Analysis of development and growth in a mutant of Physarum polycephalum with defective cytokinesis

Cultures of amoebae of the mutant strain ATS23 isolated from strain CLd of Physarum polycephalum contain multinucleate cells and cells with increased nuclear DNA content. Plasmodia derived from ATS23 clones show abnormal morphology and defective sporulation. All abnormalities are enhanced by high incubation temperature (31 °C). Genetic analysis suggested that all the abnormalities were caused by a single mutation, denoted hts-23. The kinetics of plasmodium formation were followed in cultures of apogamic amoebae carrying hts-23 and hts⁺ (wild type) respectively. Results indicated that, relative to wild type, hts-23 did not increase the rate of plasmodium formation. There was evidence that, in both mutant and wild-type strains, commitment to plasmodium development occurred in uninucleate cells. Analysis of cell pedigrees by time-lapse cinematography indicated that the primary abnormal event in cultures of hts-23 amoebae was failure of cytokinesis; an apparently complete cleavage furrow was formed but cell separation failed, resulting in a binucleate cell. This event occurred randomly in pedigrees in which the majority of divisions were completed normally; its frequency increased during incubation at 31 °C. All other abnormalities in hts-23 amoebal cultures could be attributed to this primary event, assuming that DNA synthesis continued in the absence of cytokinesis and that the binucleate cells underwent the amoebal type of “open” mitosis, allowing the possibility of spindle fusion. This implies that the acquisition of “closed” mitosis is an essential early step in plasmodium development.     

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.     

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.     

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.     

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     

QUANTITATIVE MICROSPECTROPHOTOMETRY OF NUCLEAR DNA IN SELFING STRAINS OF THE MYXOMYCETE DIDYMIUM IRIDIS

Genetic and cytochemical investigations of the origin, development, nuclear activity, and ploidy level of Plasmodia obtained from selfed clones S-2 and B₁P-33 of the heterothallic myxomycete, Didymium iridis, are presented. To demonstrate that selfing did not result from contamination of the clones, or mutations at the mating-type locus, crosses were made between F₁ clones and clones of known mating types. The data were inconsistent with these two possibilities. DNA was quantified by Feulgen-DNA microspectrophotometry. All cellular phases studied (logarithmic amoebae, swarmers, and encysted amoebae) appear to be haploid, with the nuclear DNA being in the replicated (2C) state. The plasmodia are in all cases diploid; however, the data indicate that the selfed Plasmodia are in an extended G₁ condition. The nuclear DNA content of these is therefore 2C, whereas that of the cross Plasmodium is 4C. Sporangial nuclei exhibit DNA in diploid replicated (4C) category.     

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.     

Isolation of Physarum polycephalum plasmodial mutants altered in sporulation by chemical mutagenesis of flagellates

Plasmodia are giant, multinucleate single cells which develop from mononucleate amoebae during the developmental cycle of Physarum polycephalum. In visible light, starving plasmodia lose their unlimited replicative potential and terminally differentiate into fruiting bodies (sporulation). Aiming at genetic dissection of the circuits controlling commitment and differentiation, we worked out a standardized procedure for the generation and screening of plasmodial mutants altered in sporulation by mutagenesis with ethylnitrosourea. To obtain a homogeneous population of cells of those strains which cannot grow axenically, we describe a protocol for preparing a suspension of flagellates to be used as starting material for mutagenesis. Flagellates can transform into plasmodia via the amoebal stage. Pilot phenotypic screening yielded plasmodial mutants altered in the photocontrol of sporulation or with disturbed developmental program. The existence of mutants with a disturbed developmental program indicates that the sequence and synchrony of morphogenetic steps of fruiting body formation can be uncoupled through mutation. Complementation testing by plasmodial fusion identified three complementation groups of non-sporulating mutants. The work described provides an experimental basis for performing mass screens for Physarum mutants altered in sporulation.     

Enterocytozoon hepatopenaei sp. nov. (Microsporida: Enterocytozoonidae), a parasite of the black tiger shrimp Penaeus monodon (Decapoda: Penaeidae): Fine structure and phylogenetic relationships

A new microsporidian species, Enterocytozoon hepatopenaei sp. nov., is described from the hepatopancreas of the black tiger shrimp Penaeus monodon (Crustacea: Decapoda). Different stages of the parasite are described, from early sporogonal plasmodia to mature spores in the cytoplasm of host-cells. The multinucleate sporogonal plasmodia existed in direct contact with the host-cell cytoplasm and contained numerous small blebs at the surface. Binary fission of the plasmodial nuclei occurred during early plasmodial development and numerous pre-sporoblasts were formed within the plasmodium. Electron-dense disks and precursors of the polar tubule developed in the cytoplasm of the plasmodium prior to budding of early sporoblasts from the plasmodial surface. Mature spores were oval, measuring 0.7 × 1.1 μm and contained a single nucleus, 5-6 coils of the polar filament, a posterior vacuole, an anchoring disk attached to the polar filament, and a thick electron-dense wall. The wall was composed of a plasmalemma, an electron-lucent endospore (10 nm) and an electron-dense exospore (2 nm). DNA primers designed from microsporidian SSU rRNA were used to amplify an 848 bp product from the parasite genome (GenBank FJ496356). The sequenced product had 84% identity to the matching region of SSU rRNA from Enterocytozoon bieneusi. Based upon ultrastructural features unique to the family Enterocytozoonidae, cytoplasmic location of the plasmodia and SSU rRNA sequence identity 16% different from E. bieneusi, the parasite was considered to be a new species, E. hepatopenaei, within the genus Enterocytozoon.     

Stabilization of monoasters by taxol in the amoebae ofPhysarum polycephalum (Myxomycetes)

Summary Although the plasmodial stage of the MyxomycetePhysarum polycephalum was unaffected with 200 M taxol, the amoebal stage was sensitive to 10 M taxol. The first effect of taxol resulted in an accumulation of cells blocked as a monopolar centrosphere surrounded by condensed chromosomes. In 79% of cases these monoasters contained two pairs of centrioles. The mitotic block in a monopolar stage in the presence of taxol delayed the occurrence of late mitotic events such as chromosome decondensation and formation of the nuclear envelope. Escape from the monopolar centrosphere stage and formation of multinucleated amoebae involved a transient monopolar reconstruction stage in which a long microtubular bundle interacted with a small chromosomal mass outside the monoaster.     

Pattern of DNA synthesis in nuclei of feeding and starving Amoeba proteus : A cytofluorometric study

The DNA content in isolated nuclei of Amoeba proteus was determined for each of the three groups of synchronized amoebae over different intervals after division. Several nuclei of each amoeba group were fixed 1 h after division, before the amoebae were fed. About h after division, some amoebae in each group were given food (Tetrahymena pyriformis), while the rest were left starving. Samples of the nuclei of fed and starved amoebae were fixed 24 h and (in different groups) 42–55 h after division. In each group from 22 to 48% of the fed amoebae had divided prior to the last nuclei fixation. Starved amoebae did not undergo division. In all three amoeba groups the nuclear DNA content of fed cells by the end of interphase had increased to 280–300% the value for 1 h amoebae. The nuclear DNA content of starved amoebae of all three groups was also increased, and in two groups it exceeded the initial level more than two-fold. However, in all three groups, it was lower than that of fed amoebae. In all the groups the nuclear DNA content in fed amoebae grew after 24 h, i.e. during the second half of interphase, the increase accounting for from 11 to 48% of the total increase. The hypothesis is put forward that the increase in the nuclear DNA content during the cell cycle of Amoeba proteus is the result of two processes: (1) one-time replication of the DNA of the whole genome; and (2) repeated replication of some part of the DNA. In amoebae the relation of the pattern of nuclear DNA synthesis to the diet is considered.     

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.     

Chromosome numbers in representative myxomycetes: a cytogenetic study

Myxomycetes are also called plasmodial slime molds, due to one of their characteristic features, the occurrence of the plasmodium. However, most of the distinguishing characters of the five orders currently recognised are based on the morphology of fruiting bodies and spores. Although a few myxomycetes have become widely used model organisms for genetic and cytological studies, complete information relating to the number of chromosomes in haploid cells (n) is lacking thus far. Only two species of the order Physarales have been examined with respect to chromosome numbers. Here, we present a complete data set on the numbers of chromosomes in ten species of myxomycetes that are members of all five orders. Our analysis indicates that n?=?21 is the evolutionary ancient chromosome number that occurs in the morphologically simple orders Liceales and Ceratiomyxales. More derived taxa, such as the Physarales, have significantly higher chromosome numbers (n?=?30). These data shed light on the phylogenetic relationships within the myxomycetes.     

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).     

DNA amounts and chromatin compactness in Vicia

2C DNA amounts and areas of chromatin were determined with a M 86 Vickers microdensitometer in 56 species of Vicia (x=5, 6, 7), exhibiting large differences in chromosome size. There were significant differences between the species both in DNA content and chromatin area. The nuclear DNA amounts range from 3.85 to 27.07 pg. DNA distribution appears discontinuous; species cluster into distinct groups and the average nuclear DNA amount separating each successive pair is approximately the same (2.23 pg). The compaction of DNA in interphase nuclei increases with increasing DNA amount, which is, at least partly, due to a disproportionate increase in the heterochromatin relative to the euchromatin component of DNA. Comparisons of DNA readings at various stages of the cell cycle show that the DNA amounts are underestimated by microdensitometry in nuclei with high DNA density. Estimation of relative DNA content and area of individual chromosomes were made in twelve species. The results show that changes in DNA content within chromosomes affect the degree of metaphase coiling in an orderly fashion.     

DNA Content Differences Between Male and Female Chicken (Gallus gallus domesticus) Nuclei and Z and W Chromosomes Resolved by Image Cytometry

Chicken red blood cells (CRBCs) are widely used as standards for DNA content determination. Cytogenetic data have shown that the Z sex chromosome is approximately twice as large as the W, so that the DNA content differs to some extent between male (ZZ) and female (ZW) chickens. Despite this fact, male and female CRBCs have been indiscriminately used in absolute genome size determination. Our work was conducted to verify whether the DNA content differences between male and female Gallus gallus domesticus “Leghorn” nuclei and ZZ/ZW chromosomes can be resolved by image cytometry (ICM). Air-dried smears stained by Feulgen reaction were used for nuclei analysis. Chicken metaphase spreads upon Feulgen staining were analyzed for obtaining quantitative information on the Z and W chromosomes. Before each capture session, we conducted quality control of the ICM instrumentation. Our results from nuclear measurements showed that the 2C value is 0.09 pg higher in males than in females. In chromosomes, we found that the Z chromosome shows 200% more DNA content than does the W chromosome. ICM demonstrated resolution power to discriminate low DNA content differences in genomes. We suggest prudence in the general use of CRBC 2C values as standards in comparative cytometric analysis. (J Histochem Cytochem 58:229–235, 2010)     

The Sequence of Regulatory Events in the Sporulation Control Network of Physarum polycephalum Analysed by Time-resolved Somatic Complementation of Mutants

The developmental decision for sporulation of Physarum polycephalum plasmodia is under sensory control by environmental factors like visible light or heat shock and endogenous signals like glucose starvation. Several hours after perceiving an inductive stimulus, plasmodia become committed to sporulation; thereby, they lose their unlimited replicative potential and execute a developmental program that involves differentiation into various cell types required to form a mature fruiting body. Plasmodia are multinuclear single cells which spontaneously fuse upon physical contact. Fusion of mutant plasmodia and cytoplasmic mixing allows complementation studies to be performed at the functional level. Mutant cells altered in their ability to sporulate in response to phytochrome activation by far-red light were cured by fusion with wild-type or other mutant plasmodia. Phytochrome activation in one plasmodium and subsequent fusion with a non-induced plasmodium revealed that complementation of the two mutations depended on (i) which of two genetically distinct plasmodial cells was stimulated; and (ii) on the delay time elapsed between stimulation and cytoplasmic mixing. Such experiments allow us to determine the kinetics and the causal sequence of the regulatory events tagged by mutation.     

Regulation of DNA replication in the nuclei of the slime mold Physarum polycephalum. Transplantation of nuclei by plasmodial coalescence

Nuclei in G2 phase of the slime mold Physarum polycephalum, when transplanted, by plasmodial coalescence, into an S-phase plasmodium, failed to start another round of DNA synthesis. In the reciprocal combination, S-phase nuclei in a G2-phase host continued DNA synthesis for several hours without appreciable decrease in rate. It is suggested that the beginning of DNA replication is determined by an event, either during or shortly after mitosis, which renders the chromosomes structurally competent for DNA replication.