Degree of cell spreading on a substrate as the factor determining the nature of cell microrelief in suspension

Quantitative ratio of various types of cell surface microrelief was determined in suspensions prepared from mouse monolayer cultures of embryo fibroblasts grown on different solid substrates: with high (Falcon) or low poly(2-hydroxyethylmethacrylate) adhesiveness; with flat or cylindrical (53-mu curvature radius) surfaces (polyvinylchloride). The electron microscopy revealed that poorly spread cells (on low adhesive or cylindrical substrata) in suspensions had the microvillous surface relief much more often than the cells brought to suspension from highly adhesive or flat substrata. Thus, the lower the degree of cell spreading on the substratum, the higher the probability for the cell to acquire the microvillous relief in suspended state. The microvillous relief of transformed cells in suspensions is, probably, due to their poor spreading on substrata in the monolayer cultures.     

Conformon-driven biopolymer shape changes in cell modeling

Conceptual models of the atom preceded the mathematical model of the hydrogen atom in physics in the second decade of the 20th century. The computer modeling of the living cell in the 21st century may follow a similar course of development. A conceptual model of the cell called the Bhopalator was formulated in the mid-1980s, along with its twin theories known as the conformon theory of molecular machines and the cell language theory of biopolymer interactions [Ann. N.Y. Acad. Sci. 227 (1974) 211; BioSystems 44 (1997) 17; Ann. N.Y. Acad. Sci. 870 (1999a) 411; BioSystems 54 (2000) 107; Semiotica 138 (1-4) (2002a) 15; Fundamenta Informaticae 49 (2002b) 147]. The conformon theory accounts for the reversible actions of individual biopolymers coupled to irreversible chemical reactions, while the cell language theory provides a theoretical framework for understanding the complex networks of dynamic interactions among biopolymers in the cell. These two theories are reviewed and further elaborated for the benefit of both computational biologists and computer scientists who are interested in modeling the living cell and its functions. One of the critical components of the mechanisms of cell communication and cell computing has been postulated to be space- and time-organized teleonomic (i.e. goal-directed) shape changes of biopolymers that are driven by exergonic (free energy-releasing) chemical reactions. The generalized Franck-Condon principle is suggested to be essential in resolving the apparent paradox arising when one attempts to couple endergonic (free energy-requiring) biopolymer shape changes to the exergonic chemical reactions that are catalyzed by biopolymer shape changes themselves. Conformons, defined as sequence-specific mechanical strains of biopolymers first invoked three decades ago to account for energy coupling in mitochondria, have been identified as shape changers, the agents that cause shape changes in biopolymers. Given a set of space- and time-organized teleonomic shape changes of biopolymers driven by conformons, all of the functions of the cell can be accounted for in molecular terms-at least in principle. To convert a conceptual model of the cell into a computer model, it is necessary to represent the conceptual model in an algebraic language. To this end, we have begun to apply the process algebra of Milner [Communicating and Mobile Systems: The pi-calculus, Cambridge University Press, Cambridge, 1999] to develop what is here called the "shape algebra," capable of describing complex and mobile patterns of interactions among biomolecules leading to cell functions.     

An alternative method for determining inhibition rate constants by following the substrate reaction

An alternative plotting method is described by which microscopic inhibition rate constants can be determined by following the substrate reaction in the presence of the irreversible inhibitor. Not only does this method keep the advantage of Tsou's original method (Tsou, 1965a. Acta Biochem. biophys. Sin. 5, 1028-1032; 1965b. Acta Biochem. biophys. Sin 5, 409-417), but also is suitable for the cases where the consumption of substrate and accumulation of product must be taken into account.     

Adaptation of a ciliary basal apparatus to cell shape changes in a contractile epithelium

Cilia projecting from the surfaces of highly contractile myoepithelia in the sea anemone Metridium senile maintain their basal orientation, and their ability to propel water, at different states of mesentery contraction, despite substantial changes of myoepithelial cell diameter and length. The ciliary basal apparatus in each monociliated myoepithelial cell is structurally well adapted to provide a stable anchorage for the cilium whilst compensating for these shape changes. It is composed of a distal centriole (basal body), a proximal centriole, a striated rootlet 2-3 micron long which is composed of a bundle of 4-6 nm filaments, and an arched rootlet, also striated, which is composed of a relatively loose bundle of 9-11 nm filaments. A single basal foot projects from the side of the distal centriole in the same direction as the path of the cilium during an effective-stroke; its tip is a focus for many microtubules that radiate outward in all directions toward the cell membrane. The arched rootlet forms a single arch in the cell apex, also in the same plane as the path of the cilium during an effective-stroke. The central axis of the basal apparatus, that is through the distal centriole and the striated rootlet, passes through the apex of the arch. The arched rootlet is apparently flexible so that it can increase or decrease its span as the cell increases or decreases in diameter. In pharnyx and siphonoglyph cells from M. senile, which do not undergo great changes in diameter or length, there is no arched rootlet, and the striated rootlet is much longer. The broad structural diversity of the metazoan ciliary basal apparatus must to a large extent be related to the diversity of the structural and mechanical properties of the cells in which it occurs.     

Shear flow-induced detachment kinetics of Dictyostelium discoideum cells from solid substrate

Using Dictyostelium discoideum as a model organism of specific and nonspecific adhesion, we studied the kinetics of shear flow-induced cell detachment. For a given cell, detachment occurs for values of the applied hydrodynamic stress above a threshold. Cells are removed from the substrate with an apparent first-order rate constant that strongly depends on the applied stress. The threshold stress depends on cell size and physicochemical properties of the substrate, but is not affected by depolymerization of the actin and tubulin cytoskeleton. In contrast, the kinetics of cell detachment is almost independent of cell size, but is strongly affected by a modification of the substrate and the presence of an intact actin cytoskeleton. These results are interpreted in the framework of a peeling model. The threshold stress and the cell-detachment rate measure the local equilibrium energy and the dissociation rate constant of the adhesion bridges, respectively.     

Echinocyte formation: a test case for mechanisms of cell shape changes

That cell shape changes result from monolayer condensation and/or expansion of plasma membranes when clustering of intrinsic membrane proteins occurs is a feasible hypothesis to explain important aspects of cell behaviour. Information about the human red blood cell membrane is consistent with the hypothesis. The formation of echinocytes (red cells with regular outward projections) constitutes a tractable test case for the hypothesis. Critical experiments can be done on red cells with available techniques.     

Characterization of the nuclear deformation caused by changes in endothelial cell shape

We investigated the mechanotransduction pathway in endothelial cells between their nucleus and adhesions to the extracellular matrix. First, we measured nuclear deformations in response to alterations of cell shape as cells detach from a flat surface. We found that the nuclear deformation appeared to be in direct and immediate response to alterations of the cell adhesion area. The nucleus was then treated as a neo-Hookean compressible material, and we estimated the stress associated with the cytoskeleton and acting on the nucleus during cell rounding. With the obtained stress field, we estimated the magnitude of the forces deforming the nucleus. Considering the initial and final components of this adhesion-cytoskeleton-nucleus force transmission pathway, we found our estimate for the internal forces acting on the nucleus to be on the same order of magnitude as previously measured traction forces, suggesting a direct mechanical link between adhesions and the nucleus.     

Prostaglandin induced shape changes in fibroblasts grown in cell culture

PGE₂ induced shape changes in porcine adventitial fibroblasts grown on glass in low density monolayer cell cultures. Incubation of the cells with PGE₂ at concentrations of 100 ng/ml and 1000 ng/ml induced rounding of flat fibroblasts within one hour. The rounded cells had a small rim of cytoplasm around the nucleus and from one to several long thin arborizing cytoplasmic processes extending outward along the substratum. Removal of the PGE₂ resulted in transient blebbing of the cell membrane of both the cell body and the processes as the cells returned to their flat normal morphology within one hour. The effect could be inhibited by 1% fetal calf serum. PGF_2α did not however induce similar changes. This difference between PGE₂ and PGF_2α is similar to a report on spreading and migration of mouse peritoneal macrophages, and suggests that under certain conditions PGE₂ may have the ability to induce shape changes in cells.     

Prostaglandin induced shape changes in fibroblasts grown in cell culture

PGE2 induced shape changes in porcine adventitial fibroblasts grown on glass in low density monolayer cell cultures. Incubation of the cells with PGE2 at concentrations of 100 ng/ml and 1000 ng/ml induced rounding of flat fibroblasts within one hours. The rounded cells had a small rim of cytoplasm around the nucleus and from one to several long thin arborizing cytoplasmic processes extending outward along the substratum. Removal of the PGE2 resulted in transient blebbing of the cell membrane of both the cell body and the processes as the cells returned to their flat normal morphology within one hour. The effect could be inhibited by 1% fetal calf serum. PGF2 alpha did not however induce similar changes. This difference between PGE2 and PGF2 alpha is similar to a report on spreading and migration of mouse peritoneal macrophages, and suggests that under certain conditions PGE2 may have the ability to induce shape changes in cells.     

Ultrastructural changes in the cerebral cortex following transcranial micropolarization]

Electron microscopy of the cerebral cortex in cats and monkeys following transcranial micropolarization (TCMP) demonstrated ultrastructural changes whose degree was dependent on the electric current intensity and the stimulation period. In the focus of stimulation the current affected the brain tissue directly, different elements of the cerebral cortex showing unegual sensitivity to various TCMP regimens. The glia was the first to respond, then the neuronal bodies, and the last -- the synaptic structures. In the areas distant from the TCMP focus synaptic components altered first. The ultrastructural changes revealed were not of pathological character.     

Bilayer balance and regulation of red cell shape changes

Discocytic human red cells undergo discocyte-echinocyte and discocytestomatocyte transformations under the action of a wide variety of lipid-soluble anionic and cationic agents respectively. These shape transformations are explained by the bilayer couple hypothesis of Sheetz and Singer to be the result of preferential distribution of the anionic agents in the outer half of the bilayer and the cationic agents in the inner half of the bilayer. We demonstrate that echinocytogenic effects indeed occur when the naturally occurring phospholipid lysophosphatidylcholine (LPC) is localized in the outer half of the bilayer, and stomatocytogenic effects occur when LPC is in the inner half. However, in contrast to the bilayer couple hypothesis, our results show that simple equivalent membrane surface area expansion on each layer is insufficient to maintain the discocytic shape and there exists a differential concentration effect of LPC on the two halves of the bilayer.     

Extracellular matrix- and cytoskeleton-dependent changes in cell shape and stiffness

Cell spreading is correlated with changes in important cell functions including DNA synthesis, motility, and differentiation. Spreading is accompanied by a complex reorganization of the cytoskeleton that can be related to changes in cell stiffness. While cytoskeletal organization and the resulting cell stiffness have been studied in motile cells such as fibroblasts, less is known of these events in nonmigratory, epithelial cells. Hence, we examined the relationship between cell function, spreading, and stiffness, as measured by atomic force microscopy. Cell stiffness increased with spreading on a high density of fibronectin (1000 ng/cm(2)) but remained low in cells that stayed rounded on a low fibronectin density (1 ng/cm(2)). Disrupting actin or myosin had the same effect of inhibiting spreading, but had different effects on stiffness. Disrupting f-actin assembly lowered both stiffness and spreading, while inhibiting myosin light chain kinase inhibited spreading but increased cell stiffness. However, disrupting either actin or myosin inhibited DNA synthesis. These results demonstrate the relationship between cell stiffness and spreading in hepatocytes. They specifically show that normal actin and myosin function is required for hepatocyte spreading and DNA synthesis and demonstrate opposing effects on cell stiffness upon disruption of actin and myosin.     

Myosin light chains are not a physiological substrate of AMPK in the control of cell structure changes

The kinetics of myosin regulatory light chain (MLC) phosphorylation by recombinant AMP-activated protein kinase (AMPK) were compared with commercial AMPK from rat liver and smooth muscle myosin light chain kinase (smMLCK). With identical amounts of activity units, initial rates of phosphorylation of MLC were at least 100-fold less with recombinant AMPK compared to smMLCK, whereas with rat liver AMPK significant phosphorylation was seen. In Madin-Darby Canine Kidney cells, AMPK activation led to an increase in MLC phosphorylation, which was decreased by a Rho kinase inhibitor without affecting AMPK activation. Therefore, MLC phosphorylation during energy deprivation does not result from direct phosphorylation by AMPK.

Structured summary

MINT-6800264: smMLCK (uniprotkb:P11799) phosphorylates (MI:0217) MLC (uniprotkb:P08590) by protein kinase assay (MI:0424)

MINT-6800252: AMPK (uniprotkb:Q13131) phosphorylates (MI:0217) ACC2 (uniprotkb:000763) by protein kinase assay (MI:0424)

     

G proteins mediate changes in cell shape by stabilizing the axis of polarity

Upon exposure to mating pheromone, yeast cells change their form to pear-shaped shmoos. We looked at pheromone-dependent cell shape changes in mutants that are unable to orient growth during mating and unable to choose a bud site. In these double mutants, cell surface growth, secretion sites, cytoskeleton, and pheromone receptors are spread out, explaining why these cells are round. In contrast, polarity establishment proteins localize to discrete sites in these mutants. However, the location of these sites wanders. Thus, these mutants are able to initiate polarized growth but fail to maintain the location of growth sites. Our results demonstrate that stabilization of the growth axis requires positional signaling from either the pheromone receptor or specific bud site selection proteins.