Mutations Increasing Asexual Plasmodium Formation in PHYSARUM POLYCEPHALUM

Rare plasmodia formed in clones of heterothallic amoebae were analyzed in a search for mutations affecting plasmodium formation. The results show that the proportion of mutants varies with both temperature (18°, 26° or 30°) and mating-type allele (mt1, mt2, mt3, mt4). At one extreme, only one of 33 plasmoida formed by mt2 amoebae at 18° is mutant. At the other extreme, three of three plasmodia formed by mt1 amoebae at 30° are mutant. The mutant plasmodia fall into two groups, the GAD (greater asexual differentiation) mutants and the ALC (amoebaless life cycle) mutants. The spores of GAD mutants give rise to amoebae that differentiate into plasmodia asexually at much higher frequencies than normal heterothallic amoebae. Seven of eight gad mutations analyzed genetically are linked to mt and one (gad-12) is not. The gad-12 mutation is expressed in strains with different alleles of mt. The frequency of asexual plasmodium formation is heat sensitive in some (e.g., mt3 gad-11 ), heat-insensitive in two (mt2 gad-8 and mt2 gad-9) and cold-sensitive in one (mt1 gad-12) of twelve GAD mutants analyzed phenotypically. The spores of ALC mutants give rise to plasmodia directly, thereby circumventing the amoebal phase of the life cycle. Spores from five of the seven ALC mutants give rise to occasional amoebae, as well as plasmodia. The amoebae from one of the mutants carry a mutation (alc-1) that is unlinked to mt and is responsible for the ALC phenotype in this mutant. Like gad-12, alc-1 is expressed with different mt alleles. Preliminary observations with amoebae from the other four ALC mutants suggest that two are similar to the one containing alc-1; one gives rise to revertant amoebae, and one gives rise to amoebae carrying an alc mutation and a suppressor of the mutation.     

Mutants with decreased differentiation to plasmodia in Physarum polycephalum

Summary Mutant (APT) amoebae that display reduced ability to form plasmodia asexually were isolated by the use of an enrichment procedure. The results of reconstruction experiments show that the procedure enriches only for mutants blocked early in the pathway from amoeba to plasmodium. Mutants were isolated from four parents, two of which produce plasmodia asexually because they carry the allele mth of the mating type locus, and two because they carry gad (greater asexual differentiation) mutations. The APT mutants varied widely in the frequency of residual plasmodium formation, which occurred, in some cases, by reversion. The mutants, called apt (amoeba to plasmodium transition), were recessive in diploids and linked to the mating type (mt) locus. Mutants derived from the gad parents, unlike the parents themselves, crossed readily with heterothallic amoebae. Progeny analysis from such crosses indicates that both gad mutations are linked to mt. The mutants derived from one of the mth parents fell into two groups on the basis of their ability to cross with the mutants derived from the mt2 gad-8 parent. The result suggests that the mth-derived mutants represent two or more complementation groups. Mutants derived from the mt2 gad-8 parent cross with mt2 amoebae and hence display an altered mating specificity.     

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.     

Food deprivation is not a prerequisite for the amoebal to plasmodial transition in Physarum polycephalum

The effect of food supply on the onset of asexual and sexual plasmodium formation in Physarum polycephalum was studied. Asexual differentiation occurs readily in amoebae carrying the matAh mating type allele. The density at which these amoebae begin to differentiate is influenced by the ind locus, which controls the production of a diffusible inducer. The alleles ind-1 and ind-2 are known. Strains carring the ind-1 allele begin plasmodium formation at a low amoebal density (rapid differentiation), while strains carring the ind-2 allele differentiate at a higher amoebal density (slow differentiation). The onset of differentiation is characteristic of the strain and did not change with a 20-fold variation in the number of food bacteria available. Sexual differentiation occurs between compatible amoebal strains. For a given pair of amoebal strains the onset of plasmodium formation occurs at a characteristic cell density that is determined by the genetic backgrounds of the strains. The ind locus is one of the genes that influences this cell density. Plasmodia are formed at a lower cell density in crosses involving compatible amoebae carrying the ind-1 allele than they are in crosses with strains carrying the ind-2 allele. As was found for asexual differentiation, an approximate 20-fold variation in the food supply did not affect the initiation of sexual plasmodium formation. These results suggest that in most cases starvation does not trigger the differentiation of amoebae into plasmodia. The time of onset of plasmodium formation is determined largely by genetic factors.     

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.     

Revertants of selfing (gad) mutants in Physarum polycephalum

The conversion of the uninucleate amoebal form of Physarum polycephalum to the multi-nucleate plasmodial form is under the control of a genetic region which contains matA (or mt), a determinant of mating specificity. The region is the site of most gad mutations, which give amoebae the ability to produce plasmodia in clones without mating (ie, to self). In the present study, nonselfing revertants were isolated from two matA2-derived gad mutants and two matA3-derived gad mutants. Some revertants were found to have regained exactly, or nearly, the same phenotype as the original matA2 or matA3 strain. Others expressed new mating types, having gained the ability to mate with strains of the parental matA type. The results are compatible with a model in which new mating types arise from forward mutations (gad) and back mutations (npf or no plasmodium formation) occurring successively in a single gene, matA.     

A mutation (gad) linked to mt and affecting asexual plasmodium formation in Physarum polycephalum.

Amoebae of the acellular slime mold Physarum polycephalum convert to plasmodia both asexually and sexually. Genetic analysis of a mutant that exhibits enhanced asexual plasmodium formation is reported. The mutant carries a single lesion (gad-11) located 12.3 map units from mt, a gene that controls mating specificity in sexual plasmodium formation. The mutation, which was isolated in an mt3 strain, is also expressed in mth and mt4 strains.     

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.     

Ribosomal DNA in spores of Physarum polycephalum

DNA was isolated from plasmodia, spores and newly hatched amoebae of the slime mould Physarum polycephalum. The DNA preparations were fractionated in CsCl gradients and each fraction hybridised to combined 19 S + 26 S rRNA. In all three DNA preparations hybridisation was found to be limited to satellite DNA (rho = 1.714 g/cm3) and at saturation was found to reach a level of 0.16--0.18 % of total DNA. The main band of nuclear DNA (rho = 1.702 g/cm3) did not hybridise appreciably. Further experiments using analytical CsCl gradients revealed that the ratio of satellite to main band DNA was similar in all three preparations. It is concluded that the genes for ribosomal RNA are equally reiterated in spores, hatching amoebae and in plasmodia. They appear to be similarly organised in all stages of the life cycle examined so far.     

The effect of proteases on plasmodium formation in Didymium iridis.

An improved assay for quantitatively measuring the number of plasmodia formed with time is presented. Using this assay we have investigated the effects of three proteases, subtilisin PBN', subtilisin carlsberg and alpha-chymotrypsin. We have shown that 1) plasmodium formation is sensitive to protease treatment only during the first 2 h after mixing amoebae of compatible mating type but not after, 2) amoebae are protease sensitive when treated 1 h prior to mixing, 3) the two clones used have different sensitivities to protease treatment and 4) these effects are due to enzymatic activity and have little effect on viability. The meaning of these results in relation to recent evidence for a diffusible inducer of plasmodium formation is discussed.     

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     

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.     

Two Multiallelic Mating Compatibility Loci Separately Regulate Zygote Formation and Zygote Differentiation in the Myxomycete PHYSARUM POLYCEPHALUM

The mating of Physarum polycephalum amoebae, the ultimate consequence of which is a "plasmodium," was recently shown to be governed by two compatibility loci, matA (or mt) and matB (Dee 1978; Youngmanet al. 1979). We present evidence that matA and matB separately regulate two discrete stages of mating: in the first stage, amoebae (which are normally haploid) fuse in pairs, with a specificity determined by matB genotype, to form diploid zygotes; subsequent differentiation of the zygotes into plasmodia is regulated by matA and is unaffected by matB. Mixtures of amoebae carrying unlike matA and matB alleles formed diploids to the extent of 10 to 15% of the cells present, and the diploids differentiated into plasmodia. When only the matB alleles differed, diploid cells still formed to a comparable (5 to 10%) extent, but rather than differentiating, these diploids remained amoebae. When strains carried the same alleles of matB, formation of diploid cells was greatly reduced: in like-matB, like-matA mixtures, none of 320 cells examined was diploid; in like-matB, unlike mat-A mixtures, differentiating diploids could be detected, but at only 10(-3) to 10(-2) the frequency of unlike-matB, unlike-matA mixtures. The nondifferentiating diploid amoebae recovered from unlike-matB, like-matA mixtures were genetically stable through extensive growth, even though they grew more slowly than haploids (10-hr vs. 8-hr doubling period), and could be crossed with both haploids and diploids. The results of such higher ploidy and mixed ploidy crosses indicate that karyogamy does not invariably accompany zygote formation and differentiation.     

A Proposed Life Cycle of Minchinia nelsoni (Haplosporida, Haplosporidiidae) in the American Oyster Crassostrea virginica

SYNOPSIS. A developmental sequence is proposed for the haplosporidan Minchinia nelsoni Haskin, Stauber and Mackin, 1966, based on study of oyster infections over the past 5 years in Chesapeake Bay. Uninucleate stages develop by nuclear division into multinucleate plasmodia which proliferate in the tissues by plasmotomy. Relatively small plasmodia containing what are considered to be gametic nuclei originate by unequal plasmotomy of large plasmodia. These have been interpreted to aggregate and fuse to form large plasmodia which contain prozygotes. Pairing and fusion of nuclei occur within each plasmodium to produce zygote nuclei (synkaryons) which undergo division, possibly meiotic, to form sporonts. Sporoblasts differentiate into spores with the development of spore walls and opercula. Cystoid plasmodia develop during times of unfavorable conditions. An anomalous but common sequence involving sexuality and mitosis is described, and the occurrence of various life cycle stages within the host thruout the year is discussed.     

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.     

Building a plasmodium: Development in the acellular slime mould Physarum polycephalum

The two vegetative cell types of the acellular slime mould Physarum polycephalum - amoebae and plasmodia - differ greatly in cellular organisation and behaviour as a result of differences in gene expression. The development of uninucleate amoebae into multinucleate, syncytial plasmodia is under the control of the mating-type locus matA, which is a complex, multi-functional locus. A key period during plasmodium development is the extended cell cycle, which occurs in the developing uninucleate cell. During this long cell cycle, many of the changes in cellular organisation that accompany development into the multinucleate stage are initiated including, for example, alterations in microtubule organisation. Genes have been identified that show cell-type specific expression in either amoebae or plasmodia and many of these genes alter their pattern of expression during the extended cell cycle. With the introduction of a DNA transformation system for P. polycephalum, it is now possible to investigate the functions of genes in the vegetative cell types and their roles in the cellular reorganisations accompanying development.     

A gene,imz, affecting the pH sensitivity of zygote formation inPhysarum polycephalum

Mating inPhysarum polycephalum involves the fusion of two haploid amoebae and the differentiation of the resulting diploid zygote into a multinucleate plasmodium. Mating proceeds optimally with amoebae growing on an agar medium at pH 5.0. At pH 6.2, the amoebae still grow normally, but mating is completely blocked. The barrier at pH 6.2 is not in the differentiation step, since preformed diploids readily convert to plasmodia at this pH. The barrier can be overcome by raising the ionic strength of the agar medium; the effect, moreover, is not ion-specific. We have discovered a genetic locus,imz (ionicmodulation of zygote formation), that affects the upper pH limit for mating; the respective limits associated with the two known alleles,imz-1 andimz-2, are pH 5.6 and pH 6.0 at low ionic strength. Animz-1×imz-2 mating displays the pH 6.0 limit;imz-2 is therefore “dominant”. We suggest that this new gene affects a cell component that is exposed to the exterior of the amoeba and is involved in the fusion step of mating.     

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.     

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.