Mating Types in Glaucoma scintillans

SYNOPSIS. Two sexually isolated varieties or syngens of Glaucoma scintillans have been found in Japan. Each of these includes 8 (or 9) mating types, any one of which can conjugate with the other 7 (or 8). Under appropriate conditions, a high percentage of the animals in a mixture of 2 mating types of the same syngen underwent conjugation. Conjugating pairs appeared to be formed only between animals of different mating types. In a few combinations, inter-syngenic conjugation (usually in less than 5% of the animals) was seen. Neither selfing nor autogamy was seen. Clones from conjugants pass thru a long period of immaturity and a period of adolescence before attaining full maturity. Limited observations indicated that inheritance of mating types is synclonal. Nuclear reorganization processes during conjugation are similar to those reported for Tetrahymena pyriformis.     

Methods for Inducing Selfing, Selfing and Its Role in the Life Cycle of Euplotes woodruffi syngen 3 (Ciliophora)

Methods for inducing selfing, and the relation between selfing and the life cycle of Euplotes woodruffi syngen 3 are reported. Three intercrossing stocks were used in this experiment. Selfing was induced with several treatments as follows: cell-free fluid from the cultures of complementary mating types; intact cells of GI or S phase in the cell cycle; heat-killed cells, and lysed cells of GI-, S-, and D-phase cells which were prepared by freeze-thawing. Stock SJ-27 was used as a parental stock from which Fl clones were originated through selfing. The other two stocks, SJ-8 and SJ-19, were used as testers. The period of immaturity varied from clone to clone. The heterotypic conjugation of clones with cells of stock SJ-8 seems to occur earlier in the life cycle than with cells of stock SJ-19. This result shows that this syngen has an adolescent period in the life cycle. The length of selfing immaturity seems to be different from that of crossing immaturity, and selfing appeared slightly later than crossing with testers. But the clones in which selfing 1st occurred are considered to be in adolescence or maturity, not in senility. Once selfing appeared in any clone, the clone continued to produce selfing pairs till just before clonal death. The viability of selfing and of outcrossing were compared and found not significantly different. Inbreeding depression took place in some of the F2 clones by successive selfing. The viability of F2 clones from young parents was significantly higher than that from old parents (220 to 230 fissions) both in selfing and outcrossing. The total life spans which were studied in three F1 clones were 168 to 264 fissions.     

Abnormalities in Nuclear Behavior and Mating Type Determination in Cytoplasmically Bridged Exconjugants of Doublet Paramecium aurelia*

Exconjugant clones of Paramecium aurelia stock 51S, syngen 4, which fail to separate prior to the 1st fission have numerous cytologic and mating type determination anomalies. The doublets have abnormal distribution of macronuclear anlagen, fewer macronuclear fragments per cell, and abnormalities in numbers of micronuclei. Despite apparent cell fusion and mixture of cytoplasm, the singlets arising from each side of the doublet may be of opposite mating types, and mating type determination may remain unstable for 1 or more fissions in contrast to the usual pattern of mating type determination before the 1st postconjugation fission.     

MOLECULAR DELINEATION OF SPECIES AND SYNGENS IN VOLVOCACEAN GREEN ALGAE (CHLOROPHYTA)1

Two species of the colonial green flagellate family Volvocaceae are worldwide in distribution yet exhibit contrasting species structure. Geographically disparate isolates of Gonium pectorale Mueller can interbreed while isolates of Pandorina morum Bory behave quite differently. More than 20 sexually isolated subpopulations occur within this species; these have been termed “syngens” (sensu Sonneborn). Because prezygotic barriers to mating cause intersyngen pairings to fail, breeding analyses cannot be used to estimate genetic relatedness among the syngens of P. morum. DNA comparisons provide an alternative method of assessing genetic relatedness. We compared the nucleotide sequence of the internal transcribed spacer (ITS) region of the nuclear ribosomal repeat among clones of P. morum and of G. pectorale. Members of syngens of P. morum with distribution restricted to one small geographical area show great similarity. Likewise, members of any syngen of worldwide distribution show near uniformity, even those from different continents. However, the ITS sequence of each syngen differs from that of other syngens. In contrast, G. pectorale, which has an ITS region that is remarkably uniform throughout the world, appears to consist of a single syngen within North America and Europe by mating tests. The molecular data are in complete conformity with previous syngen assignment. Because the latter is based on mating affinity, with two complementary mating types per syngen, the evolution of new mating type pairs appears to be the basis of microevolution in these algae. We infer that either P. morum is a more ancient species than G. pectorale or that P. morum has a less stable genome. In either case, the biogeographic distribution of certain syngens may reflect climatological changes of the past.     

Induction of Competence for Mating in Tetrahymena by Cell-Free Fluids

SYNOPSIS. Cell-free fluid from sexually reactive cultures of Tetrahymena pyriformis, syngen 7 can induce mating in otherwise unreactive mixtures of cells of 2 mating types. Rare individual cells may initiate the production of this substance, but once it is produced, the entire culture becomes sexually reactive.     

Mating Types, Breeding System, Conjuàtion and Nuclear Phenomena in the Marine Ciliate Euplotes cristatus Kahl from the Gulf of Naples

SYNOPSIS. The marine ciliate Euplotes cristatus Kahl (Ciliophora, Hypotrichida), collected off Capri, Gulf of Naples, is described in detail. From populations, 6 different mating types, representing 1 variety or syngen, have been isolated. The breeding relations revealed a multiple mating type system characteristic of other members of the Hypotrichida that have been investigated. Presumably a 7th mating type was found which does not mate with any of the others. Although this may belong to another syngen, it could represent a mating type which has not yet reached sexual maturity or 1 which may be in a period of decline. Animals of different mating type do not mate immediately after being mixed but usually 3 or more hours later. An agglutination reaction involving many specimens is absent. Instead, 2 ciliates engage in a “pairing play” before joining firmly in conjugation. Well-fed or actively feeding and dividing ciliates do not mate; mating occurs only after the food becomes gradually depleted or when the food supply is sharply cut off. All mating types appear to be extremely stable. Neither selfing pairs (intraclonal conjugation) nor autogamy have been observed within any clonal culture during the several years under investigation. Cell-free filtrates from 1 mating type do not elicit mating or induce conjugation with specimens of a different mating type. The general pattern of nuclear events in conjugation and exconjugant reorganization is as follows: 1 preliminary division, 3 pregamic (prezygotic) divisions, fertilization, and generally 1 or occasionally 2 postzygotic divisions. The fate of micronuclear products may be determined by their size and location. Those which are larger and close to the cell membranes of the joined conjugants persist and/or divide. Those which are smaller are carried by cyclosis toward the center of each ciliate and degenerate. The degenerating macronucleus of each conjugant becomes segmented in a more or less uniform manner resulting in 4 subspherical masses. Two become localized in the anterior end of a conjugant and 2 in the posterior end. Those in the posterior end are always the first to degenerate completely and disappear. In nuclear reorganization of the exconjugant, fusion of the macronuclear anlage with parts of the old macronucleus does not occur.     

Mating Types and Mating Type Inheritance in Euplotes minuta Yocom (Ciliata, Hypotrichida)

SYNOPSIS. Thirty-one stocks of a marine ciliate, Euplotes minuta Yocom, collected from different localities, can be grouped in seven mating types. True pairs are formed only in mixtures of stocks belonging to different mating types. No selfing pairs or intraclonal conjugation have ever been observed. Synclonal inheritance of mating types is the rule, although about 10% of pairs show clonal inheritance. The latter can be explained by assuming syncaryon formation through cytogamy or through caryogamy of pronuclei derived from different products of meiosis. Mating type determination is due to 7 alleles at the single locus mt . There is complete dominance among the 7 alleles which can be orderly seriated, as shown in Table 3, according to their dominance relationship. The 5 stocks, and only these 5, of mating type VII have the autogamy trait. The mortality rate in F₁ and F₂ is very low–a maximum of 10%; however, the F₂'S obtained by autogamy from F₁ progenies in which mating type VII is involved have a very high mortality rate. The two facts (high mortality rate in F₂ and strict association of autogamy trait with mating type VII in natural populations) have been considered as evidences of a probable isolation mechanism existing between mating type VII and the other 6 mating types. Thus, the 7 mating types have been assigned to the same syngen only tentatively.     

A SIMPLIFIED,RAPID METHOD FOR IDENTIFYING MATING TYPE IN ALGAE: RESULTS WITH THE PANDORINA MORUM (CHLOROPHYCEAE) SPECIES COMPLEX1

As a collection expands, increasing numbers of test crosses are required to identify new isolates in algal species containing numerous pairs of mating types. A short-cut is described that utilizes a reduced number of preliminary test crosses. The method was used successfully with the colonial green flagellate, Pandorina morum Bory de St. Vincent, to identify a new pair of milling types (syngen) from Japan and five new isolates from China of a previously known syngen. When tested on the 20 previously described syngens, it revealed one unexpected multi-clone effect on mating. The method should be valuable for identifying newly collected clones, examining potential, interactions among incompatible mating types, and for screening other highly specific inter-organism interactions such as host-parasite infections.     

The Exchange of RNA and Protein During Conjugation in Tetrahymena*

SYNOPSIS. Exchange of cytoplasm in Tetrahymena pyriformis, syngen 1, has been demonstrated by growing cells of 1 mating type in medium supplemented with H³-uridine or H³-histidine, washing, mixing with cells of an unlabeled, starved mating type, sampling conjugants at different times, and preparing autoradiographs. It was found that cytoplasmic interchange begins soon after the mates unite, and has become extensive before the end of the 1st prezygotic prophase (micronuclear crescent stage). When the RNA in one mating type had been labeled with H³-uridine, the activity was distributed almost evenly between the mates by late stages of conjugation. These results are consistent with electron micrographs of this syngen showing small pores in the attachment region of the mates, and many free ribosomes in the cytoplasm (8,11). By contrast, when protein in one mating type had been labeled with H³-histidine, these cells at late conjugation remained about twice as active as their originally unlabeled mates, presumably because of the physical characteristics of some structures which incorporated the amino acid (for example, cilia and membranes of the cell surface; cytoplasmic bodies, such as mitochondria, larger than the pores). That the radioactivity in the originally unlabeled cells came from their mates and not from the environment is indicated by the continued presence of inactive non-conjugants after 1 and 2 days in the mating type mixtures. Other cells which did acquire small amounts of active cytoplasm probably had engaged in abortive conjugation, separating from labeled mates before forming and exchanging pronuclei.     

Spontaneous Selfing (Intraclonal Conjugation) in the Ciliate Euplotes patella Syngen 2 Takes Place without a Change in Mating Type Expression

ABSTRACT. Cells of Euplotes patella syngen 2 have been found to excrete mating-type-specific gamones (mating-inducing factors) into the surrounding medium. In strains of E. patella syngen 2, intraclonal conjugation (selfing) sometimes occurred spontaneously. Cell-free fluids of clonal cultures in which spontaneous selfing occurred were not effective in inducing homotypic pair formation in other cultures of the same mating type as the culture from which the cell-free fluids were derived. This indicates that selfing cultures produce only those gamones expected of their own mating types. This result suggests that spontaneous selling in E. patella syngen 2 is not due to change of mating type expression. The possible mechanisms for spontaneous selfing in E. patella syngen 2 are discussed.     

Mating Type Determination in Stock 51, Syngen 4 of Paramecium aurelia Grown in Axenic Culture*

SYNOPSIS. The use of axenic medium permits the study of mating type determination in stock 51 (sensitive) of syngen 4 of Paramecium aurelia. A high frequency of cytoplasmically bridged pairs was correlated with a high frequency of change of mating type following conjugation in axenic medium. The direction of change was predominantly from mating type VII to mating type VIII, suggesting a dominance of type VIII cytoplasm in the clones arising from a mixed cytoplasmic ancestry. No significant effect of either lower temperature or of N_aX₃ upon the pattern of mating type determination was found. The high frequency of cytoplasmic bridges between conjugants led to the formation of many double or higher multiplex clones.     

A SEX DETERMINING MECHANISM IN THE CLOSTERIUM EHRENBERGII (CHLOROPHYTA) SPECIES COMPLEX1

Homozygous mt^?/mt^? diploid clones of the Closterium ehrenbergii Menegh. ex Ralfs species complex were obtained by hypertonic treatment from minus vegetative cells, and mating type segregation ratios in the F₁ progeny of “triploid” zygospores between wild type mt⁺ haploid and mt^?/mt^? homozygous diploui were analyzed. The ratio of plus to minus individuals was 1:4.8, and the ratio of the pairs of opposite mating types to those of minus mating type was 1:2.1. The results clearly show that mt^? is dominant to mt⁺ and that the mating type inheritance in these zygospores follows the triploid-like pattern. The validity of our assumption that the two mating types are determined by one genetic factor (mt^? allele dominant) was confirmed in B₁ progeny analyses as well. The results suggest that this sex determining mechanism is working effectively in the C. ehrenbergii species complex, in which several biological species have evolved through polyploidization.     

Genes Controlling Mating-Type Specificity in PARAMECIUM CAUDATUM: Three Loci Revealed by Intersyngenic Crosses

In mating interactions in Paramecium caudatum, initial mating agglutination is strictly mating-type specific, but subsequent conjugating pair formation is not mating-type specific. Using this nonspecificity of pair formation, intersyngenic (intersibling species) pairs were induced by mixing four mating types of two different syngens. To distinguish intersyngenic pairs from intrasyngenic ones, the behavioral marker CNR (Takahashi 1979) was mainly used. Clones of intersyngenic hybrids showed high fertility and thus made feasible a genetic analysis of syngenic specificity of mating type. The syngenic specificities of E (even) mating types were found to be controlled by co-dominant multiple alleles at the Mt locus, and those of O (odd) mating types by interactions of co-dominant multiple alleles at two loci, MA and MB. Clones of heterozygotes express dual mating types. Mt is epistatic to MA and MB, and thus O mating types can be expressed only in the recessive homozygote (mt/mt) at the Mt locus. In addition, at least one allele each at the MA and MB loci must have a common syngen specificity for the expression of O types. Thus, when MA is homozygous for one syngen and MB is homozygous for another syngen, no mating type is expressed.     

CHLOROPLAST INHERITANCE IN COSMARIUM TURPINII BRÉB.

Chloroplast inheritance was studied in Cosmarium turpinii Bréb. with respect to both vegetative and zygotic transmission. Analyses were carried out on (1) reciprocal haploid x diploid crosses with respect to the number and size of the zygotic chloroplasts, (2) differential survival of chloroplasts in hypnospores of different mating type strains, and (3) the position of the chloroplasts in diploid zygotes. Morphological evidence indicates that the chloroplasts in the mature zygote are derived from the (+) mating type gamete with an infrequent contribution from the (–) mating type gamete. Additional evidence suggests that the chloroplast material of each of 2 Bones arising from the zygote is derived from the plastid material of a semicell of a gamete. Differential survival of the chloroplasts is interpreted as a result of physiological differences between cells of complementary mating types.     

Mutational Analysis of Mating Type Inheritance in Syngen 4 of PARAMECIUM AURELIA

Six genic mutations restricting clones to mating type VII (O) were isolated in syngen 4, Paramecium aurelia. The only three extensively tested were neither allelic nor closely linked. A second type of mutation, allelic to one of the O restricted mutants, was also found. Clones homozygous for this mutant gene were selfers, producing both O and E (VIII) mating types, but only when they were progeny of mating type E parental clones. While all seven mutant genes behaved as recessives in monohybrid crosses, clones heterozygous at two different loci often demonstrated an unanticipated phenotype: selfing. The significance of the findings is discussed in relation to mating type determination and the evolution of mating type systems.     

Mating-Type Inheritance and Maturity Times in Crosses between Subspecies of TETRAHYMENA PIGMENTOSA

Subspecies 6 and 8 of T. pigmentosa (formerly syngens 6 and 8 of T. pyriformis) share a mating-type system controlled by three alleles with "peck-order" dominance at a single locus. The system is apparently closed and limited to three mating types that are homologous, but not identical, in the subspecies. These relationships are reflected in new mating-type designations.—The viability in some intersyngenic crosses is excellent, and the inheritance of major mating types in first-generation hybrids and their progeny follows the pattern of subspecies 8.—The period of immaturity is shorter than that previously reported for subspecies 8, with 50% of the subclones maturing between 46 and 100 fissions after conjugation. Maturity curves are generally sigmoid, but some are apparently biphasic. The onset of maturity in triplicate sublines from the same synclone is usually highly correlated.     

Life Cycle of Paramecium bursaria Syngen 1 in Nature

ABSTRACT. Studies were completed on the natural population density of Paramecium bursaria syngen 1 and on the life cycle stages to which the individuals belonged. Green paramecia were collected from two streams once every 20 days for over one year: 413 individuals on 26 collection dates in Mikumarikyo stream and 83 individuals on 23 collection dates in Momijidani-gawa stream. Individuals in nature did not maintain at a steady density but fluctuated greatly depending on the month. It seems that conjugation occurred from April to June in the Mikumarikyo stream and from May to June in the Momijidani-gawa stream. The appearance of individuals with mating ability might be related closely to increasing population so that sexual reproduction probably occurred near the peak of the population density. The 413 individuals from Mikumarikyo stream were examined to determine their position within the life cycle; 309 (74%) were immature, 55 (13%) were adolescent, and 49 (12%) were mature. No senile individuals were observed. The fraction of individuals with mating ability was generally less than 30% at any collection. Four mating types were observed occurring with about equal frequencies in mature individuals. The results show the frequencies of the recessive genes for mating types (a and b) are higher than for dominant genes (A and B). Of 83 individuals from Momijidani-gawa stream, 44 (52%) were immature, 21 (25%) were adolescent, and 18 (21%) were mature. Again, no senile individuals were observed. Because only two mating types were found, II and III (genotypes aaB- and aabb), it seems possible that the dominant gene A was rare or absent in the Momijidani-gawa population.     

Intersyngenic variations in the esterases of axenic stocks of Paramecium aurelia

The esterase isozymes were surveyed in axenic stocks of syngens 1, 2, 4, 5, 6, and 8 of Paramecium aurelia by starch gel electrophoresis. In paramecia there appear to be four types of esterases which are clearer in axenic than in bacterized stocks. Each type differs in its substrate specificity and/or its response to the inhibitor eserine sulfate. Minor variations in type D esterases sometimes occur in different extracts of the same stock and may result from changes in the temperature of growth of the cells or growth cycle differences. Differences in the mobility of the A, B, or C (cathodal) types of esterases may occur in different syngens. They also occur for the A and B types among stocks within a syngen, but the frequency is low, except in the case of syngen 2. Since each of the types of esterases varies independently, at least four and possibly more genes appear to specify the esterases in the species complex. Some pairs of syngens vary in their electrophoretic positions for all types of esterases. Other pairs have identical zymograms. This observation suggests that some syngens may differ from each other by as many as four esterase genes, while others may not differ at all. The difference between P. aurelia and Tetrahymena pyriformis in the degree of intrasyngenic variation observed for enzymes is discussed in relation to other types of characters, the organization of the genetic material in the macronucleus, the presence of symbionts, and their breeding systems. It is suggested that enzyme variation is achieved by the action of different selective forces in these two groups of ciliated protozoa.Supported by research grants from the National Institute of General Medical Sciences (GM-15879), U.S. Public Health Service, and from the British Medical Research Council.     

Intimate Relationship between mtDNA, Plasmids, and the Fusion of Mitochondria

Physarum polycephalum. The conformation of Physarum mtDNA is currently thought to be circular. The inheritance of its mtDNA depends on the multiallelic mating type loci, matA. In a cross with ordinary matA combinations, the strain that has the higher matA status transmits its mtDNA to the progeny (uniparental inheritance). The mF plasmid promotes the fusion of mitochondria in the zygote and during sporulation. When it exists in a strain with a lower status matA, the mF plasmid overcomes the force of uniparental inheritance and is preferentially transmitted to the progeny via mitochondrial fusion. Moreover, the conformation of mtDNA is changed from circular to linear by recombination with the mF plasmid. Since biparental inheritance usually occurs in a cross involving a combination of matA1 and matA15, two types of inheritance of Physarum mtDNA exist. Considering the existence of the mF plasmid, there are four patterns of cytoplasmic inheritance in P. polycephalum: 1) uniparental inheritance of mtDNA, 2) uniparental inheritance of mtDNA and preferential transmission of the mF plasmid, 3) biparental inheritance of mtDNA, and 4) biparental inheritance of mtDNA and the mF plasmid. This article describes the events involved in each pattern. Finally, we discuss a hypothetical mechanism for mitochondrial fusion. The essential protein may be the ORF640 protein encoded in the mF plasmid. Received 8 March 2000/ Accepted in revised form 23 March 2000