Events in the amoebal-plasmodial transition ofPhysarum polycephalum studied by enrichment for committed cells

Summary Amoebae of strain CLof Physarum polycephalum undergo apogamic development to form multinucleate plasmodia. During the amoebalplasmodial transition, large uninucleate cells become irreversibly committed to plasmodium development. In developing cultures, amoebae lose the ability to flagellate before they become committed. Enriched suspensions of committed cells can be obtained by inducing asynchronous differentiating cultures to flagellate and passing the cells through a glass bead column. Committed cells can be cultured to form plasmodia on bacterial lawns or in axenic liquid medium but cannot be cultured on axenic agar medium. Uninucleate committed cells express tubulin isotypes characteristic of amoebae, but after culture in axenic liquid medium, the cells express plasmodial specific tubulin isotypes.Abbrevations SDM Semi-defined medium - DSDM Dilute semidefined medium - LIA Liver infusion agar - SBS Standard bacterial suspension - IEF Isoelectric focussing - SDS Sodium dodecyl sulphate - PAUF Precommitted amoebae unable to flagellate (for the explanation of these cells see text).     

Variable pathways for developmental changes of mitosis and cytokinesis in Physarum polycephalum

The development of a uninucleate ameba into a multinucleate, syncytial plasmodium in myxomycetes involves a change from the open, astral mitosis of the ameba to the intranuclear, anastral mitosis of the plasmodium, and the omission of cytokinesis from the cell cycle. We describe immunofluorescence microscopic studies of the amebal-plasmodial transition (APT) in Physarum polycephalum. We demonstrate that the reorganization of mitotic spindles commences in uninucleate cells after commitment to plasmodium formation, is completed by the binucleate stage, and occurs via different routes in individual developing cells. Most uninucleate developing cells formed mitotic spindles characteristic either of amebae or of plasmodia. However, chimeric mitotic figures exhibiting features of both amebal and plasmodial mitoses, and a novel star microtubular array were also observed. The loss of the ameba-specific alpha 3-tubulin and the accumulation of the plasmodium-specific beta 2-tubulin isotypes during development were not sufficient to explain the changes in the organization of mitotic spindles. The majority of uninucleate developing cells undergoing astral mitoses (amebal and chimeric) exhibited cytokinetic furrows, whereas cells with the anastral plasmodial mitosis exhibited no furrows. Thus, the transition from astral to anastral mitosis during the APT could be sufficient for the omission of cytokinesis from the cell cycle. However, astral mitosis may not ensure cytokinesis: some cells undergoing amebal or chimeric mitosis contained unilateral cytokinetic furrows or no furrow at all. These cells would, most probably, fail to divide. We suggest that a uninucleate committed cell undergoing amebal or chimeric mitosis can either divide or else form a binucleate cell. In contrast, a uninucleate cell with a mitotic spindle of the plasmodial type gives rise only to a binucleate cells. Further, the decision to enter mitosis after commitment to the APT is independent of the developmental changes in the organization of the mitotic spindle and cytokinesis.     

Mutations affecting the initiation of plasmodial development in Physarum polycephalum

In the heterothallic myxomycete Physarum polycephalum, uninucleate amoebae normally differentiate into syncytial plasmodia following heterotypic mating. In order to study the genetic control of this developmental process, mutations affecting the amoebal-plasmodial transition have been sought. Numerous mutants characterized by self-fertility have been isolated. The use of alkylating mutagens increases the mutant frequency over the spontaneous level but does not alter the mutant spectrum. Three spontaneous and 14 induced mutants have been analyzed genetically. In each, the mutation appears to be linked to the mating type locus. In three randomly selected mutants, the nuclear DNA content is the same in amoebae and plasmodia, indicating that amoebal syngamy does not precede plasmodium development in these strains. These results indicate that a highly specific type of mutational event, occurring close to or within the mating type locus, can abolish the requirement for syngamy normally associated with plasmodial differentiation. These mutations help define a genomic region regulating the switch from amoebal to plasmodial growth.     

A Comparative Study of Mitosis in Amoebae and Plasmodia of the True Slime Mold Didymium nigripes

SYNOPSIS. Studies comparing mitosis in amoebae and plasmodia of the true slime mold Didymium nigripes reveal that at the time of differentiation pronounced changes occur in the mitotic process. Not only does the amount of time required for division of the 2 stages differ, but plasmodial mitosis is characterized by persistence of the nuclear membrane and the apparent lack of centrioles. The origin of multinucleate plasmodia from uninucleate cells which have already undergone cytoplasmic differentiation is described. Division time in a population of amoebae becomes more uniform after those cells which are destined to form plasmodia have differentiated.
The observations and data presented indicated that differences in mitotic behavior also occur between amoebae of 3 stocks with differences in plasmodial structure and behavior. Comparison of mitosis in the plasmodia of these 3 stocks revealed no significant differences.     

Myosin switching during amoebo-plasmodial differentiation of slime mold, Physarum polycephalum

We reported previously that myosins from amoebal and plasmodial stages in the life cycle of Physarum polycephalum differ in the primary structure of heavy chains and phosphorylatable 18,000 Mr light chains, while Ca-binding 14,000 Mr light chains are common to both myosins (Kohama & Takano-Ohmuro, Proc Jpn acad 60B (1984) 431; Kohama et al., J biol chem 260 (1986) 8022). We have carried out immunofluorescence microscopical studies upon differentiating cultures of amoebic colonies, which show apogamic amoebo-plasmodial differentiation as follows: Typical amoebae differentiate into mono-nucleate intermediate cells with swollen nuclei and then into two or multi-nucleate young plasmodia (Anderson et al., Protoplasma 89 (1976) 29. Antibodies against plasmodial myosin heavy chain (PMHC) and 18,000 Mr plasmodial myosin light chain (PMLC18) stained intermediate cells and young plasmodia, but not typical amoebae. On the other hand, antibody against amoebal myosin heavy chain (AMHC) stained typical amoebae and intermediate cells--but not young plasmodia. Thus staining was detected using antibodies against both PMHC and AMHC in intermediate cells. Intermediate cells were also stained by antibody against another plasmodium-specific cytoskeletal protein, viz., high molecular weight actin-binding protein (HMWP). We propose that synthesis of myosin subunits switches immediately from amoebal to plasmodial type in mono-nucleate cells with swollen nuclei. This myosin switching is associated with the initiation of HMWP synthesis.     

Apogamic development of plasmodia in the myxomycetePhysarum polycephalum: a cinematographic analysis

Summary Strain CL ofPhysarum polycephalum forms multinucleate plasmodia within clones of uninucleate amoebae. The plasmodia have the same nuclear DNA content as the amoebae. Analysis of plasmodial development, using time-lapse cinematography, showed that binucleate cells were formed as a result of nuclear division in uninucleate cells. Binucleate cells developed into plasmodia by further nuclear divisions and cell fusions. No fusions involving uninucleate cells were observed. A temporary increase in cell and nuclear size occurred at the time of binucleate cell formation.     

Nuclear membrane behavior during mitosis in normal and heteroploid Myxomycetes

Summary Photomicrographic evidence is presented of the difference in behavior of nuclear membranes during mitosis in amoebae, zygotes and plasmodia of Myxomycetes. One of the species was cultured on bacteria and possessed a normal cycle of plasmogamy and karyogamy between the amoebal and plasmodial phases. The second species was axenically grown in liquid media and had become highly heteroploid and lacked the ability to develop into plasmodia, existing only in the amoeboid form. The significance of the amoeboid form of mitosis in the heteroploid axenically cultured strain is discussed in relation to the difference in nuclear membrane behavior and the possible significance of such behavior.     

Mating type and the differentiated state in Physarum polycephalum.

In the acellular slime mold, Physarum polycephalum, the differentiation of amoebae into plasmodia is controlled by a mating type locus, mt. Amoebae carrying heterothallic alleles usually do not differentiate within clones; plasmodia form when two amoebae carrying different alleles fuse and undergo karyogamy. In this paper, we show that amoebae heterozygous for heterothallic alleles can be isolated and maintained as amoebae; the amoebae form plasmodia in clones without a change in ploidy. Plasmodia were also found to be formed, infrequently, by heterothallic amoebae of a single mating type. The plasmodia are healthy and are also formed without a change in ploidy. Thus, the presence of two different heterothallic mating type genes in a single nucleus is compatible with the amoebal state and one heterothallic mating type gene is compatible with the plasmodial state, once established.     

A developmental mutation (npfL1) resulting in cell death in Physarum polycephalum.

In Physarum, microscopic uninucleate amoebae develop into macroscopic multinucleate plasmodia. In the mutant strain, RA614, plasmodium development is blocked. RA614 carries a recessive mutation (npfL1) in a gene that functions in sexual as well as apogamic development. In npfL+ apogamic development, binucleate cells arise from uninucleate cells by mitosis without cytokinesis at the end of an extended cell cycle. In npfL1 cultures, apogamic development became abnormal at the end of the extended cell cycle. The cells developed a characteristic rounded, vacuolated appearance, nuclear fusion and vigorous cytoplasmic motion occurred, and the cells eventually died. Nuclei were not visible by phase-contrast microscopy in most of the abnormally developing cells, but fluorescence microscopy after DAPI staining revealed intensely staining, condensed nuclei without nucleoli. Studies of tubulin organization during npfL1 development indicated a high frequency of abnormal mitotic spindles and, in some interphase cells, abnormally thick microtubules. Some of these features were observed at low frequency in the parental npfL+ strain and may represent a pathway of cell death, resembling apoptosis, that may be triggered in more than one way. Nuclear fusion occurred during interphase and mitosis in npfL1 cells, and multipolar spindles were also observed. None of these features were observed in npfL+ cells, suggesting that a specific effect of the npfL1 mutation may be an incomplete alteration of nuclear structure from the amoebal to the plasmodial state.     

Use of monoclonal antibodies to analyse the expression of a multi-tubulin family

We have used a panel of monoclonal antibodies in a study of the expression of multiple tubulins in Physarum polycephalum. Three anti-beta-tubulin monoclonal antibodies, DM1B, DM3B3 and KMX-1 all reacted with the beta 1-tubulin isotypes expressed in both myxamoebae and plasmodia. However, these antibodies showed a spectrum of reduced reactivity with the plasmodial beta 2-tubulin isotype - the competence of recognition of this isotype was graded DM1B greater than KMX-1 greater than DM3B3. The anti-alpha-tubulin monoclonal antibody, YOL 1/34 defined the full complement of Physarum alpha-tubulin isotypes, whilst the anti-alpha-tubulin monoclonal antibody, KMP-1 showed a remarkably high degree of isotype specificity. KMP-1 recognises all of the myxamoebal alpha 1-tubulin isotypes but only recognises 3 out of the 4 alpha 1-tubulin isotypes expressed in the plasmodium (which normally focus in the same 2D gel spot). KMP-1 does not recognise the plasmodial specific alpha 2-tubulin isotype. This monoclonal antibody reveals a new level of complexity amongst the tubulin isotypes expressed in Physarum and suggests that monoclonal antibodies are valuable probes for individual members of multi-tubulin families.     

Temperature-sensitive mutants of Physarum polycephalum: viability, growth, and nuclear replication.

Using a selfing strain of Physarum polycephalum that forms haploid plasmodia, we have isolated temperature-sensitive growth mutants in two ways. The negative selectant, netropsin, was used to enrich for temperature-sensitive mutants among a population of mutagenized amoebae, and, separately, a nonselective screening method was used to isolate plasmodial temperature-sensitive mutants among clonal plasmodia derived from mutagenized amoebae. Complementation in heterokaryons was used to sort the mutants into nine functional groups. When transferred to the restrictive temperature, two mutants immediately lysed, whereas the remainder slowed or stopped growing. Of the two lytic mutants, one affected both amoebae and plasmodia, and the other affected plasmodia alone. The growth-defective mutants were examined for protein and deoxyribonucleic acid synthesis and for aberrations in mitotic behavior. One mutant may be defective in both protein and deoxyribonucleic acid synthesis, and another only in deoxyribonucleic acid synthesis. The latter shows a striking reduction in the frequency of postmitotic reconstruction nuclei at the restrictive temperature. We believe that this mutant, MA67, is affected in a step in the nuclear replication cycle occurring late in G2. Execution of this step is necessary for both mitosis and chromosome replication.     

Cellular events during sexual development from amoeba to plasmodium in the slime mould Physarum polycephalum

Time-lapse cinematography and immunofluorescence microscopy were used to study cellular events during amoebal fusions and sexual plasmodium development in Physarum polycephalum. Amoebal fusions occurred frequently in mixtures of strains heteroallelic or homoallelic for the mating-type locus matA, but plasmodia developed only in the matA-heteroallelic cultures. These observations confirmed that matA controls development of fusion cells rather than cell fusion. Analysis of cell pedigrees showed that, in both types of culture, amoebae fused at any stage of the cell cycle except mitosis. In matA-heteroallelic fusion cells, nuclear fusion occurred in interphase about 2 h after cell fusion; interphase nuclear fusion did not occur in matA-homoallelic fusion cells. The diploid zygote, formed by nuclear fusion in matA-heteroallelic fusion cells, entered an extended period of cell growth which ended in the formation of a binucleate plasmodium by mitosis without cytokinesis. In contrast, no extension to the cell cycle was observed in matA-homoallelic fusion cells and mitosis was always accompanied by cytokinesis. In matA-homoallelic cultures, many of the binucleate fusion cells split apart without mitosis, regenerating pairs of uninucleate amoebae; in the remaining fusion cells, the nuclei entered mitosis synchronously and spindle fusion sometimes occurred, giving rise to a variety of products. Immunofluorescence microscopy showed that matA-heteroallelic fusion cells possessed two amoebal microtubule organizing centres, and that most zygotes possessed only one; amoebal microtubule organization was lost gradually over several cell cycles. In matA-homoallelic cultures, all the cells retained amoebal microtubule organization.     

Change of contractile behavior in plasmodia ofPhysarum polycephalum during mitosis

Summary Oscillations of ectoplasmic contraction in plasmodia of the myxomycetePhysarum polycephalum growing on agar containing semidefined medium were studied to determine if the contractile force is altered during the synchronous mitosis. In interphase the regular oscillations of contraction in the plasmodial sheet had an average period of 0.93 minutes in plasmodia growing at 24 °C. During mitosis the amplitude of these oscillations gradually decreased, ceasing for an average time of 2.7 minutes in 74% of the 23 plasmodia studied. Cessation of oscillating contractions in mitosis was accompanied by a decrease in the width of the channels embedded in the plasmodial sheet, and a decrease in the velocity of endoplasmic shuttle streaming usually to a complete standstill. Of 13 plasmodia in which the mitotic stage was very accurately determined, the stop in oscillating contractions occurred during metaphase in 10 plasmodia, and in prometaphase, anaphase, telophase in the 3 others. The cessation of contractile oscillations or of streaming did not occur absolutely simultaneously during mitosis in widely separated locations within one plasmodium, indicating mitotic asynchrony over a period of a few minutes within each plasmodium. We suggest that the halt of plasmodial migration during mitosis reported by others is caused by a decrease or cessation at slightly different times in the amplitude of ectoplasmic contractile oscillations in different areas of a plasmodium in mitosis resulting in an overall lack of coordination of endoplasmic flow throughout the plasmodium, thus temporarily halting migration. Possible physiological mechanisms linking a decrease in actomyosin contraction with the metaphase stage of mitosis are discussed.     

Demonstration of different patterns of microtubule organization in Physarum polycephalum myxamoebae and plasmodia using immunofluorescence microscopy

We have used anti-tubulin antibodies and immunofluorescence microscopy to determine the overall distribution of microtubules during interphase and mitosis in both the myxamoebae and plasmodia of the slime mold Physarum polycephalum. We have paralleled these observations with electron microscopy of the same stages. The myxamoebae possess a network of cytoplasmic microtubules whilst the coenocytic plasmodium does not possess any cytoplasmic microtubules--at either interphase or mitosis. In plasmodia microtubules are, however, elaborated by an intranuclear microtubule organizing centre (MTOC) during prophase of mitosis and these microtubules proceed to form part of the mitotic spindle. There is little difference in the overall distribution and arrangement of microtubules during division of either the myxamoebal or plasmodial nuclei. These findings are discussed in relation to the synthesis of tubulin during the plasmodial cell cycle and the rearrangements of the nuclear envelope during mitosis.     

Growth and development in relation to the cell cycle inPhysarum polycephalum

Summary In strain CL ofPhysarum polycephalum, multinucleate, haploid plasmodia form within clones of uninucleate, haploid amoebae. Analysis of plasmodium development, using time-lapse cinematography, shows that binucleate cells arise from uninucleate cells, by mitosis without cytokinesis. Either one or both daughter cells, from an apparently normal amoebal division, can enter an extended cell cycle (28.7 hours compared to the 11.8 hours for vegetative amoebae) that ends in the formation of a binucleate cell. This long cycle is accompanied by extra growth; cells that become binucleate are twice as big as amoebae at the time of mitosis. Nuclear size also increases during the extended cell cycle: flow cytometric analysis indicates that this is not associated with an increase over the haploid DNA content. During the extended cell cycle uninucleate cells lose the ability to transform into flagellated cells and also become irreversibly committed to plasmodium development. It is shown that commitment occurs a maximum of 13.5 hours before binucleate cell formation and that loss of ability to flagellate precedes commitment by 3–5 hours. Plasmodia develop from binucleate cells by cell fusions and synchronous mitoses without cytokinesis.Abbreviations CL Colonia Leicester - DSDM Dilute semi-defined medium - FKB Formalin killed bacterial suspension - IMT Intermitotic time - LIA Liver infusion agar - SBS Standard bacterial suspension - SDM Semi-defined medium     

Induction of synchronous differentiation (encystment) in Physarum polycephalum myxamoebae

Encystment of Physarum polycephalum myxamoebae, grown under nearly identical physiological conditions as plasmodia is induced by transfer to a salts medium containing 0.5 M mannitol or mannose. After 24 h induction approximately 50% of amoebae had differentiated to cells which were identified to be young cysts by light and electron microscopy. Several other polyols, sugars, biogenic amines, and a starvation period from 24 h to one week caused no reproducible cyst formation. In contrast to the formation of dormant forms in the plasmodial stage of the life cycle, the induction of cysts and their germination to amoebae are not inhibited neither by actinomycin C nor by cycloheximide. In addition, the isoenzyme spectra of aminopeptidases and acid proteases remain nearly identical in growing and differentiating amoebae.Abbreviations SD semi-defined BSS basal salts solution The investigation is a part of the Ph. D. thesis of A. Haars, Göttingen, 1976     

An immunological approach to the isolation of factors with mitotic activity from the plasmodial stage of the myxomycete Physarum polycephalum

Nuclear divisions in plasmodia of Physarum polycephalum were advanced by applying immunologically purified plasmodial extracts of late G2 phase on the surface of plasmodia which were 1.5 h before the third mitosis. The purification of G2 extracts was achieved by interaction of antibodies prepared against the antigens of early S phase plasmodia with the antigens of late G2 plasmodia. There was no advancement of mitosis by extracts prepared from early S phase plasmodia. Untreated G2 extracts did not accelerate mitosis with the same effectiveness as did antibody purified G2 extracts.