THE CHANGING PATTERN OF BIREFRINGENCE IN PLASMODIA OF THE SLIME MOLD, PHYSARUM POLYCEPHALUM

Plasmodia of the acellular slime mold, Physarum polycephalum, reveal a complex and changing pattern of birefringence when examined with a sensitive polarizing microscope. Positively birefringent fibrils are found throughout the ectoplasmic region of the plasmodium. In the larger strands they may be oriented parallel to the strand axis, or arranged circularly or spirally along the periphery of endoplasmic channels. Some fibrils exist for only a few minutes, others for a longer period. Some, particularly the circular fibrils, undergo changes in birefringence as they undergo cyclic deformations. In the ramifying strand region and the advancing margin there is a tendency for fibrils of various sizes to become organized into mutually orthogonal arrays. In some plasmodia the channel wall material immediately adjacent to the endoplasm has been found to be birefringent. The sign of endoplasmic birefringence is negative, and its magnitude is apparently constant over the streaming cycle. The pattern of plasmodial birefringence and its changes during the shuttle streaming cycle of Physarum are considered in the light of several models designed to explain either cytoplasmic streaming alone or the entire gamut of plasmodial motions. The results of this and other recent physical studies suggest that both streaming and the various other motions of the plasmodium may very likely be explained in terms of coordinated contractions taking place in the fibrils which are rendered visible in polarized light.     

Dynamics of the contractile system in the pseudopodial tips of normally locomoting amoebae,demonstrated in vivo by video-enhancement

Summary Behaviour of the membrane and contractile system was directly recorded in the advancing and retracting frontal zones of spontaneously locomoting or stimulated amoebae. The advancing pseudopodial tips alternately slow down and accelerate. In the slowing phase the frontal hyaline caps are flat and compressed by countercontraction of the cortical actin network beneath the leading edge. At this stage the membrane-cytoskeleton complex splits: the detached contractile layer is retracted inwards, and the membrane lifted outwards. The fluid endoplasm fraction is filtered forward through the detached actin network. This results in a local hydrostatic pressure drop, immediately restores the forward flow of endoplasm and initiates the acceleration phase of the leading edge progression. The frontal membrane, temporarily disconnected from the cytoskeletal layer, is free to slide and extend forward, but the new submembrane contractile network is soon repolymerized. In this way, after making one step forward, the frontal zone recovers its former state, and the cycle is then repeated. The cortex disassembly-reassembly cycles at the leading edge are produced every 2 s, on average. Retraction of the frontal contractile layers is part of the general centripetal cortex flow observed during motor functions of amoebae and many other cells, and is therefore associated with various other backward movements observed within and on the surface of advancing frontal zones of amoebae. The backward movement of the contractile cortex is also responsible for the withdrawal of previously advancing pseudopodia, if the detachment of successive contractile sheets from the frontal membrane ceases. It was demonstrated that the action of attractants and repellents is based on the activation or inhibition, respectively, of rhythmic disassembly of the membrane-cytoskeleton complex at the leading edge.     

The contractile basis of amoeboid movement : IV. The viscoelasticity and contractility of amoeba cytoplasm in vivo

The viscoelasticity and contractility of amoeba cytoplasm has been studied in vivo and in vitro. A gradient of increasing viscoelasticity and contractility was identified in the endoplasm of intact cells from the uroid (tail) to the fountain zone (tip of advancing pseudopod). Anterior endoplasm, as well as all of the ectoplasm, contracted in response to the microinjection of a threshold calcium ion concentration (ca 7.0 × 10⁻⁷ M). In contrast, there were only delayed weak contractions in the uroid endoplasm upon the microinjection of a threshold calcium ion concentration. Contractions induced in the ectoplasm by microinjecting the contraction solution readily caused the endoplasm to stream. However, the endoplasm at the tips of the extending pseudopods were also contractile and transmitted applied tensions. Furthermore, the microinjection of subthreshold calcium ion concentrations caused the loss of distinct endoplasmic structure and the cessation of streaming in both the uroid and the anterior third of the cell. In addition, the relationship between contractility and cytoplasmic streaming was characterized in “relaxed” cytoplasm placed in a gradient of calcium ion concentration inside quartz capillaries. The results of these experiments demonstrated that the mechanochemical conversion of endoplasm to ectoplasm caused the cytoplasm to become more structured and contractile. Therefore, physiological contractions are possible during and after the conversion of endoplasm to ectoplasm.     

Studies on contraction rhythm of the plasmodial strand IV. Site of active oscillation in an advancing plasmodium

Summary From the anterior region of an advancingPhysarum plasmodium, a slender rectangular piece of cytoplasmic gel was removed and its contractile properties were compared with those of a strand segment isolated from the network region of the same plasmodium. The anterior piece, in spite of injury caused by the surgical operation, began to contract and relax periodically without an appreciable lag stage after it had been excised. The segment of strand (vein) obtained from the network behind the advancing front showed no significant rhythm immediately after it had been isolated. Only after a lag period lasting for 10–20 minutes (stage I.Yoshimoto andKamiya 1978 a) did the strand gradually begin to oscillate under both isometric and isotonic conditions. Such behaviour of the isolated strand is interpreted as showing that the active site of the rhythmic contraction and relaxation in the advancing plasmodium is restricted to its anterior zone and the rear network structure plays no leading part in bringing about rhythmicity when it isin situ. Rhythmicity of a strand segment excised from the plasmodial network occurs only after it has been isolated as an independent system. Whether or not the strand is under tension is not important for this functional reorganization.The present work was supported in part by grants-in-aid from the Mitsubishi Foundation and the Japanese Ministry of Education, Science, and Culture.     

A new myxosporean,Zschokkella leptatherinae n. sp. (Myxozoa: Myxidiidae), from the hepatic ducts and gall-bladder of Australian marine fishes

A new myxosporean,Zschokkella leptatherinae n. sp., was found in the hepatic ducts and gall bladder of five atherinid fish species,Leptatherina presbyteroides, Atherinosoma microstoma, Kestratherina brevirostris, K. esox andK. hepsetoides, collected at Dru Point, Margate in south-eastern Tasmania, Australia. This species has a round, ellipsoid or irregular plasmodium. The plasmodium is enclosed by a surface membrane and the cytoplasm is composed of an outer homogeneous ectoplasm and an inner coarse endoplasm with large clear areas, numerous vacuoles and spores which differentiate in the central area of the endoplasm. The characteristic metrical data of the myxosporean are as follows: spores 15.3 × 11.8 m; polar capsules 3.9 × 3.4 m. This is the thirdZschokkella species reported from Australia.     

Co-variations and clustering of chronic disease behavioral risk factors in China: China Chronic Disease and Risk Factor Surveillance, 2007

Background

Chronic diseases have become the leading causes of mortality in China and related behavioral risk factors (BRFs) changed dramatically in past decades. We aimed to examine the prevalence, co-variations, clustering and the independent correlates of five BRFs at the national level.

Methodology/Principal Findings

We used data from the 2007 China Chronic Disease and Risk Factor Surveillance, in which multistage clustering sampling was adopted to collect a nationally representative sample of 49,247 Chinese aged 15 to 69 years. We estimated the prevalence and clustering (mean number of BRFs) of five BRFs: tobacco use, excessive alcohol drinking, insufficient intake of vegetable and fruit, physical inactivity, and overweight or obesity. We conducted binary logistic regression models to examine the co-variations among five BRFs with adjustment of demographic and socioeconomic factors, chronic conditions and other BRFs. Ordinal logistic regression was constructed to investigate the independent associations between each covariate and the clustering of BRFs within individuals. Overall, 57.0% of Chinese population had at least two BRFs and the mean number of BRFs is 1.80 (95% confidence interval: 1.78–1.83). Eight of the ten pairs of bivariate associations between the five BRFs were found statistically significant. Chinese with older age, being a male, living in rural areas, having lower education level and lower yearly household income experienced increased likelihood of having more BRFs.

Conclusions/Significance

Current BRFs place the majority of Chinese aged 15 to 69 years at risk for the future development of chronic disease, which calls for urgent public health programs to reduce these risk factors. Prominent correlations between BRFs imply that a combined package of interventions targeting multiple BRFs might be appropriate. These interventions should target elder population, men, and rural residents, especially those with lower SES.     

Internal Water Distribution and Cytoplasmic Streaming in Physarum polycephalum

A fungal vacuolation factor causes vacuolation when appliedto the plasmodium ofP. polycephalum, and also results in negativechemotaxis of the plasmodium. This, and the relationship betweenthe normal distribution of vacuoles in the plasmodium and itsdirection of locomotion, suggests that a similar factor maybe operative in determining polarity. A vacuolation factor hasbeen extracted from P. polycephalum. A vacuolar-reticular system in the cytoplasm shows a cycle ofcontractions and expansions that, in the advancing lobe at least,is usually in phase with the oscillating streaming pattern ofthe plasmodium in that region. The possible significance ofthese findings for the mechanism of streaming is discussed.     

Relationship between endoplasmic and ectoplasmic oscillations during chemotaxis ofPhysarum polycephalum

Summary The plasmodium ofPhysarum polycephalum usually migrates coordinately as one whole body even in a complicated environment. By measuring oscillation phenomena in endoplasm and ectoplasm separately during chemotactic process, we studied the mechanism of information processing to achieve such a coordination. (1) The interaction between endoplasmic oscillators was long-range, competitive according to the length of period, and fast (18 cm/min). Ectoplasmic one was short-range. (2) After a partial stimulation of attractant to the organism, the period at the stimulated portion decreased first, and a global phase gradient appeared in endoplasm. Then ectoplasm at the non-stimulated portion was entrained to the endoplasmic pattern, and the migration direction at each part changed in accordance with the phase gradient as a whole body. (3) When the endoplasmic interaction was interrupted, the above coordinated response was not observed. These facts suggest that two-layer coupled oscillator system composed of endoplasm and ectoplasm play important roles for such an information integration.     

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.     

Differential treatment ofAcetabularia with cytochalasin B and N-Ethylmaleimide with special reference to their effects on cytoplasmic streaming

Summary Cytoplasmic streaming in the stalk ofAcetabularia, ryukyuensis at the vegetative stage was reversibly inhibited by cytochalasin B (cB) of 50 g/ml and irreversibly by N-Ethylmaleimide (NEM) above concentrations of 0.25 mM.After the endoplasm and the chloroplasts were pushed forward one end of the stalk by gentle centrifugation at about 500 × g for 3 minutes, numerous ectoplasmic striations remainedin situ in the stalk cortex. The striations ran in parallel with the longitudinal axis of the stalk at unequal intervals. The endoplasm streamed back only along these striations.By combining centrifugation and a double chamber technique, the endoplasm and the cortex of the stalk were treated separately with CB or NEM. CB treatment of the cortex arrested streaming; when treatment was restricted to the endoplasm, streaming continued at an normal rate. NEM treatment restricted to the cortex permitted normal streaming rates. Treatment restricted to the moving endoplasm inhibited streaming.These results suggest that microfilaments and a moiety, possibly myosin, play an active role in the streaming. Microfilaments must reside in the cortex, especially in the ectoplasmic striations, while the putative myosin must reside in the moving endoplasm.     

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     

Immunocytochemistry of the acellular slime mold Physarum polycephalum. III. Distribution of myosin and the actin-modulating protein (fragmin) in sandwiched plasmodia

The acellular slime mold Physarum forms very thin plasmodia when sandwiched between two agar sheets. After extraction with glycerol-containing buffers, suitable objects for immunofluorescence microscopy are obtained, and an analysis of the cytoskeletal and contractile system of Physarum becomes possible. Plasmodia were stained with antibodies against myosin and fragmin, a protein factor involved in actin filament length regulation. The microanatomy and topography of cellular structures containing these proteins were investigated at the light and electron microscopic levels. The patterns obtained with the two antibodies are closely related to those obtained with actin antibody [25]. In both cases the complex system of cytoplasmic fibrils is stained selectively. The fibrils form a more or less regular network in the advancing front zone with the fibrils being interconnected by focal nodes. In the posterior region of the plasmodium, where endoplasmic pathways and protoplasmic veins are differentiated, larger fibrils are detected, running obliquely or longitudinally to the veins. With both antibodies the fluorescent pattern of the fibrils is continuous without indications of periodic interruptions or striations, which would be expected in the case of sarcomere-like subunits. With anti-myosin unstained patches are frequently seen at or close to the nodes of the fibrillar network in the anterior region. The small lobopodia, which are rich in actin, are apparently not stained by the myosin antibody, a result similar to the situation in "ruffling edges? of cultured vertebrate cells. Electron microscopic investigations of antibody-labeled fibrils in embedded and sectioned plasmodia allow the identification of antibody molecules at specific sites along the fibrils with a different distribution pattern for each of the two antibodies.     

Recurrent senescence in axenic cultures of Physarum polycephalum

When subcultures of the aux-2 and aux-4 strains of Physarum polycephalum, which had been grown for more than four years in axenic shake culture, were transferred to non-axenic surface culture they displayed progressively shorter lifespans (older axenic surface cultures yield shorter lived non-axenic cultures). Similar subcultures transferred to axenic agar medium also underwent senescent-like events. These subcultures, after a period of vigorous growth, displayed a slower growth rate, reduced cytoplasmic streaming, loss of yellow pigment, and eventually they fragmented into a number of small spherical structures with the concomitant lysis of most of the plasmodium. In non-axenic culture these structures quickly degenerated (and disappeared from the culture); however, in axenic culture they revived and after several days produced new vigorous plasmodia. Following a period of vigorous growth the plasmodium again underwent senescent-like events. This cycle of senescence and growth was repeated a number of times before death finally occurred.     

Dynamic aspects of the contractile system in Physarum plasmodium. III. Cyclic contraction-relaxation of the plasmodial fragment in accordance with the generation-degeneration of cytoplasmic actomyosin fibrils

Plasmodial fragments of Physarum polycephalum, excised from anterior regions of a thin-spread plasmodium, contracted-relaxed cyclicly with a period of 3-5 min. The area of the fragments decreased approximately 10% during contraction. In most cases, there was little endoplasmic streaming which indicates that contractions were synchronized throughout the fragment. By both polarized light and fluorescence microscopy, the organization and distribution of the cytoplasmic actomyosin fibrils in the fragments changed in synchrony with the contraction cycle. The fibrils formed during the contraction phase, and finally became a highly organized framework consisting of a three-dimensional network of numerous fibrils with many converging points (the nodes). During relaxation, the fibrils degenerated and disappeared almost completely, though some very weak fibrils remained near the nodes and the periphery. The results obtained by fluorometry of the fragments, stained with rhodamine-phalloidin, suggested that the G-F transformation of actin is not the main underlying process of the fibrillar formation.     

Hydrodynamic models of viscous coupling between motile myosin and endoplasm in characean algae

Cytoplasmic streaming in characean algae is thought to be driven by interaction between stationary subcortical actin bundles and motile endoplasmic myosin. Implicit in this mechanism is a requirement for some form of coupling to transfer motive force from the moving myosin to the endoplasm. Three models of viscous coupling between myosin and endoplasm are presented here, and the hydrodynamic feasibility of each model is analyzed. The results show that individual myosinlike molecules moving along the actin bundles at reasonable velocities cannot exert enough viscous pull on the endoplasm to account for the observed streaming. Attachment of myosin to small spherical organelles improves viscous coupling to the endoplasm, but results for this model show that streaming can be generated only if the myosin-spheres move along the actin bundles in a virtual solid line at about twice the streaming velocity. In the third model, myosin is incorporated into a fibrous or membranous network or gel extending into the endoplasm. This network is pulled forward as the attached myosin slides along the actin bundles. Using network dimensions estimated from published micrographs of characean endoplasm, the results show that this system can easily generate the observed cytoplasmic streaming.     

NAD(P)H oscillation in relation to the rhythmic contraction in thePhysarum plasmodium

Summary ThePhysarum plasmodium shows rhythmic contractile activities with a period of a few min. Phases of the oscillation in the plasmodium migrating unindirectionally agreed sideways throughout at the frontal part. So, time course of an intracellular chemical component was determined by analyzing small pieces cut off successively from the frontal part of the large plasmodium. Intracellular NAD(P)H concentration oscillated with the same period as the rhythmic contraction but with a different phase advancing about 1/3 of the period. UV irradiation suppressed the rhythmic contraction without affecting the rhythmic variation of NAD(P)H. Thus, the NAD(P)H oscillator works independently of the rhythmic contractile system, but seems entraining with each other.Abbreviations UV ultraviolet - NADH nicotinamide adenine dinucleotide, reduced form - NADPH nicotinamide adenine dinucleotide phosphate, reduced form - ATP adenosine 5-triphosphate - cAMP cyclic adenosine 3, 5-monophosphate - FMNH₂ flavin mononucleotide, reduced form - TCA tricarboxylic acid - BSA bovine serum albumin - DTT dithiothreitol     

Regulation of myosin sliding alongChara actin bundles by native skeletal muscle tropomyosin

Summary Native tropomyosin from rabbit skeletal muscle introduced by intracellular perfusion intoChara cells inhibited the cytoplasmic streaming irrespective of the Ca²⁺ concentration. To find the action site of native tropomyosin inChara, the cytoplasmic streaming was reconstituted by introducing isolated endoplasm into actin donorChara cells from which native endoplasm had been removed. The reconstituted streaming was inhibited by pretreatment of the actin donor cells with native tropomyosin but not by that of the endoplasm, suggesting that the native tropomyosin inhibited the cytoplasmic streaming by binding toChara actin bundles. Staining of the actin bundles with FITC-labeled native tropomyosin also showed that the native tropomyosin could bind to the actin bundles. Streaming reconstituted fromChara actin bundles and skeletal muscle myosin was insensitive to Ca²⁺, but became sensitive on application of the native tropomyosin.Abbrevations APW artificial pond water - ATP adenosine 5-triphosphoric acid - BSA bovine serum albumin - EDTA ethylene diamine tetraacetic acid - EGTA ethyleneglycol-bis-(-aminoethylether) N,N,N,N-tetraacetic acid - FITC fluorescein isothiocyanate - FITC-NTM fluorescein isothiocyanate-labeled native tropomyosin - NTM native tropomyosin     

Fine structural studies on the digestion of chloroplasts in the rumen ciliate Entodinium caudatum

The rumen ciliate Entodinium caudatum engulfed both native and glutaraldehyde-fixed chloroplasts, which were then usually found in vesicles located in the protozoal endoplasm. The native chloroplasts lost their characteristic morphological appearance in less than 5 min. The grana stacks disappeared and the thylakoid membranes were altered and appeared as many single rings or as concentric rings of membranous material resembling myelin figures. The membranes were shown to be of chloroplast rather than protozoal origin.     

Cytoplasmic streaming in giant algal cells: A historical survey of experimental approaches

Various methods have been used to study cytoplasmic streaming in giant algal cells during the past three decades. Simple techniques can be used with characean internodal cells to modify the cell constitution in various ways to gain insight into the mechanism of cytoplasmic streaming. Another method involves isolatingin vitro a huge drop of uninjured endoplasm, to examine its physical and dynamic properties. The motive force responsible for streaming has been measured by three different techniques with similar results. Subcortical fibrils consisting of bundles of F-actin with the same polarity are indispensable for streaming. Differential treatment of the endoplasm and ectoplasm has shown that putative characean myosin is localized in the endoplasm. Studies of the roles of ATP, Mg²⁺, Ca²⁺, H⁺ etc. in the streaming have been conducted by cellular perfusion, which allows removal of the tonoplast, or by techniques permeabilizing the protoplasmic membrane. A slow version of the movement can even be artificially reproduced by combining characean actinin situ and exogenous myosin in the presence of Mg-ATP. The findings thus far obtained support the hypothesis that cytoplasmic streaming in characean cells is caused by an active shearing force produced by interaction of the actin filament bundles on the cortex with myosin in the endoplasm.     

Ultrastructural studies on the sporulation of oocysts of Toxoplasma gondii. II. Formation of the sporocyst and structure of the sporocyst wall

The ultrastructural changes observed during sporocyst formation and the structure of the sporocyst wall was examined in oocysts which had been allowed to sporulate for between 12 and 48 hours at 27 degrees C. As the spherical sporoblast developed into the sporocyst the cytoplasmic mass became ellipsoidal in shape although no change was noted in the organelle compliment, which cosisted of two nuclei plus a number of polysaccharide granules, lipid globules, mitochondria, Golgi bodies, and some rough endoplasmic reticulum. The sporocyst wall consisted of a thin outer layer (15-20 nm) which was formed from two limiting membranes of the sporoblast and an inner layer (40-50 nm) which was comprised of four curved plates. This inner layer was formed under the outer layer and, although no specific cytoplasmic organelle disappeared with its formation, some unit membranes were observed close to the plasmalemma during its formation. Each curved plate has a marginal swelling and an interposing strip of material is present between the margins of adjacent plates. The plates are joined to the interposing strip by a thin band of osmiophilic material. In oblique and tangential sections through the plates two types of cross banding were observed which differed in periodicity.