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.     

SPORE ULTRASTRUCTURE OF THE MYXOMYCETE PHYSARUM POLYCEPHALUM

Spores of the true slime mold Physarum polycephalum were examined at several stages of their development by means of scanning and transmission electron microscopy. The spores were globose, spine-covered structures produced within a sporangium enclosed in a tough, noncellular peridium. Cytologically, the spore represented a typical eukaryotic cell, having discrete organelles similar to spores of other myxomycetes. The presence of dictyosomes, helical filaments, and microbodies in these cells, as well as the further elucidation of the cell wall and the “polysaccharide-containing” areas, represent new contributions to the ultrastructure of the myxomycete spore. Of special interest were observations of metaphase nuclei just prior to spore cleavage, interphase nuclei in young spores, and nuclei in mature spores containing synaptonemal complexes. These observations indicate that in Physarum polycephalum mitosis occurs just prior to spore cleavage, and meiosis takes place after spore cleavage.     

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.     

Complementation of Amoebal-Plasmodial Transition Mutants in PHYSARUM POLYCEPHALUM

Amoebae of the Myxomycete Physarum polycephalum differentiate to yield plasmodia in two ways: in crossing, haploid amoebae of appropriate genotypes fuse to form diploid plasmodia; in selfing, plasmodia form without amoebal fusion or increase in ploidy. Amoebae carrying the mating-type allele matAh (formerly mt_h) self efficiently, but occasionally give rise to mutants that self at very low frequencies. Such "amoebal-plasmodial transition" mutants were mixed in pairs to test their ability to complement one another in the formation of plasmodia by crossing. The pattern of crossing permitted 33 mutants to be assigned to four complementation groups (aptA^-, npfA^-, npfB^- and npfC^-). Similar tests had previously proved only partially successful, as crossing had occurred only rarely in mixtures of compatible strains. The efficiency of complementation was greatly increased in the current work by mixing strains that carried different alleles of a newly-discovered mating-compatibility locus, matB; this locus had no effect on the specificity of complementation. A possible interpretation of the complementation behavior of the mutants is suggested.     

多头绒泡菌中动蛋白的免疫化学鉴定

动蛋白(kinesin)是一种微管系统的运动蛋白(motor protein),它能通过水解ATP将化学能转化为机械能,推动微管产生运动.微管系统作为一种主要的细胞骨架存在于所有真核细胞中,它们对于维持细胞形态,细胞的分裂,染色体的运动及细胞内的物质运输起着重要作用.细胞质力蛋白(dynein)和动蛋白是公认的推动这类运动的运动蛋白.自从1985年Vole首次在鱿鱼大轴突(squidgiant axon)中发现动蛋白以来,人们先后在许多种动物细胞中发现有动蛋白存在,甚至在低等真核生物棘状变形虫,盘基网柄茵和高等植物烟草花粉管中发现有动蛋白的存在.研究结果表明,动蛋白参与了真核细胞中的许多重要生命活动,如细胞中的细胞器及囊泡的运动,染色体排裂和分离等运动.动蛋白很可能是普通存在于所有真核细胞中的一种运动蛋白.多头绒泡菌(Physarum poly-cephalum)属于粘菌纲(Myxomycetes)的一种低等真核生物,它表现出许多显著的细胞运动特征如原生质团迁移,细胞质的穿梭运动(shuttle streaming)等,是研究非肌细胞运动和收缩蛋白的经典材料.在多头绒泡菌胞质中也具有微管系统,它们构成其纺锤丝等,参与染色体的运动及其它胞质运动,但至今国内外尚无人证明其中有与微管作用的运动蛋白——动蛋白的存在,作者利用抗牛脑动蛋白的单克隆抗体,     

FIBRILLAR DIFFERENTIATION IN A MICROPLASMODIUM OF THE SLIME MOLD PHYSARUM POLYCEPHALUM

The motility of Physarum polycephalum microplasmodia depends upon the conditions under which they are cultured. To investigate the relation between protoplasmic streaming and filamentous structures observed in the cytoplasm, microplasmodia were collected from shaken cultures, agar plates and shaken cultures of the organism which had previously been plate-cultured.
No sign of streaming could be found in materials in shaken culture, even in those which were shaken after they had once been motile on an agar plate. The immotile microplasmodia in both cases failed to contain any filamentous structures.
Microplasmodia on agar plates were motile, showing vigorous peripheral movements (projection of pseudopods) and inner protoplasmic streaming. In the motile organisms two types of filamentous structures were observed: loose networks just inside the plasma membrane of rounded pseudopods with smooth surfaces; and compact, straight bundles beneath the pseudopods or in much deeper locations.     

Genetics of Somatic Fusion in PHYSARUM POLYCEPHALUM: the Ppii Strain

Plasmodial (somatic) fusion in a strain of Physarum polycephalum, a true slime mold, is controlled by four loci, each of which displays simple dominance. Two diploid plasmodia fuse with each other only if they are phenotypically or genotypically identical for all four fusion loci.     

多头绒泡菌细胞核周期的电镜研究

多头绒泡菌PhysarumpolycophalumSchw的营养生长阶段为没有细胞壁的原生质团（合胞体）,内部众多的细胞核进行着同步的核内有丝分裂,本文电镜下研究了细胞核在有丝分裂周期中的结构变化。有丝分裂前期,染色质经松散改组和集缩形成染色体,核仁由中央移向边缘,并在近核膜处解体;中期核膜不消失,在核内形成纺锤体,核仁解体后的物质是不规则状散在于核内;有丝分裂后核膜的破裂处重新愈合,染色体解集缩成染色质,分散的核仁物质逐渐合并形成新的核仁。     

A Gene, ALCA, Affecting the Life Cycle Form Expressed in PHYSARUM POLYCEPHALUM

The usual sequence of forms in the Physarum polycephalum life cycle is plasmodium-spore-amoeba-plasmodium. So-called "amoebaless life cycle" or alc mutants of this Myxomycete undergo a simplified plasmodium-spore-plasmodium life cycle. We have analyzed three independently isolated alc mutants and found in each case that the failure of the spores to give rise to amoebae is due to a recessive Mendelian allele. The three mutations are tightly linked to one another and belong to a single complementation group, alcA. The mutations are pleiotropic, not only interfering with the establishment of the amoebal form at spore germination, but also affecting the phenotype of alc amoebae, which occasionally arise from alc spores. The alc amoebae (1) grow more slowly than wild type, particularly at elevated temperatures; (2) tend to transform directly into plasmodia, circumventing the sexual fusion of amoebae that usually accompanies plasmodium formation; and (3) form plasmodia by the sexual mechanism less efficiently than wild-type amoebae. The various effects of an alc mutation seem to derive from mutation of a single gene, since reversion for one effect is always accompanied by reversion for the other effects. Moreover, a mutation, aptA1, that blocks direct plasmodium formation by alcA amoebae, also increases their growth rate to near normal. The manner of plasmodium formation in alcA strains differs significantly from that in another class of mutants, the gad mutants. Unlike gad amoebae, alcA amoebae need not reach a critical density in order to differentiate directly into plasmodia and do not respond to the extracellular inducer of differentiation. In addition, alcA differentiation is not prevented by a mutation, npfA1, that blocks direct differentiation by most gad amoebae.     

LASER MICROSCOPE IRRADIATION OF PHYSARUM POLYCEPHALUM: DYNAMIC AND ULTRASTRUCTURAL EFFECTS

Streaming plasmodia of Physarum polycephalum were irradiated with a microscope-mounted ruby laser and the resulting changes were recorded by cinemicrography or streak photographs. Some lesions were processed for electron microscopy. By varying the incident energy, three levels of response were detected. Two transient responses, a gelation briefly blocking streams and a more severe gelation with contraction, changed movement patterns but not organelle ultrastructure. At higher energies, a permanently coagulated lesion was rapidly segregated from normal and transiently altered cytoplasm by formation of new membranes. Within the coagulum, pigment granules were destroyed, membranes were disrupted, and cytoplasm was flocculent. Nuclei and mitochondria were compact in the center and swollen in a peripheral space left by contraction of the coagulum. These changes are probably caused by heat produced by the interaction between the laser beam and the pigment granules of the plasmodium. Many of the changes seem to be secondary responses that follow the primary capture of energy during irradiation.     

肌动蛋白是多头绒泡菌细胞核骨架和染色体骨架的组成成分

自多头绒泡菌(Physarum polycephalum Schw.)的原质团中分离细胞核和染色体,分别经DNaseⅠ消化和2 mol/L NaCl抽提后制备成细胞核骨架和染色体骨架。以抗肌动蛋白的抗体作一抗、FITC标记的羊抗兔IgG抗体作二抗进行的间接免疫荧光实验结果显示,细胞核骨架和染色体骨架都分别与抗体呈阳性反应。间接免疫斑点印迹实验结果进一步证实,细胞核骨架和染色体骨架的蛋白质成分中存在与肌动蛋白抗体呈阳性显色反应的抗原。以抗肌动蛋白的抗体作一抗、金颗粒标记的蛋白A作二抗的间接免疫电镜实验结果表明,在实验组间期细胞核的核仁、集缩染色质和核基质以及中期染色体上都有很多金颗粒分布。上述结果证明,肌动蛋白是多头绒泡菌细胞核和染色体及其骨架的组成成分。     

多头绒泡菌染色体构建过程的形态学研究

以同步核内有丝分裂的多头绒泡菌(Physarum polycephalum)原质团为材料,在有丝分裂周期中连续取材,按常规方法制备超薄切片,在电镜下研究了染色体形态构建的整个过程。有丝分裂前期,首先是G_2期凝集的染色质块逐渐解集缩成为松散状,染色质在松散的同时逐渐改组成直径为80～150nm的松散染色线结构。接着是在松散的染色线上形成一些电子密度高的集缩区,随着集缩区的增多和扩展,染色线缩短变粗,最后形成直径300～350nm的染色体。上述两个过程各需30min左右。与上述过程同时发生的是,核仁由中央位置逐渐移向边缘,前期50min左右时在近核膜处呈团块状解体。染色体形态构建的整个过程约需1h,可分为染色质的松散改组和集缩两个连续的步骤,25～30nm染色质纤维是这一过程中能分辨的最细的形态单位。     

THE EFFECT OF ACTIDIONE ON MITOSIS IN THE SLIME MOLD PHYSARUM POLYCEPHALUM

Actidione, reportedly a specific inhibitor of protein synthesis, was found to reduce the incorporation of labeled amino acids into proteins of the slime mold Physarum polycephalum without drastically inhibiting the incorporation of nucleic acid precursors into RNA. This inhibitor was found to completely block the ensuing mitosis if it was added at any time between telophase and late prophase. Plasmodia given Actidione in late prophase (about the time of nucleolar dissolution) went on through telophase to reconstruction even though nuclear amino acid incorporation was drastically reduced during that period.