The distribution of actin and myosin in Dictyostelium amebae at different developmental stages was studied by improved immunofluorescence ("agar-overlay" technique). Both were localized at the cortical region of amebae in all early developmental stages. In amebae with polarized morphology, bright fluorescence with antiactin was seen in the anterior pseudopode. The cortex in the posterior end was also stained with antiactin. On the other hand, very specific crescent-shaped staining with antimyosin was seen at the posterior cortex. In cells in contact with each other, actin was concentrated at the contact region, whereas myosin was localized specifically in the cortex on the other side of the contact region. At the aggregation stage, when monopodial amebae migrate forming streams, actin staining was seen all around the cell periphery, with intense fluorescence in the anterior pseudopode. On the other hand, specific staining of myosin was seen only at the posterior cortex. The cleavage furrow of cells performing cytokinesis displayed distinct myosin staining, and this staining represented the filamentous structure aligned in parallel to the axis of constriction. These findings indicate that myosin staining reflects the portion of the cell cortex where contraction occurs and the motive force of ameboid movement is generated at the posterior cortex of a migrating cell.Actin and myosin are thought to play significant roles in the biological machinery in nonmuscle cell movement. However, the locomotory mechanism of a cell has not been totally elucidated. Dictyostelium is a good material for studying cell motility because it migrates by ameboid movement, one of the most conservative mechanisms of cell motility. Biochemical and electron microscopic studies have revealed the significant concomitance of actin, myosin, and their associated proteins in cellular motile events of Dictyostelium (6, 12).The solation-contraction coupling hypothesis of Hellewell and Taylor (13) suggests a structural requirement of local breakdown of the gel for contraction in the motile extract of Dictyostelium. However, the structural organization of the contractile components in intact cells has not been fully clarified.Initial immunofluorescence using antiactin showed that vegetative amebae were stained uniformly whereas actively migrating cells are stained strongly at their leading edges (8). Recently, Bazari and Clarke (2) demonstrated that calmodulin and myosin are localized in the peripheral region. Condeelis et al. (5) and Brier et al. (3), using conventional immunofluorescence, found that 120-and 95-kdalton actin-binding proteins are also localized at the cell periphery.Partially because of the round shape and small size of Dictyoslelium amebae, no detailed information on the spatial organization of cytoskeletal components has been provided by conventional immunofluorescence. We thus improved the technique and identified the localization of microtubules (17,30). In the present study, we document the localization of actin and myos...
Myosin is thought to act as a major mechanochemical transducer in non-muscle cell motility, but the in situ organization of the molecules has not yet been determined. Here we report the localization of myosin 'rods', analogous to the thick filaments of muscle, by ameliorated immunofluorescence and demonstrate the dynamic translocation of these rods in response to exogenously added cyclic AMP, which is a chemoattractant for Dictyostelium amoebae. On addition of cyclic AMP, we observed instantaneous shedding of the endoplasmic myosin followed by an increase in cortical rods, the original distribution being recovered in a few minutes. We conclude that myosin filaments mediate Dictyostelium cell movement, probably by an assembly/disassembly cycle of the molecules in response to a chemotactic stimulus.
This paper summarizes the newly developed immersed finite element method (IFEM) and its applications to the modeling of biological systems. This work was inspired by the pioneering work of Professor T.J.R. Hughes in solving fluid-structure interaction problems. In IFEM, a Lagrangian solid mesh moves on top of a background Eulerian fluid mesh which spans the entire computational domain. Hence, mesh generation is greatly simplified. Moreover, both fluid and solid domains are modeled with the finite element method and the continuity between the fluid and solid subdomains is enforced via the interpolation of the velocities and the distribution of the forces with the reproducing Kernel particle method (RKPM) delta function. The proposed method is used to study the fluid-structure interaction problems encountered in human cardiovascular systems. Currently, the heart modeling is being constructed and the deployment process of an angioplasty stent has been simulated. Some preliminary results on monocyte and platelet deposition are presented. Blood rheology, in particular, the shear-rate dependent de-aggregation of red blood cell (RBC) clusters and the transport of deformable cells, are modeled. Furthermore, IFEM is combined with electrokinetics to study the mechanisms of nano/bio filament assembly for the understanding of cell motility.
Movement of a eukaryotic cell along a substrate occurs by extension of lamellipodia and pseudopodia at the anterior and retraction at the posterior of the cell. The molecular and structural mechanisms of these movements are uncertain. Dictyostelium discoideum contains two forms of myosin. Here we show by immunofluorescence microscopy that non-filamentous myosin I occurs at the leading edges of the lamellipodial projections of migrating Dictyostelium amoebae, which are devoid of myosin II, whereas filamentous myosin II is concentrated in the posterior of the cells. On the basis of these locations of the two forms of myosin and their known biochemical and biophysical properties, we suggest that actomyosin I may contribute to the forces that cause extension at the leading edge of a motile cell, while the contraction of actomyosin II at the rear squeezes the cell mass forward. Myosin I isozymes might have similar roles in metazoan cells, for example at the leading edges of neuronal growth cones, and in the extension of lamellipodia and pseudopodia of leukocytes, macrophages and fibroblasts.
Poor oral health and hygiene are increasingly recognized as major risk factors for pneumonia among the elderly. To identify modifiable oral health–related risk factors, we prospectively investigated associations between a constellation of oral health behaviors and incident pneumonia in the community-living very elderly (i.e., 85 years of age or older). At baseline, 524 randomly selected seniors (228 men and 296 women; mean age, 87.8 years) were examined for oral health status and oral hygiene behaviors as well as medical assessment, including blood chemistry analysis, and followed up annually until first hospitalization for or death from pneumonia. During a 3-year follow-up period, 48 events associated with pneumonia (20 deaths and 28 acute hospitalizations) were identified. Among 453 denture wearers, 186 (40.8%) who wore their dentures during sleep were at higher risk for pneumonia than those who removed their dentures at night (log rank P = 0.021). In a multivariate Cox model, both perceived swallowing difficulties and overnight denture wearing were independently associated with an approximately 2.3-fold higher risk of the incidence of pneumonia (for perceived swallowing difficulties, hazard ratio [HR], 2.31; and 95% confidence interval [CI], 1.11–4.82; and for denture wearing during sleep, HR, 2.38; and 95% CI, 1.25–4.56), which was comparable with the HR attributable to cognitive impairment (HR, 2.15; 95% CI, 1.06–4.34), history of stroke (HR, 2.46; 95% CI, 1.13–5.35), and respiratory disease (HR, 2.25; 95% CI, 1.20–4.23). In addition, those who wore dentures during sleep were more likely to have tongue and denture plaque, gum inflammation, positive culture for Candida albicans, and higher levels of circulating interleukin-6 as compared with their counterparts. This study provided empirical evidence that denture wearing during sleep is associated not only with oral inflammatory and microbial burden but also with incident pneumonia, suggesting potential implications of oral hygiene programs for pneumonia prevention in the community.
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