[Involvement of phosphatidylinositol-4,5-bisphosphate binding proteins in the generation of contractile oscillations in the Physarum polycephalum plasmodium].

Using the Physarum polycephalum, plasmodium, a giant amoeboid cell with the strongly pronounced auto-oscillatory mode of motility, which exhibits regularities of motile behavior common with those of tissue cells and has the same signal systems, the possibility of the participation of phosphatidylinositol-4,5-bisphosphate in the regulation of the contractile activity has been studied. The effect of neomycin as a substrate inhibitor of phospholipase C, which binds with high affinity to phosphatidylinositol-4,5-bisphosphate in the membrane, on force oscillations generated by plasmodial strands under isometric conditions and after the addition of the protein kinase C inhibitors staurosporine, UCN-01, and Ro-318220, separatelyand in combination with the calmodulin inhibitor calmidazolium has been examined. It has been shown that neomycin at pH 7.0 and concentrations of 0.1-5.0 mM stops contractile oscillations for 10-30 min but then they begin to gradually restore; the oscillation period at the initial stage of the restoration is.shorter than it was earlier and then increases due to the elongation of the contraction phase. Analysis of data obtained is in favor of the assumption that the plasmodial membrane contains MARCKS-like proteins and protein kinase C-controlled pools of phosphatidylinositol-4,5-bisphosphate, which can participate in the generation of auto-oscillations observed in the plasmodium.

[Involvement of cyclic adenosine monophosphate in the control of motile behavior of Physarum polycephalum plasmodium].

Possible involvement of autocrine factors into the control of motile behavior via a receptor-mediated mechanism was investigated in Physarum polycephalum plasmodium, a multinuclear amoeboid cell with the auto-oscillatory mode of motility. Cyclic adenosine monophosphate (cAMP) and extracellular cAMP-specific phosphodiesterase, its involvement into the control of plasmodium motile behavior was proved by action of its strong inhibitor, were regarded as putative autocrine factors. It was shown that the plasmodium secreted cAMP. When it was introduced into agar support, 0,1-1 mM cAMP induced a delay of the plasmodium spreading and its transition to migration. When locally applied, cAMP at the same concentrations induced typical for attractant action the increase in oscillation frequency and the decrease of ectoplasm elasticity. The ability to exhibit positive chemotaxis in cAMP gradient and the dependence of its realization were shown to depend on the plasmodium state. Chemotaxis test specimens obtained from the migrating plasmodium, unlike those obtained from growing culture, generate alternative fronts which compete effectively with fronts oriented towards the attractant increment. The results obtained support our supposition stated earlier that advance of the Physarum polycephalum plasmodium leading edge is determined by local extracellular cAMP gradients arising from a time delay between secretion and hydrolysis of the nucleotide.

[Involvement of extracellular cAMP-specific phosphodiesterase in control of motile activity of Physarum polycephalum plasmodium].

Possible involvement of extracellular cAMP-specific phosphodiesterase in the control of cell motile behavior has been investigated in Physarum polycephalum plasmodium, a multinuclear amoeboid cell with the autooscillatory mode of motility. It was found that the rate of the hydrolysis of 10 mM cAMP by a partially purified preparation of cAMP-specific phosphodiesterase secreted by the plasmodium in the course of migration decreases 20-30 times under the action of 1 mM dithiothreitol. In the presence of 1-5 mM of this strong reducing agent, the onset of the plasmodium spreading and the transition to the stage of migration were delayed in a concentration-dependent manner. In accordance with the morphological pattern of motile behavior, the duration of the maintenance of high frequency autooscillations, which normally precede the increase in the rate of the spreading and appear also in response to the application of attractants at spatially uniform concentrations, strongly increased by the action of dithiothreitol. The results obtained suggest that the autocrine production of cAMP and extracellular cAMP-specific phosphodiesterase is an important constituent of the mechanism controlling the motile behavior of the Physarum polycephalum plasmodium.

[Cytomechanics of oscillatory contractions. Modeling the longitudinal dynamics of Physarum polycephalum protoplasmic strands].

A mathematical model of the longitudinal dynamics of an isolated strand of the Physarum polycephalum plasmodium has been constructed. Its contractile system is considered as a continual viscoelastic medium with passive and active components. The mathematical description of the longitudinal dynamics of the plasmodial strand is reduced to a system of three first-order differential equations, whose variables are its active stress, deformation, and the intracellular concentration of calcium ions. The model is based on the hypothesis that there exists a feedback loop, which appears because of the influence of strand stretching on the rate of the release of calcium ions, which in turn controls the active contraction and deformation of the strand. Nonlinear interactions between the variables evoke a loss of the stationary state stability and a self-excitation of mechanochemical autooscillations when the external load exceeds some critical value. The results of numerical solutions of the model with the empirically determined viscoelastic parameters are in good agreement with the available experimental data and testify to the adequacy of the description of strand dynamics by the mathematical model in which the contractile apparatus is a part of the cellular control system. In particular, this model well simulates the form and duration of transient mechanochemical processes observed under isotonic and isometric conditions immediately after strand isolation, as well as the subsequent excitation of autooscillations of the contractile activity and their activation by strand stretching.

[Cytomechanics of oscillatory contractions. Measurement of active mechanical properties of Physarum polycephalum plasmodium strands].

The aim of this series of studies is to elucidate the role of mechanical stresses in the processes of cell activation. The experiments were done with a huge unicellular organism, the Physarum polycephalum plasmodium, which is a classical object in studies of the nonmuscle motility. The contractile properties of this amoeboid cell were investigated with the help of an inexpensive electronic-mechanical measuring system. A short description of this device is presented, which allows one to maintain a given kinetics of either the length or the load of the object and to measure either its tension force or deformation, respectively, as a response. Some examples of the longitudinal dynamics of the plasmodial strand and its activation under periodic switching of regimes of measurement in certain phases of the contraction-relaxation cycle are shown.

[The role of phosphoinositide-3-kinase in controlling the shape and directional movement in Physarum polycephalum plasmodium].

The influence of wortmannin and LY294002, specific inhibitors of phosphoinosite-3-kinase, on the shape, motile behavior, and chemotaxis toward glucose has been investigated in Physarum polycephalum plasmodium, a multinuclear amoeboid cell with the autooscillatory mode of motion. Both inhibitors were shown to cause a reduction of the plasmodium frontal edge and a decrease in the efficiency of mass transfer during migration. They also suppress chemotaxis toward glucose and eliminate characteristic changes in autooscillatory behavior normally observed in response to the treatment of the whole plasmodium with glucose. The manifestation of these effects depends on the inhibitor concentration, the duration of treatment, and the size of plasmodium. The involvement of phosphoinosite-3-kinase in creating the frontal edge and in controlling the chemotaxis of Physarum plasmodium suggests that the interrelation of polar shape and directional movement of amoeboid cells with the distribution of phosphoinositides in the plasma membrane has the universal nature.

[Synchronization of mechanochemical auto-oscillations within the Physarum polycephalum plasmodium by periodical external actions].

Amoeboid locomotion of huge unicellular organism, the Physarum polycephalum plasmodium, is stipulated by endoplasmic flow, which is produced by spatially highly coordinated rhythmic contractions of the ectoplasm. To describe the self-organization of the plasmodial contractile activity, we proposed a mathematical model, which is based on the hypothesis of positive feedback between the deformation of the cytoskeleton and release of a chemical regulator of the active contraction. A nonautonomous analogue of this model was used to study the synchronization of mechanochemical auto-oscillations by periodic gradient of the external pressure. Numerical computations of the system of differential equations obtained revealed a dependency of the synchronization band on the amplitude of the external pressure oscillations. On the basis of this dependence and experimental data on the band of synchronization of the shuttle endoplasmic flow by the periodic gradient of temperature obtained with the help of the laser Doppler anemometer, relative efficiency of external synchronizing action of temperature and pressure was evaluated.

A continuum model of contraction waves and protoplasm streaming in strands of Physarum plasmodium.

We present a mathematical model for continuously distributed mechanochemical autooscillations (autowaves) in a protoplasmic strand of Physarum polycephalum. The model is based on a hypothesis of local positive feedback between deformation and contraction of the contractile apparatus. This feedback is mediated through a cell regulatory system whose kinetics involves coupling to mechanical strain. Mathematical analysis and computer simulations have demonstrated that the solutions of the model agree quantitatively with the available experimental data. In particular, hydrodynamic interaction alone, between different sections of the strand via the streaming endoplasm, is capable of inducing the characteristic contractile behavior.