Unusual amoebal strains of the MyxomycetePhysarum polycephalum possessing two pro-flagellar apparatuses

Summary The microtubules structure of two stable diploid amoebal strains, each resulting from the fusion of two haploid amoebae has been studied by electron microscopy. Tridimensional reconstructions showed that these diploid amoebae-typically possessed two proflagellar apparatuses,i.e., two microtubule organizing centers 1 (mtoc 1) and two pairs of centrioles with their associated microtubular arrays. These observations account for the high frequency of biflagellated amoebae in these two strains. The presence of two mtoc 1 may account for the high percentage of mitotic abnormalities which was observed under phase contrast microscopy and electron microscopy and is in agreement with a role of the mtoc 1 as a mitotic center during mitosis. However, the presence of numerous normal mitotic apparatuses raises the question of the regulations which play a role in the mitotic process. The unusual distribution of centrioles and the unusual pro-flagellar apparatuses which were produced suggest that in interphase the anterior centriole is a necessary structure for the morphogenesis of the microtubular arrays 2 and 3 and that the posterior centriole is a necessary structure for the morphogenesis of the microtubular arrays 4 and 5.     

Microtubule cytoskeleton and morphogenesis in the amoebae of the myxomycete Physarum polycephalum

Summary— The amoebae of the myxomycete Physarum polycephalum are of interest in order to analyze the morphogenesis of the microtubule and microfilament cytoskeleton during cell cycle and flagellation. The amoebal interphase microtubule cytoskeleton consists of 2 distinct levels of organization, which correspond to different physiological roles. The first level is composed of the 2 kinetosomes or centrioles and their associated structures. The anterior and posterior kinetosomes forming the anterior and posterior flagella are morphologically distinguishable. Each centriole plays a role in the morphogenesis of its associated satellites and specific microtubule arrays. The 2 distinct centrioles correspond to the 2 successive maturation stages of the pro-centrioles which are built during prophase. The second level of organization consists of a prominent microtubule organizing center (mtoc 1) to which the anterior centriole is attached at least during interphase. This mtoc plays a role in the formation of the mitotic pole. These observations based on ultrastructural and physiological analyses of the amoebal cystoskeleton are now being extended to the biochemical level. The complex formed by the 2 centrioles and the mtoc 1 has been purified without modifying the microtubule-nucleating activity of the mtoc 1. Several microtubule-associated proteins have been characterized by their ability to bind taxol-stabilized microtubules. Their functions (e.g., microtubule assembly, protection of microtubules against dilution or cold treatment, phosphorylating and ATPase activities) are under investigation. These biochemical approaches could allow in vitro analysis of the morphogenesis of the amoebal microtubule cytoskeleton.     

Spatial relationships between the anterior centriole and the mitotic center during interphase in the amoebae of the myxomycete Physarum polycephalum

Amoebae of the Myxomycete Physarum polycephalum in the interphase state typically contain only one proflagellar apparatus in which the anterior kinetosome (anterior centriole) is attached to the microtubule organizing center 1 (mtoc 1). We built strains possessing more than one mtoc 1 and a variable number of anterior centrioles to allow the appearance of new structures. In 8% of the amoebae of these strains, the 1:1 attachment between the anterior centriole and the mtoc 1 is not always respected. In nine cases studied using tridimensional reconstructions from ultrastructural thin sections, the pattern of attachment was more complex. A mtoc 1 could be linked to several anterior centrioles, and/or reciprocally an anterior centriole could be linked to several mtoc 1. In one case, an anterior centriole was not linked to a mtoc 1 and in three cases, a single centriole exhibited anterior and posterior characteristics. These observations suggest that (1) each pair of centrioles constitutes a morphological and physiological entity that is distinct from the mitotic center (mtoc 1); (2) the attachment of the anterior centriole to the mtoc 1 occurs at the end of each mitosis; (3) there is an inductory process during the morphogenesis of the link between the anterior centriole and the mtoc 1; (4) the anterior characteristics of a centriole can be present in the absence of the link with the mtoc 1; (5) the anterior and posterior characteristics of a centriole are not exclusive of each other, ruling out the existence of a lineage corresponding to the anterior centriole and a lineage corresponding to the posterior centriole; and (6) the differences between anterior and posterior centrioles result from a maturation process.     

Centriole size modifications during the cell cycle of the amoebae of the mxyomycete Physarum polycephalum

Anterior and posterior centrioles of Physarum amoebae are indistinguishable by their size during interphase but there is a correlation between the size of the two centrioles in the same amoeba. The interphase length of centrioles in diploid amoebae possessing only one pair of centrioles was 11% longer than in the case of the haploid strain. Treatment with taxol led to a 23 and 32% increase of the mean length in interphase and blocked mitosis, respectively. Conversely, during control mitosis the parental centrioles showed a 12% decrease of their mean length while the size of the daughter centrioles increased progressively. Neither nocodazole nor cold treatment induce a decrease of centriole length. The mean length of the cartwheel structure (internal proximal part) although constant during mitosis could be increased 24% in the presence of taxol. Similarly there was a correlation between the number of anterior satellites and the centriole length.     

Spatial relationships between centrioles and the centrosphere in monoasters induced by taxol inPhysarum polycephalum amoebae

Summary Monoasters induced by taxol in the amoebae of the MyxomycetePhysarum polycephalum show an unusual tridimensional location of the centrioles. Tridimensional reconstructions of individual monoasters with either two or four centrioles show that the position of centrioles is not random. The characteristics of these monoasters suggest that the centrioles are not linked to the mitotic center in the monoaster since mitotic centers completely devoid of centrioles in adjacent or central location are observed. However, the preferential centrifugal orientation of the centrioles in the centrosphere induced by taxol suggests that centrioles are initially located in the mitotic center in agreement with the attachment of the centrioles to the mitotic center during interphase.     

Fine structure of plasmodial nuclei in the slime moldPhysarum polycephalum I. Comparison of diploid and haploid vegetative mitosis

Summary The same basic ultrastructural features of interphase and mitotic nuclei were found for both the haploid Colonia and the diploid wild type strains of the myxomycete,Physarum polycephalum. Differences in nuclear size and chromocenter numbers were observed, but the nucleolar cycle and the intranuclear and acentriolar type of mitosis characteristic of the plasmodial stage of the diploid is present in haploid plasmodia, ruling out any relation between ploidy level and type of mitotic figure.     

The centriole cycle in the amoebae of the myxomycetePhysarum polycephalum

Summary In the amoebae of the myxomycetePhysarum polycephalum, procentrioles are formed on the anterior and posterior centrioles in early prophase. Although the relative position of the parental and procentrioles is fixed, all relative positions of the daughter and parental centrioles were observed. During the different stages of mitosis daughter centrioles elongate and acquire anterior satellites, one of the characteristic features of the anterior centrioles. All other anterior morphological characteristics appear only in telophase and early reconstruction stages. In contrast to the parental posterior centrioles, which do not change morphologically during the successive mitotic stages, the parental anterior centrioles lose their morphological characteristics in late prophase and early prometaphase and then acquire the morphological features characteristic of the posterior centrioles. Thus, the following maturation scheme is suggested: a procentriole becomes an anterior centriole during the first mitosis and a posterior centriole during the second mitosis. Since posterior features are maintained during mitosis, the posterior centriole corresponds to the final state of centriole maturation.     

The structure of the flagellar apparatus of the swarm cells ofPhysarum polycephalum

Summary Flagellation ofPhysarum polycephalum amoebae (Myxomycete) involves the formation around the two kinetosomes of a flagellar apparatus leading to a modification in the shape of the amoeba and its nucleus. A tridimensional ultrastructural model of the flagellar apparatus is proposed, based upon observation of the isolated nucleo-flagellar apparatus complex. The flagellar apparatus is composed of a non-microtubular structure (the posterior para-kinetosomal structure), five microtubular arrays and two flagella: a long anterior flagellum and a short flagellum directed backwards. The asymmetry of the flagellar apparatus is due mainly to the presence of the posterior para-kinetosomal structure on the right side of the posterior kinetosome and of the two asymmetrical microtubular arrays 3 and 4. Thus, the flagellar apparatus is right-handed. This asymmetry implies also some spatial constraints on two other microtubular arrays (2 and 5). Except in the case of the microtubular array 1 which links the proximal end of the anterior kinetosome to the nuclear membrane, the number of microtubules of each microtubular array seems to be well defined: 39, 5–6, 7–9, and 2+2 for the microtubular arrays 2, 3, 4, and 5 respectively. All the elements of the nucleo-flagellar apparatus complex are linked either directly or indirectly through bridges. Furthermore, the microtubules which composed the microtubular array 3 are linked through bridges while the microtubules of the microtubular arrays 2, 3, and 4 seem to be linked through a reticulate material. All these spatial relationships lead to a great cohesion of the nucleo-flagellar apparatus complex which appears to be a well defined structure. This suggests thatPhysarum amoebal flagellation can be a promising system to study the morphogenesis of an eucaryotic cell.Abbreviations PIPES Piperazine-N,N-bis [2-ethane-sulfonic acid] - EGTA [Ethylenebis(oxyethylenenitrile)]tetraacetic acid - DMSO Dimethyl sulfoxide     

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.     

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.     

Flow cytometry reveals a high degree of genomic size variation and mixoploidy in various strains of the acellular slime mold Physarum polycephalum

High-resolution flow cytometry, using avian erythrocytes as an internal standard, was employed to study constitutive genome size variation of G2-phase nuclei of Physarum polycephalum strains during the macroplasmodial stage of their life cycle. Our results document a previously unknown extent of genome size variation and mixoploidy in this organism. The unimodal diploid strain Tu 291 displayed the largest genome of the strains tested; in contrast, the Colonia strain displayed only half of the Tu 291 G2-phase fluorescence, confirming its haploid nature. An additional strain, derived from a recent cross between Lu897 and Lu898 amoebae, must have arisen by selfing (propagation of only one of the parental genomes to the macroplasmodial stage), since its nuclei display close to the haploid G2-phase DNA content. The observation of a small fraction of corresponding diploid nuclei within the haploid population of this strain, while maintained as microplasmodia, supports the notion that meiosis in haploid strains may require the presence of diploid nuclei. Two of the descendants of the prototype haploid Colonia strain, which were kept for extended periods of time in submerse culture, proved to be near diploid and mixoploid. Polyploidization and subsequent loss of DNA thus seems to contribute to the extremes of genome size variation in Physarum. In addition to unimodal fluorescence distributions, a number of diploid strains displayed bi- and even trimodal distributions within harvests of a single G2-phase macroplasmodium. Analysis of these mixoploid strains by means of gaussian curve-fitting suggests that the smaller genome size differences in Physarum may arise in step-wise diminution of DNA in approximate units of 3-5% of the original Tu 291 genome.     

Indirect immunofluorescent staining of the microtubules in interphase and mitotic amoebae of the myxomycetePhysarum polycephalum

Summary The microtubules ofPhysarum amoebae have been decorated with rat antibodies against yeast tubulin. The indirect fluorescent staining observed in interphase amoebae and in flagellated amoebae is consistent with the three-dimensional reconstructions previously deduced from electron microscopic studies. Mitotic amoebae exhibit a pattern of fluorescence which is similar to that exhibited by mammalian cells and is consistent with the previous electron microscopic studies, except that we also observe pole-pole microtubule fibers during metaphase and anaphase and the presence of a typical midbody during cytokinesis. The various types of tripolar mitosis which are observed suggest that there is a regulatory mechanism allowing the formation of pseudo-bipolar mitotic apparatuses in amoebae possessing more than two mitotic centers during mitosis. The mitotic center, located in the middle of the centrosphere, is not fluorescent after staining of the monoasters induced with taxol suggesting the absence of tubulin in the mitotic center.     

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.     

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     

The centriolar cycle in polykaryons containing prematurely condensed chromosomes or telophase-like nuclei]

In fused interphase-mitotic cells, either interphase nuclei are induced to premature chromosome condensation (PCC) or mitotic chromosomes are induced to telophase-like nuclei (TLN) formation. This study concerns structural and functional changes in centrioles of fused cells in which PCC or TLN are induced. Embryonic pig kidney cells were fused using a modified PEG-DMSO-serum method. Cell cycle period of the nuclei was determined before cell fusion using double-labeling autoradiography. Polykaryons containing desirable type of PCC or interphase nuclear combination in TLN were selected on the basis of isotope labeling after being embedded in epon. Selected cells were cut into serial sections and studied under electron microscope. The data obtained showed that centrioles at every interphase period undergo mitotic activation when their nuclei are induced to PCC. They acquire fibrillar halo and form half-spindles. Daughter centrioles at G1, S and G2 periods are also capable of mitotic activation when separated from their mother centriole. Inert centrioles were found in some cells with G1-PCC. When mitotic nuclei are induced to TLN formation, their centrioles also become inactivated. They lose fibrillar halo and mitotic spindles break down. Some mitotic centrioles develop features characteristic of interphase period such as satellites and vacuoles. Induced nuclear and centriolar changes are simultaneous and may be controlled by the same factor. Mitotic factor of mitotic cell partner which induces PCC may also induce interphase centrioles to mitotic activation. Degradation of the mitotic factor leading to TLN formation may also cause the loss of the mitotic activity of centrioles and disorganization of mitotic spindles.     

Correlation between the number of centrioles and ploidy of mouse liver hepatocytes

Using the electron microscope it was shown that in interphase hepatocytes with ploidies equal to 2n, 2n.2, 4n, 4n.2 and 8n, the number of centrioles per cell exactly corresponded to the ploidy of the cell. Both in mononuclear and binuclear cells all the centrioles are accumulated in one complex in which each pair of centrioles forms a diplosome. In binuclear cells, the complex of diplosomes is situated at equal distances from each nucleus, thus making the cell centre. The involvement of the supernumerous centrioles in polyploid metaphase cells was detected for the regenerating liver of old mice. It was found that each mitotic pole had at least four centrioles. In the pole, a pair of centrioles forms diplosomes tightly connected to each other. It is suggested that the initially tetraploid cell might divide in this manner. In addition, a question is discussed on how the existence of centrioles can be associated with the mechanism of polyploidization.     

Mutability of the LYS2 gene in diploid saccharomycete yeasts. I. The occurrence of spontaneous mutants and mutants induced by x-ray and ultraviolet radiation

More than 3000 spontaneous and induced lys2 mutants were obtained in haploid and diploid strains of yeast Saccharomyces. The ability to utilize alpha-aminoadipate was used for lys2 mutant screening. The spontaneous and induced mutation rates were measured in haploid and diploid strains. Mitotic segregation of pho1 marker linked to LYS2 was studied in lys2 mutants obtained in diploid strains. Fertility of diploid lys2 mutants was tested. The conclusion to be drawn from the data presented is that mutations appeared in one of two homologous chromosomes and then segregated by mitotic homozygotization.     

Comparative study of the effectiveness of selection in diploid and autotetraploid populations]

The mitotic activity and ploidy of cells of three strains of cellus tissue by the addition of the culture medium of 0,01; 0,1 and 1 mg/l of phytohemagglutinin was studied. These strains derived from the leaves of haploid, diploid, and tetraploid plants of Lycopersicon, esculentum. The number of dividing cells under the influence of phytohemagglutinin increased by 1;5 and 4% for haploid, diploid and tetraploid strains respectively. The shift of the peak of the mitotic activity at early stages of subculture under the effect of phytohemagglutinin was noticed. Phytohemagglutinin did not change the frequencies of cells of different ploidy in all the strains analysed. A weak mutagenic activity of phytohemagglutinin in the concentrations used was observed. Cells with single bridges were more frequently observed among the aberrant cells.     

Ultrastructural studies of the cell cycle in a multicentriolar form ofBracteacoccus minor (Chlorophyceae,Chlorellales)

Summary The ultrastructure of mitosis and cytokinesis is studied in the typical and a multicentriolar form of the multinucleate green algaBracteacoccus minor (Chodat) Petrovà. These processes are essentially identical in both forms, and are similar to those in other uni- and multinucleate chlorellalean algae. The mitotic spindle is closed and centric, and a fragmentary perinuclear envelope is present. In multinuclear cells mitosis is synchronous and may occur at the same time as cytokinesis. Cleavage is simultaneous and centrifugal, starting near the nucleus-associated centrioles and apparently mediated by phycoplast microtubules of the trochoplast type. Flagellated wall-less spores are usually formed. In the typical form ofB. minor, each interphase nucleus is associated with two mature centrioles (= one set) which function as centrosomal markers. At the onset of mitosis these centrioles duplicate and segregate and eventually establish the two poles of the spindle, where polar fenestrae develop in the nuclear envelope. In the multicentriolar form, however, each interphase nucleus generally is associated with two or three sets of centrioles. Consequently, during mitosis each half-spindle is associated with two or three sets. These centrioles are not necessarily all associated with the fenestrae at the spindle poles, but one or more sets are frequently associated with the nuclear membrane, more or less remote from the nuclear poles. However, the spindle in this multicentriolar form remains essentially bipolar. Cleavage generally results in zoospores with two, four or six flagella. The behaviour of the extra centrioles during the cell cycle and their possible relationship with centrosomes are discussed.     

Die Verteilung der Chromosomen auf die Tochterzellkerne multipolarer Mitosen in euploiden Gewebekulturen von Microtus agrestis

In kidney epithelial cultures from female Microtus agrestis, 3,55% of all mitoses are multipolar, 94% of them tripolar. Feulgen photometric measurements of 21 tripolar mitoses reveal a total DNA amount corresponding to the mitotic diploid value (4c) in 5 cases, and to the tetraploid value (8c) in 16 cases, Diploid tripolar mitoses divide into one daughter nucleus with a diploid DNA value (2c) and two nuclei each with a haploid DNA value (1c). Most tetraploid tripolar mitoses divide into one daughter nucleus with a diploid DNA value (2c) and two nuclei with a triploid DNA value (3c). Also the sex chromosomes are distributed to the daughter nuclei in the relation of 2∶3∶3. This can be seen in anaphase figures as well as in interphase nuclei presumably derived from tripolar mitoses, showing chromocenters according to the number of X-chromosomes. In two cases of tripolar tetraploid mitoses the resulting nuclei have a haploid, a triploid and a tetraploid DNA value. The DNA replication pattern is always identical in the daughter nuclei of diploid and tetraploid tripolar mitoses. — Our observations suggest segregation and distribution of haploid chromosome sets or multiples of haploid sets to the daughter nuclei of multipolar mitoses. They also show a possible way of formation of haploid and triploid cells in a basically diploid tissue. Presumably triploid nuclei (with 3 chromocenters) are capable of DNA synthesis.