectron microscopy (unlabeled antibody peroxidase method), using a specific antibody to myosin from chicken gizzard. Immunoreactivity was localized in the apical cytoplasm, where it was concentrated along the rootlets of the microvillar filament bundles and in the terminal web. A model of microvillar contraction is proposed.     

The circle of life: Phases of podosome formation,turnover and reemergence

Podosomes are highly dynamic actin-rich structures in a variety of cell types, especially monocytic cells. They fulfill multiple functions such as adhesion, mechanosensing, or extracellular matrix degradation, thus allowing cells to detect and respond to a changing environment. These abilities are based on an intricate architecture that enables podosomes to sense mechanical properties of their substratum and to transduce them intracellularly in order to generate an appropriate cellular response. These processes are enabled through the tightly orchestrated interplay of more than 300 different components that are dynamically recruited during podosome formation and turnover. In this review, we discuss the different phases of the podosome life cycle and the current knowledge on regulatory factors that impact on the genesis, activity, dissolution and reemergence of podosomes. We also highlight mechanoregulatory processes that become important during these different stages, on the level of individual podosomes, and also at podosome sub- and superstructures.     

The molecular mechanism of induction of unfolded protein response by Chlamydia

The unfolded protein response (UPR) contributes to chlamydial pathogenesis, as a source of lipids and ATP during replication, and for establishing the initial anti-apoptotic state of host cell that ensures successful inclusion development. The molecular mechanism(s) of UPR induction by Chlamydia is unknown. Chlamydia use type III secretion system (T3SS) effector proteins (e.g, the Translocated Actin-Recruiting Phosphoprotein (Tarp) to stimulate host cell's cytoskeletal reorganization that facilitates invasion and inclusion development. We investigated the hypothesis that T3SS effector-mediated assembly of myosin-II complex produces activated non-muscle myosin heavy chain II (NMMHC-II), which then binds the UPR master regulator (BiP) and/or transducers to induce UPR. Our results revealed the interaction of the chlamydial effector proteins (CT228 and Tarp) with components of the myosin II complex and UPR regulator and transducer during infection. These interactions caused the activation and binding of NMMHC-II to BiP and IRE1α leading to UPR induction. In addition, specific inhibitors of myosin light chain kinase, Tarp oligomerization and myosin ATPase significantly reduced UPR activation and Chlamydia replication. Thus, Chlamydia induce UPR through T3SS effector-mediated activation of NMMHC-II components of the myosin complex to facilitate infectivity. The finding provides greater insights into chlamydial pathogenesis with the potential to identify therapeutic targets and formulations.     

不同低氧时间对SD大鼠颏舌肌肌纤维类型的影响

目的:观察不同低氧时间大鼠颏舌肌肌纤维类型的变化。方法:建立低氧模型,血气分析证实模型成功建立。在低氧不同时间点分别取低氧组和正常组雄性SD大鼠颏舌肌进行HE染色,肌球蛋白ATP酶组织化学染色和RT-PCR检测肌纤维类型的变化。结果:血气分析结果证实低氧组氧分压与血氧饱和度较对照组发生明显下降(P0.05)。低氧1周组、2周组、3周组、4周组较正常组氧分压下降至55.04±2.31 mm Hg,52.69±1.51 mm Hg,49.80±1.39 mm Hg,50.11±3.02 mm Hg(P0.05);血氧饱和度下降至77.51±1.81%,70.13±2.90%,74.20±1.95%,74.97±2.36%(P0.05)。HE染色和肌球蛋白ATP酶组织化学染色法显示低氧2、3、4周组Ⅱ型肌纤维所占比例较相应正常组依次升高:45.92±1.8%,57.44±2.1%,56.89±2.6%,在第三周时达到顶峰(P0.05)。RT-PCR结果也同样验证了这一规律。结论:随着低氧活动的进行,颏舌肌肌纤维类型发生有规律的转化,从而影响着肌肉的功能。