Involvement of extracellular cAMP-specific phosphodiesterase in the control of motile activity of <Emphasis Type="Italic">Physarum polycephalum</Emphasis> 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.     

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.     

The role of phosphoinositide-3-kinase in the control of shape and directional movement of the Physarum polycephalum plasmodium

The effects of wortmannin and LY294002, specific inhibitors of phosphoinositide-3-kinase, on the shape, locomotive behavior, and glucose chemotaxis were studied using the Physarum polycephalum plasmodium, a multinuclear amoeboid cell with the self-oscillatory mode of locomotive behavior. Both inhibitors were shown to cause a reduction in the plasmodium frontal edge and a decrease in the efficiency of mass transfer during migration. They also suppressed the chemotaxis towards glucose and eliminated the characteristic changes in self-oscillatory behavior normally observed in response to the treatment of the whole plasmodium with glucose. The manifestation of these effects depended on the inhibitor concentration, treatment duration, and size of plasmodium. The involvement of phosphoinositide-3-kinase in formation of the frontal edge and control of P. polycephalum plasmodium chemotaxis suggests that the correlation of polar shape and directional movement of amoeboid cells with the distribution of phosphoinositides in the plasma membrane has a universal nature.     

A model of network formation by Physarum plasmodium: Interplay between cell mobility and morphogenesis

The plasmodium of Physarum polycephalum has attracted much attention due its intelligent adaptive behavior. In this study, we constructed a model of the organism and attempted to simulate its locomotion and morphogenetic behavior. By modifying our previous model, we were able to get closer to the actual behavior. We also compared the behavior of the model with that of the real organism, demonstrating remarkable similarity between the two.     

Coupling of phospholipase C and PI3K/PTEN signaling pathways in <Emphasis Type="Italic">Physarum polycephalum</Emphasis>: The action of U73122 on motile and autooscillatory activity of plasmodium

The possibility of tight coupling of phospholipase C with the signal pathway PI3K/ PTEN, a ubiquitous mechanism for the control of chemotaxis and cell shape in free-living amoebae and mammalian tissue cells, has been investigated in Physarum polycephalum plasmodium, a multinuclear amoeboid cell with the autooscillatory mode of motility. It was found that on the maintenance of contractile autooscillations and protoplasmic shuttle streaming, U73122, an inhibitor of the signal transduction to phospholipase C, induces degradation of the plasmodium frontal zone, decreases efficiency of locomotion and suppresses the chemotaxis toward glucose as well as the response of oscillator to this attractant. The identity of the effects of U73122 with those shown for wortmannin and LY294002, widely used PI3K inhibitors (Matveeva et al. 2008. Biophysics. 53, 533–538), suggests a tight coupling of the signal pathways of phospholipase C and PI3K/PTEN. U73122 increases the period of contractile oscillations and abolishes its cyclic changes attributed for the plasmodium migration. The results indicate that motile behavior of the plasmodium is under the receptor-mediated control.     

Studies on the velocity distribution of the protoplasmic streaming in the myxomycete plasmodium

Summary It was shown that the velocity distribution of the intracapillary streaming of protoplasm in a plasmodium ofPhysarum polycephalum is the same no matter whether the flow is spontaneous or whether it is induced artificially by external local air pressure applied to the plasmodium. Thus we conclude that the protoplasmic flow in the plasmodium is caused by local difference in endoplasm pressure. The view that the seat of the motive force responsible for the flow is located in the streaming protoplasm itself is untenable for this type of streaming.     

Thermostable extracellular cyclic nucleotide phosphodiesterase of the Physarum polycephalum plasmodium

Cyclic nucleotide phosphodiesterase secreted by the Physarum polycephalum plasmodium was partially purified by ion-exchange chromatography on DEAE cellulose, ultrafiltration, and HPLC. The data obtained by gel filtration, HPLC, electrophoresis, and isoelectric focusing showed that the active enzyme in solution exists as a monomer of about 90 kDa with pI 3.6–4.0. The K _m values were 0.9 and 7.7 mM for cAMP and cGMP, respectively, whereas the maximal rates of hydrolysis of these nucleotides were virtually equal and reached several millimoles of hydrolyzed cyclic nucleotide per hour per milligram of enzyme. The partially purified enzyme was highly stable. It was not inactivated by heating at 100°C for 30 min. The enzyme remained active in the presence of 1% sodium dodecyl sulfate; however, it was completely inactivated under these conditions in the presence of β-mercaptoethanol.     

Physarum polymalic acid hydrolase: Recombinant expression and enzyme activation

As a platform for syntheses of nanoconjugates in antitumor drug delivery, polymalic acid together with its tailoring specific exohydrolase is purified from plasmodium cultures of the slime mold Physarum polycephalum, a member of the phylum myxomycota. Polymalic acid hydrolase is expressed in an inactive form that functions as a molecular adapter for polymalic acid trafficking within the plasmodium and is activated only during secretion. Activation follows specific protein tyrosine phosphorylation and dissociation from plasma membranes. Purified inactive Physarum polymalic acid hydrolase, recombinantly expressed in yeast Saccharomyces, is activated on a preparative basis by the addition of plasma membrane fragments from plasmodia of P. polycephalum. Activation of polymalic acid hydrolase and inhibition of polymalic acid synthesis by protein tyrosine phosphorylation are complementary events and could indicate a joint signal response to plasma membrane damage.     

Morphogenesis and alpha-tubulin gene of plasmodium in Didymium megalosporum

The morphogenesis of plasmodium in Didymium megalosporum was observed for the first time by hanging drop culture and 3 % oat-agar culture under controlled conditions. The development of plasmodium was characteristic formation process of phaneroplasmodium. The mature plasmodium was white yellow or yellow green in color, and had an extending fan-like sheet at the front, followed by a network of veins. It could be easy to fuse into a bigger plasmodium during the formation and die at high temperature or starvation. In view of the important role of alpha-tubulin during the morphogenesis of plasmodium, we sequenced partial sequence of alpha-tubulin gene, a total length of 1,159 bp, in this plasmodium. It had an intron area from 177 to 235 bp, and the exon area had a similarity of 91 % relative to altA locus of alpha-tubulin gene in Physarum polycephalum, the translated amino acid sequence was identical (100 % match) between the two.     

Multiple Alleles and Other Factors Affecting Plasmodium Formation in the True Slime Mold Physarum polycephalum Schw*

SYNOPSIS. The life cycle of the true slime mold Physarum polycephalum includes 2 vegetative stages: the multinucleate coenocytic plasmodium and the uninucleate amoeba. A clone of amoebae established from a single spore does not normally yield plasmodia. Plasmodia are formed when amoebae from particular clones are mixed; thus plasmodium formation is said to be controlled by a ‘mating-type’ system. Previous work by the author with a sample of P. polycephalum derived from a single source revealed that 2 mating types were present and were determined by a pair of alleles at 1 locus. The present paper reveals the presence of 2 more mating types in a sample of P. polycephalum derived from a different source and provides evidence that these are determined by 2 alleles at the same locus as the other 2. Evidence for the presence of other inherited factors affecting plasmodium formation, the mode of action of these factors and possible explanations for the occurrence of plasmodia in single-spore cultures are also discussed.     

Controlling the geometry and the coupling strength of the oscillator system in plasmodium ofPhysarum polycephalum by microfabricated structure

Summary The plasmodium of the true slime moldPhysarum polycephalum, which shows various oscillatory phenomena, can be regarded as a collective of nonlinear oscillators. Partial bodies in the plasmodium, which are assumed to be nonlinear oscillators, are mutually connected by microscale tubes named plasmodial strand. The interactions among the oscillators can be strongly affected by the geometry and the dimension of the tube network. Investigation of the collective behavior under the condition that the configuration of the network can be manipulated gives significant information on the characteristics of the plasmodium from the viewpoint of nonlinear dynamics. In this study, we have developed a new method to control the geometry and the tube dimension of the plasmodium with a microfabricated structure. It is shown that the geometry of the plasmodium can be manipulated with a microstructure which is fabricated of ultrathick photoresist resin by photolithographic processes. In order to confirm that not only the geometry but also the dimension of the tubes can be controlled with the microstructure, we observed the cross section of the patterned plasmodium with a three-dimensional internal-structure microscope. By observing the oscillatory behavior of the partial bodies of the patterned plasmodium, it was confirmed that the coupling strength between two oscillators, which corresponds to the dimension of the plasmodial strand, can be controlled by the microstructure. It is concluded that the present method is suitable for further studies of the network of Physarum plasmodium as a collective nonlinear oscillator system.     

Cytomechanics of oscillatory contractions. 1. Measuring active mechanical properties of the <Emphasis Type="Italic">Physarum polycephalum</Emphasis> plasmodial strands

An experimental device with an inexpensive electronic-mechanical measurement system was designed to clarify the role of mechanical tensions in cell activation. This device provides for maintaining a specified kinetics of either the object’s length or applied load to measure its tension force or deformation. The experiments were performed with the plasmodium of Physarum polycephalum, a giant unicellular organism, which is a classical object for studying a nonmuscle motility. Several examples of the longitudinal dynamics of the plasmodial strand and its activation in response to periodic switching at certain phases of the contraction- relaxation cycle are described.     

Bidirectional flow of endoplasm inPhysarum plasmodium under centrifugal acceleration

Summary The behavior of cytoplasmic streaming in plasmodial strand ofPhysarum polycephalum was studied under centrifugal acceleration using a centrifuge microscope of the stroboscopic type. Cytoplasmic streaming in the plasmodium was greatly affected by changes in the acceleration. The endoplasmic flow in the centrifugal direction was accelerated, while that in the centripetal was retarded, by centrifugal acceleration. The centrifugal acceleration required to stop the endoplasmic flow in the centripetal direction did not cause total cessation of streaming but always induced a bidirectional flow of endoplasm in one and the same strand. Each profile of velocity distribution of the bidirectional flow was both parabola with flattened apex. One possible cause of the bidirectional flow is discussed.Dedicated to Emeritus Professor Noburo Kamiya on the occasion of his 80th birthday     

Cognition of different length by Physarum polycephalum: Weber's law in an amoeboid organism

A true slime mold, the plasmodium of Physarum polycephalum has the ability to find the shortest route between two points in a labyrinth. To find the shortest route between two points, detection of the difference in lengths can be made from two aspects: the absolute difference between the lengths or the ratio of them. We found that the ratio of two lengths, rather than the absolute difference between the two lengths, was important in discriminating the difference in the two lengths by P. polycephalum. This finding indicates that an amoeboid organism detects differences in stimulus intensity as though it is constrained by Weber's law, suggesting that Weber's law is not reliant on the presence of a neural system and is used widely even in Amoebozoa.     

First report of sporangia of a myxomycete (Physarum pusillum) on the body of a living animal, the lizard Corytophanes cristatus

Myxomycetes are protists whose life cycle depends on aerially dispersed spores that germinate into motile myxamoebae, which then pair and fuse to form a larger, motile plasmodium. The plasmodium seeks out a suitable fruiting site (usually atop vegetative material or detritus) and transforms into fruiting bodies that release the spores. In this paper we report the first known instance of a myxomycete, in this case Physarum pusillum, sporulating on the body of a living animal, the cryptic lizard Corytophanes cristatus, which was collected in eastern Honduras in 2003.     

Non-transfer of materials between plasmodia of different species of myxomycetes

Summary Under the experimental conditions of this study no transfer of radiophosphorus occurred from one living plasmodium to another when a radioactive plasmodium ofPhysarum polycephalum and a non-radioactive plasmodium ofPhysarum gyrosum orFuligo septica were in intimate contact for 24 hours.This research constitutes a part of a program Experimental Approach to the Taxonomy of the Myxomycetes, supported by National Science Foundation Grant G-6382.     

Information processing for the organization of chemotactic behavior ofPhysarum polycephalum studied by micro-thermography

Summary The spatial and temporal pattern of oscillating temperatures on the cell surface of a plasmodial strand ofPhysarum polycephalum was measured with a sensitive thermal image camera. The longitudinal tension of the strand was studied simultaneously. In the absence of chemical stimulation, the phases of the temperature oscillation observed at various portions of the strand were entrained with almost coincidental phase. The temperature and tension oscillation were synchronized, although the phase difference between them was occasionally changed. With local chemical stimulation, the phase of the temperature oscillation advanced in the portion to which the plasmodium would be induced to migrate. The phases between temperature and tension oscillations then became constant. The mechanism by which the plasmodium processes local information of chemical stimulus to global information for the migration is discussed.     

Electron microscopy of the slime moldPhysarum polycephalum

Summary Electron micrographs of fixed sections of the plasmodium of the classic protoplasmic material,Physarum polycephalum, are presented. Numerous round nuclei having well-defined membranes and containing one to three dense nucleoli were especially prominent in the plasmodium. In the surrounding cytoplasm, many irregular membrane-limited bodies were evident, some containing tiny rod-like elements and others with inner structures resembling mitochondria. In addition, there can be seen many small dense granules plus various vacuoles and other inclusions.     

Environment-dependent morphology in plasmodium of true slime mold Physarum polycephalum and a network growth model

Branching network growth patterns, depending on environmental conditions, in plasmodium of true slime mold Physarum polycephalum were investigated. Surprisingly, the patterns resemble those in bacterial colonies even though the biological mechanisms differ greatly. Bacterial colonies are collectives of microorganisms in which individual organisms have motility and interact through nutritious and chemical fields. In contrast, the plasmodium is a giant amoeba-like multinucleated unicellular organism that forms a network of tubular structures through which protoplasm streams. The cell motility of the plasmodium is generated by oscillation phenomena observed in the partial bodies, which interact through the tubular structures. First, we analyze characteristics of the morphology quantitatively, then we abstract local rules governing the growing process to construct a simple network growth model. This model is independent of specific systems, in which only two rules are applied. Finally, we discuss the mechanism of commonly observed biological pattern formations through comparison with the system of bacterial colonies.