scholarly journals Actin polymerization and intracellular solvent flow in cell surface blebbing.

1995 ◽  
Vol 129 (6) ◽  
pp. 1589-1599 ◽  
Author(s):  
C C Cunningham
Keyword(s):  
Cell Surface ◽  
Actin Polymerization ◽  
Surface Membrane ◽  
Control Cell ◽  
Cortical Actin ◽  
Final Size ◽  
Actin Structure ◽  
Close Study ◽  
A Cell ◽  
Solvent Flow

The cortical actin gel of eukaryotic cells is postulated to control cell surface activity. One type of protrusion that may offer clues to this regulation are the spherical aneurysms of the surface membrane known as blebs. Blebs occur normally in cells during spreading and alternate with other protrusions, such as ruffles, suggesting similar protrusive machinery is involved. We recently reported that human melanoma cell lines deficient in the actin filament cross-linking protein, ABP-280, show prolonged blebbing, thus allowing close study of blebs and their dynamics. Blebs expand at different rates of volume increase that directly predict the final size achieved by each bleb. These rates decrease as the F-actin concentration of the cells increase over time after plating on a surface, but do so at lower concentrations in ABP-280 expressing cells. Fluorescently labeled actin and phalloidin injections of blebbing cells indicate that a polymerized actin structure is not present initially, but appears later and is responsible for stopping further bleb expansion. Therefore, it is postulated that blebs occur when the fluid-driven expansion of the cell membrane is sufficiently rapid to initially outpace the local rate of actin polymerization. In this model, the rate of intracellular solvent flow driving this expansion decreases as cortical gelation is achieved, whether by factors such as ABP-280, or by concentrated actin polymers alone, thereby leading to decreased size and occurrence of blebs. Since the forces driving bleb extension would always be present in a cell, this process may influence other cell protrusions as well.

scholarly journals Actin polymerization controls the activation of multidrug efflux at fertilization by translocation and fine-scale positioning of ABCB1 on microvilli

2012 ◽  
Vol 23 (18) ◽  
pp. 3663-3672 ◽  
Author(s):  
Kristen Whalen ◽  
Adam M. Reitzel ◽  
Amro Hamdoun
Keyword(s):  
Cell Surface ◽  
Actin Polymerization ◽  
Sea Urchins ◽  
Three Dimensional ◽  
Cortical Reorganization ◽  
Fine Scale ◽  
Multidrug Efflux ◽  
Cortical Actin ◽  
Contrast Enhanced ◽  
And Function

Fertilization changes the structure and function of the cell surface. In sea urchins, these changes include polymerization of cortical actin and a coincident, switch-like increase in the activity of the multidrug efflux transporter ABCB1a. However, it is not clear how cortical reorganization leads to changes in membrane transport physiology. In this study, we used three-dimensional superresolution fluorescence microscopy to resolve the fine-scale movements of the transporter along polymerizing actin filaments, and we show that efflux activity is established after ABCB1a translocates to the tips of the microvilli. Inhibition of actin poly­merization or bundle formation prevents tip localization, resulting in the patching of ABCB1a at the cell surface and decreased efflux activity. In contrast, enhanced actin polymerization promotes tip localization. Finally, interference with Rab11, a regulator of apical recycling, inhibits activation of efflux activity in embryos. Together our results show that actin-mediated, short-range traffic and positioning of transporters at the cell surface regulates multidrug efflux activity and highlight the multifaceted roles of microvilli in the spatial distribution of membrane proteins.

scholarly journals BINDING OF SOLUBLE IMMUNE COMPLEXES TO HUMAN LYMPHOBLASTOID CELLS

1974 ◽  
Vol 140 (4) ◽  
pp. 877-894 ◽  
Author(s):  
Argyrios N. Theofilopoulos ◽  
Frank J. Dixon ◽  
Viktor A. Bokisch
Keyword(s):  
Cell Surface ◽  
B Cell ◽  
Cell Lines ◽  
Immune Complexes ◽  
Surface Membrane ◽  
Raji Cells ◽  
Human Lymphoblastoid Cell ◽  
C Cell ◽  
A Cell ◽  
Soluble Immune Complexes

In the present work we studied the expression of membrane-bound Ig (MBIg) as well as receptors for IgG Fc and complement on nine human lymphoblastoid cell lines. When MBIg and receptors for IgG Fc were compared, four categories of cell lines could be distinguished: (a) cell lines having both MBIg and receptors for IgG Fc, (b) cell lines having MBIg but lacking receptors for IgG Fc, (c) cell lines lacking MBIg but having receptors for IgG Fc, and (d) cell lines lacking both MBIg and receptors for IgG Fc. Two types of receptors for complement could be detected on the cell lines studied, one for C3-C3b and one for C3d. When sensitized red cells carrying C3b or C3d were used for rosette tests, three categories of cell lines could be distinguished: (a) cell lines having receptors for C3b and C3d, (b) cell lines having receptors only for C3d and (c) cell lines lacking both receptors. However, when a more sensitive immunofluorescent method was used instead of the rosette technique, it was found that cell lines unable to form rosettes with EAC1423bhu were able to bind soluble C3 or C3b which indicated the presence of these receptors on the cell surface. Inhibition experiments showed that receptors for C3-C3b and receptors for C3d are distinct and that receptors for C3-C3b and C3d are different from receptors for IgG Fc. A cell line (Raji) without MBIg but with receptors for IgG Fc, C3-C3b, and C3d was selected for use in studying the binding mechanism of soluble immune complexes to cell surface membrane. Aggregated human gamma globulin was used in place of immune complexes. Immune complexes containing complement bind to Raji cells only via receptors for complement, namely receptors for C3-C3b and C3d. Binding of immune complexes containing complement to cells is much greater than that of complexes without complement. Immune complexes bound to cells via receptors for complement can be partially released from the cell surface by addition of normal human serum as well as isolated human C3 or C3b. We postulate that such release is due to competition of immune complex bound C3b and free C3 or C3b for the receptors on Raji cells.

Factor Vlla/Tissue Factor-Catalyzed Activation of Factors IX and X on a Cell Surface and in Suspension: A Kinetic Study

1992 ◽  
Vol 67 (06) ◽  
pp. 654-659 ◽  
Author(s):  
L Vijaya Mohan Rao ◽  
Thomas Robinson ◽  
An D Hoang
Keyword(s):  
Cell Surface ◽  
Tissue Factor ◽  
Intact Cell ◽  
Surface Membrane ◽  
Factor Ix ◽  
Factor X ◽  
Ovarian Carcinoma Cell Line ◽  
Cell Lysate ◽  
A Cell ◽  
The Difference

SummaryThe kinetics of activation of factor IX and factor X by factor Vila was studied in the presence of various sources of tissue factor: (1) a surface membrane of human ovarian carcinoma cell line, OC-2008 (2) the cell lysate (of 002008) and (3) reconstituted purified human tissue factor. The rates of activation of factors IX and X were monitored in activation peptide release assays using tritiated substrates. The results indicate that the apparent K m values for factor IX and factor X were similar for a given tissue factor, but varied with tissue factor source. The source of tissue factor greatly influenced the apparent differences in V max for factors IX and X. When a surface of monolayer provided tissue factor, the Vmax of factor IX was only 2-3 fold lower than factor X, but when either a cell lysate or purified tissue factor was the source of cofactor activity, the difference in V max rose to about 8-10 fold. Although, the tissue factor apoprotein in the cells was expressed entirely on the outer surface membrane, the activity of tissue factor on the intact cell surface was 50 to 100fold lower than in the lysed cell preparation.

Repairing a torn cell surface: make way, lysosomes to the rescue

2002 ◽  
Vol 115 (5) ◽  
pp. 873-879 ◽  
Author(s):  
Paul L. McNeil
Keyword(s):  
Plasma Membrane ◽  
Cell Surface ◽  
Actin Polymerization ◽  
Surface Membrane ◽  
Cell Cortex ◽  
Yolk Granule ◽  
Protein Markers ◽  
Filamentous Actin ◽  
Animal Cells ◽  
Fusion Plasma

Biological membranes are often described as `self-sealing' structures. If indeed membranes do have an inherent capacity for repair, does this explain how a cell can rapidly reseal a very large (1-1000 μm2)disruption in its plasma membrane? It is becoming increasingly clear that, in nucleated animal cells, the cytoplasm plays an active and essential role in resealing. A rapid and apparently chaotic membrane fusion response is initiated locally in the cytoplasm by the Ca2+ that floods in through a disruption: cytoplasmic vesicles are thereby joined with one another(homotypically) and with the surrounding plasma membrane (exocytotically). As a consequence, internal membrane is added to cell surface membrane at the disruption site. In the case of large disruptions, this addition is hypothesized to function as a `patch'. In sea urchin eggs, the internal compartment used is the yolk granule. Several recent studies have significantly advanced our understanding of how cells survive disruption-inducing injuries. In fibroblasts, the lysosome has been identified as a key organelle in resealing. Protein markers of the lysosome membrane appear on the surface of fibroblasts at sites of disruption. Antibodies against lysosome-specific proteins, introduced into the living fibroblast,inhibit its resealing response. In gastric eptithelial cells, local depolymerization of filamentous actin has been identified as a crucial step in resealing: it may function to remove a barrier to lysosome-plasma membrane contact leading to exocytotic fusion. Plasma membrane disruption in epithelial cells induces depolymerization of cortical filamentous actin and, if this depolymerization response is inhibited, resealing is blocked. In the Xenopus egg, the cortical cytoskeleton has been identified as an active participant in post-resealing repair of disruption-related damage to underlying cell cortex. A striking, highly localized actin polymerization response is observable around the margin of cortical defects. A myosin powered contraction occurring within this newly formed zone of F-actin then drives closure of the defect in a purse-string fashion.

scholarly journals A Cell-Surface Membrane Protein Signature for Glioblastoma

Cell Systems ◽  
2017 ◽  
Vol 4 (5) ◽  
pp. 516-529.e7 ◽  
Author(s):  
Dhimankrishna Ghosh ◽  
Cory C. Funk ◽  
Juan Caballero ◽  
Nameeta Shah ◽  
Katherine Rouleau ◽  
...  
Keyword(s):  
Membrane Protein ◽  
Cell Surface ◽  
Surface Membrane ◽  
Cell Surface Membrane ◽  
A Cell ◽  
Protein Signature

A ‘Dynamic Adder Model’ For Cell Size Homeostasis in Dictyostelium Cells

2021 ◽  
Author(s):  
Masahito Tanaka ◽  
Shigehiko Yumura
Keyword(s):  
Cell Surface ◽  
Surface Area ◽  
Cell Size ◽  
Surface Membrane ◽  
Total Cell ◽  
Membrane Turnover ◽  
Cell Surface Area ◽  
Daughter Cells ◽  
A Cell ◽  
Original Size

Abstract After a cell divides into two daughter cells, the total cell surface area of the daughtercells should increase to the original size to maintain cell size homeostasis in a single cellcycle. Previously, three models have been proposed to explain the regulation of cell sizehomeostasis: sizer, timer, and adder models. Here, we precisely measured the total cellsurface area of Dictyostelium cells in a whole cell cycle by using the agar-overlaymethod, which eliminated the influence of surface membrane reservoirs, such asmicrovilli and membrane winkles. The total cell surface area linearly increased duringinterphase, slightly decreased at the metaphase, and then increased by approximately20% during cytokinesis. From the analysis of the added surface area, we concluded thatthe cell size was regulated by the near-adder model in interphase and by the timer modelin the mitotic phase. The adder model in the interphase is not caused by a simple cellmembrane addition, but is more dynamic due to the rapid cell membrane turnover. Wepropose a ‘dynamic adder model’ to explain cell size homeostasis in the interphase.

scholarly journals Yeast actin patches are networks of branched actin filaments

2004 ◽  
Vol 166 (5) ◽  
pp. 629-635 ◽  
Author(s):  
Michael E. Young ◽  
John A. Cooper ◽  
Paul C. Bridgman
Keyword(s):  
Actin Filaments ◽  
Actin Polymerization ◽  
Branch Ratio ◽  
Actin Assembly ◽  
Cortical Actin ◽  
Capping Protein ◽  
Negative Stain ◽  
Actin Structure ◽  
Negative Stain Electron Microscopy ◽  
Actin Patch

Cortical actin patches are the most prominent actin structure in budding and fission yeast. Patches assemble, move, and disassemble rapidly. We investigated the mechanisms underlying patch actin assembly and motility by studying actin filament ultrastructure within a patch. Actin patches were partially purified from Saccharomyces cerevisiae and examined by negative-stain electron microscopy (EM). To identify patches in the EM, we correlated fluorescence and EM images of GFP-labeled patches. Patches contained a network of actin filaments with branches characteristic of Arp2/3 complex. An average patch contained 85 filaments. The average filament was only 50-nm (20 actin subunits) long, and the filament to branch ratio was 3:1. Patches lacking Sac6/fimbrin were unstable, and patches lacking capping protein were relatively normal. Our results are consistent with Arp2/3 complex-mediated actin polymerization driving yeast actin patch assembly and motility, as described by a variation of the dendritic nucleation model.

scholarly journals Inducible recruitment of Cdc42 or WASP to a cell-surface receptor triggers actin polymerization and filopodium formation

1999 ◽  
Vol 9 (7) ◽  
pp. 351-361 ◽  
Author(s):  
Flavia Castellano ◽  
Philippe Montcourrier ◽  
Jean-Claude Guillemot ◽  
Edith Gouin ◽  
Laura Machesky ◽  
...  
Keyword(s):  
Cell Surface ◽  
Actin Polymerization ◽  
Cell Surface Receptor ◽  
Surface Receptor ◽  
A Cell ◽  
Filopodium Formation
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