Mapping the mating type locus of Tetrahymena thermophila: meiotic linkage of mat to the ribosomal RNA gene.

Tetrahymena thermophila has a multiple mating type system. While a sexually mature cell usually expresses only one mating type, its germline (micronucleus) carries the genetic potential for 5 to 7 mating types. The set of allowed mating types is specified by the mat locus. The choice of which particular mating type is expressed by a cell reflects a somatically inherited, developmentally programmed differentiation of the somatic nucleus (macronucleus). In this work we report that the mat locus maps to the left arm of chromosome 2, as determined by nullisomic deletion mapping. We also report a distance of 29 cM between the mat locus and the ribosomal RNA gene, previously mapped to chromosome 2L. This represents another (rare) case of meiotic linkage in Tetrahymena.     

Molecular Polymorphism in the MTA and MTB Mating Type Genes of Tetrahymena thermophila and Related Asexual Species

Each of the seven mating types of Tetrahymena thermophila is determined by a pair of large genes, MTA and MTB, whose expression peaks at early conjugation. Each protein consists of a mating‐type specific domain and a common transmembrane domain. To assess variation in natural populations, regions of both domains from wild isolates expressing mating types V and VII were analyzed. Corresponding regions of amicronucleates incapable of mating also were examined. MTA and MTB showed high haplotype diversity, with greater sequence variation in MTB. Mating type VII was less variable than mating type V, suggesting more recent origin. No polymorphism distinguished between mat1‐ and mat2‐like alleles encoding different arrays of mating types, nor did polymorphisms give evidence of population structure. MTA and MTB variants have different phylogenies, suggesting independent rather than concerted evolution, and are under weak purifying selection. Codon usage is less biased than for housekeeping genes, and reassigned glutamine encoding stop codons are preferentially used. Amicronucleate T. thermophila and closely related nsp15 and nsp25 have higher levels of nucleotide and amino acid substitution, consistent with cox1 distances. The results suggest that complete sequencing of mating type genes of wild isolates coupled with functional analysis will be informative.     

Deletion of the mating-type sequences in Podospora anserina abolishes mating without affecting vegetative functions and sexual differentiation

The mating-type locus of Podospora anserina controls fusion of sexual cells as well as subsequent stages of development of the fruiting bodies. The two alleles at the locus are defined by specific DNA regions comprising 3.8 kb for mat+ and 4.7 kb for mat–, which have identical flanking sequences. Here we present the characterization of several mutants that have lost mat+-specific sequences. One mutant was obtained fortuitously and the other two were constructed by gene replacement. The mutants are deficient in mating with strains of either mat genotype but are still able to differentiate sexual reproductive structures. The loss of the mating type does not lead to any discernible phenotype during vegetative growth: in particular it does not change the life span of the strain. The mutants can recover mating ability if they are transformed with DNA containing the complete mat+ or mat– information. The transformants behave in crosses as do the reference mat+ or mat– strains, thus indicating that the transgenic mat+ and mat– are fully functional even when they have integrated at ectopic sites.     

Mating type differentiation in Tetrahymena thermophila: Strong influence of delayed refeeding of conjugating pairs

Mating type differentiation in Tetrahymena thermophila is known to regularly involve stable hereditary alterations at a single chromosomal locus in the somatic (macro)nucleus. This differentiation is directionally affected by the temperature at which new macronuclei develop after fertilization. We now report large and predictable effects of delayed refeeding of conjugating pairs upon mating type differentiation, particularly among mat-2 homozygotes. The mating types whose frequency is affected the most are IV, VI, and VII, a set different from that most affected by temperature. We interpret our observations to reveal the existence of a second system which can participate in mating type differentiation, with different specificity from the system influenced by temperature under conditions of early refeeding of conjugating pairs. These observations enrich the phenomenology surrounding mating type differentiation in T thermophila and provide additional, easily controllable experimental conditions for the manipulation of mating type frequencies.     

Mating type differentiation in tetrahymena thermophila: Characterization of the delayed refeeding effect and its implications concerning intranuclear coordination

Mating type determination in Tetrahymena thermophila involves developmentally programmed, heritable alterations of the macronucleus, localized to the mtd locus. This determination can be predictably controlled by the environmental conditions during macronuclear development, eg, temperature and time of refeeding. In this article we have further characterized the effects of delayed refeeding on mating type determination, as revealed by the frequency of mating types among the progeny of a cross. Our results show that 1) the magnitude of this starvation effect decreases with temperature of conjugation and becomes undetectable at 18°C; 2) starvation during the interval 14 to 22 hr (after conjugation is induced at 30°C) is a necessary and sufficient condition for the induction of starvation effects; 3) relative mating type frequencies vary monotonically with nutrient concentration present during this critical period; and 4) sister macronuclei, developing under starvation conditions in the same cytoplasm, differentiate majority mating types characteristic of early or late refeeding; sister macronuclei show no apparent correlation with each other. On the basis of our observations on early and late refed cells, we propose that the composition of the newly developed macronucleus is the outcome of two key events: 1) mating type determination at the mtd locus and 2) differential molecular cloning of generally one or two autonomously replicating fragments (ARFs) of the macronuclear DNA bearing the mtd locus.     

Control of yeast cell type by the mating type locus: I. Identification and control of expression of the a-specific gene BAR1

The MATα allele of the yeast mating type locus confers the α mating phenotype and contains two complementation groups, MATα1 and MATα2. The α1–α2 hypothesis proposes that MATα1 is a positive regulator of α-specific genes and that MATα2 is a negative regulator of a-specific genes. According to this hypothesis, matα2 mutants, which are defective in mating and in production of extracellular α-factor, express both a-specific functions (because they lack MATα2 product) and α-specific functions (because they contain MATα1 product). Failure to produce extracellular α-factor results from antagonism between these functions; in particular, because α-factor (an α-specific function) is degraded by an a-specific function. If this view is correct, matα2 mutants should acquire the ability to produce α-factor if they also carry a defect in the gene(s) responsible for α-factor degradation. We have isolated a derivative of a matα2 mutant that produces α-factor and have characterized the suppressor mutation in this strain. (1) This strain carries a mutation (bar1-1) tightly linked to HIS6 (on chromosome IX) that allows matα2 mutants to produce α-factor. (2) It does not allow matα1 mutants to produce α-factor. (3) Haploids of the a mating type bearing the bar1-1 mutation still mate, but are unable to act as a barrier to the diffusion of α-factor. MATa bar1-1 cells display increased sensitivity to α-factor. (4) A mutation (sst1?2) that causes increased sensitivity to α-factor is allelic to bar1-1 and also allows α-factor synthesis by matα2 mutants. The ability of matα2 bar1 double mutants to produce extracellular α-factor indicates that matα2 mutants do produce α-factor but that it is degraded by the Barrier function. These results suggest that BAR1 is normally expressed only in a cells, and is negatively regulated in α cells by the MATα2 product.     

Control of cell type in yeast by the mating type locus: The α1-α2 hypothesis

We have extended the genetic analysis of four mutants carrying defective MATα alleles in order to determine how the mating type locus controls yeast cell types: a, a, and $\text{a}\text{α}$. First, we have mapped the defect in the mutant VC73 to the mating type locus by diploid and tetraploid segregation analysis. Second, we have determined that the mutations in these strains define two complementation groups, MATα1 and MATα2. The MATα1 gene is proposed to be a positive regulator of α mating functions. The MATα2 gene product is proposed to have two roles, as a negative regulator of a-specific mating functions and as a regulator of $\text{a}\text{α}$ cell functions (required for sporulation, for inhibition of mating and other processes). This view of MATα leads to the prediction that matα1^?matα2^? mutants should have the mating ability of an a cell and that matα1^?matα2^?/MATα strains should mate as α and be unable to sporulate. Such double mutants have been constructed and behave as predicted. We therefore propose that a-specific mating functions in MATa cells are constitutively expressed due to the absence of the MATα2 gene product and that α-specific mating functions are not expressed due to the absence of the MATα1 gene product.     

Mating-Type Polymorphic Variation in Euplotes minuta (Ciliophora: Hypotrichida)1

An investigation was carried out to probe into the mating-type structure of a local population of the marine ciliate, Euplotes minuta. From this population, nine different mating types belonging to a unique set were isolated. The nine type-representative wild stocks analyzed were found to be heterozygous at the mating-type (mat) locus and provided, together with their sexual progeny, a total of 15 pure mating types. In E. minuta, the high-multiple nature of the basic mating system controlled by a series of peck-order alleles at a single locus should be considered a virtual certainty. The relationships among the genetic economies of the similar bottom-dwelling marine ciliates of the genus Euplotes, the E. vannus-crassus-minuta group, are discussed.     

Comparative genomics of the mating-type loci of the mushroom Flammulina velutipes reveals widespread synteny and recent inversions

Background

Mating-type loci of mushroom fungi contain master regulatory genes that control recognition between compatible nuclei, maintenance of compatible nuclei as heterokaryons, and fruiting body development. Regions near mating-type loci in fungi often show adapted recombination, facilitating the generation of novel mating types and reducing the production of self-compatible mating types. Compared to other fungi, mushroom fungi have complex mating-type systems, showing both loci with redundant function (subloci) and subloci with many alleles. The genomic organization of mating-type loci has been solved in very few mushroom species, which complicates proper interpretation of mating-type evolution and use of those genes in breeding programs.

Methodology/Principal Findings

We report a complete genetic structure of the mating-type loci from the tetrapolar, edible mushroom Flammulina velutipes mating type A3B3. Two matB3 subloci, matB3a that contains a unique pheromone and matB3b, were mapped 177 Kb apart on scaffold 1. The matA locus of F. velutipes contains three homeodomain genes distributed over 73 Kb distant matA3a and matA3b subloci. The conserved matA region in Agaricales approaches 350 Kb and contains conserved recombination hotspots showing major rearrangements in F. velutipes and Schizophyllum commune. Important evolutionary differences were indicated; separation of the matA subloci in F. velutipes was diverged from the Coprinopsis cinerea arrangement via two large inversions whereas separation in S. commune emerged through transposition of gene clusters.

Conclusions/Significance

In our study we determined that the Agaricales have very large scale synteny at matA (∼350 Kb) and that this synteny is maintained even when parts of this region are separated through chromosomal rearrangements. Four conserved recombination hotspots allow reshuffling of large fragments of this region. Next to this, it was revealed that large distance subloci can exist in matB as well. Finally, the genes that were linked to specific mating types will serve as molecular markers in breeding.     

Control of yeast cell type by the mating type locus: II. Genetic interactions between MATα and unlinked α-specific STE genes

The alleles of the yeast mating type locus, MATα and MATa, determine the yeast cell types, a,α, and a/α. It has been proposed that the MATα2 product negatively regulates expression of unlinked a-specific genes, and that the MATα1 product positively regulates expression of unlinked α-specific genes. The behavior of mutants defective in MATα2, which are deficient in mating and in production of α-factor, can thus be attributed to antagonism between a-specific and α-specific functions expressed simultaneously in matα2^? strains. If this view is correct, then elimination by mutation of the specific functions required to mate as α may allow matα2 mutants to mate as a. In order to test this possibility, we examined the interactions between matα2 mutations and various unlinked mutations that cause α cells but not a cells to be mating defective (α-specific STE mutations). Three α-specific mutations (ste3, ste13 and kex2) were found to be non-allelic. Furthermore, although matα2 mutants mate weakly as a, matα2, ste3 double mutants, but not matα2 ste13 or matα2 kex2 double mutants, mate efficiently as a. The ability of matα2 ste3 strains to mate as a supports the view that matα2 mutants express a-specific mating functions, and suggests that a mating functions are expressed constitutively in MATa cells. The mating behaviour of the matα2 ste3 double mutant is consistent with the proposal that STE3 is positively regulated by the MATα1 product.     

Deletion of the mating-type sequences in Podospora anserina abolishes mating without affecting vegetative functions and sexual differentiation

The mating-type locus of Podospora anserina controls fusion of sexual cells as well as subsequent stages of development of the fruiting bodies. The two alleles at the locus are defined by specific DNA regions comprising 3.8 kb for mat+ and 4.7 kb for mat?, which have identical flanking sequences. Here we present the characterization of several mutants that have lost mat+-specific sequences. One mutant was obtained fortuitously and the other two were constructed by gene replacement. The mutants are deficient in mating with strains of either mat genotype but are still able to differentiate sexual reproductive structures. The loss of the mating type does not lead to any discernible phenotype during vegetative growth: in particular it does not change the life span of the strain. The mutants can recover mating ability if they are transformed with DNA containing the complete mat+ or mat? information. The transformants behave in crosses as do the reference mat+ or mat? strains, thus indicating that the transgenic mat+ and mat? are fully functional even when they have integrated at ectopic sites.     

Control of yeast cell type by the mating type locus: Positive regulation of the α-specific STE3 gene by the MATα 1 product

The mating type locus (MAT) determines the three yeast cell types, a, α, and a/α. It has been proposed that alleles of this locus, MATa and MATα, encode regulators that control expression of unlinked genes necessary for mating and sporulation. Specifically, the α1 product of MATα is proposed to be a positive regulator of α-specific genes. To test this view, we have assayed RNA production from the α-specific STE3 gene in the three cell types and in mutants defective in MATα. The STE3 gene was cloned by screening a yeast genomic clone bank for plasmids that complement the mating defect of ste3 mutants. Using the cloned STE3 gene as a probe, we find that a cells produce STE3 RNA, whereas a and a/a cells do not. Furthermore, matα 1 mutants do not produce STE3 RNA, whereas matα 2 mutants do. These results show that the STE3 gene, required for mating only by α cells, is expressed only in α cells. They show also that production of RNA from the STE3 gene requires the α1 product of MATα. Thus α1 positively regulates at least one α-specific gene by increasing the level of that gene's RNA product.     

Ecological Genetics of Tetrahymena thermophila: Mating Types, i-Antigens, Multiple Alleles and Epistasis

Until recently, Tetrahymena thermophila has rarely been isolated from nature. With improved sampling procedures, T. thermophila has been found in ponds in many northeastern states. The availability of resident populations makes possible both population and ecological genetic studies. All seven known mating types have been recovered; no eighth mating type has been found. Crosses among whole-genome homozygotes derived from Pennsylvania isolates reveal a spectrum genotypes with mating type alleles resembling traditional A (IV- and VII-) and B(I-) categories. The genotypes differ significantly with respect to mating type frequency, both among themselves and from previously described genotypes. One A-category genotype appears to lack mating type II, while one A-category and all B-category genotypes have low frequencies of mating type III, thus accounting for the low frequency of III in the pond. The low frequency of III in all five B-category genotypes examined suggests that the founding allele in this region was low for III. These and other differences are discussed both in terms of mating type frequencies in the pond and in terms of the possible molecular structure of mat alleles. By contrast, numerous variants of the cell surface immobilization antigen are found in addition to the previously described i-antigens. Variants of the known SerH alleles include those with restriction fragment length polymorphisms and temperature sensitivity as well as alleles with new antigenic specificity. Multiple alleles are present in single ponds. Genes exhibiting serially dominant epistasis over SerH genes also are found. In two instances (K and C), families of antigenically similar polypeptides are expressed in place of H i-antigen. Molecular weight differences suggest that these paralogous i-antigen genes evolve by gene duplication and unequal crossing over within central repeats. The existence of complex patterns of epistasis together with seasonal changes in i-ag frequencies suggest that i-ag play an important, but as yet unknown, ecological role related to the occurrence of frequent conjugation.     

Sex-linked transcriptional divergence in the hermaphrodite fungus Neurospora tetrasperma

In the filamentous ascomycete Neurospora tetrasperma, a large (approx. 7 Mbp) region of suppressed recombination surrounds the mating-type (mat) locus. While the remainder of the genome is largely homoallelic, this region of recombinational suppression, extending over 1500 genes, is associated with sequence divergence. Here, we used microarrays to examine how the molecular phenotype of gene expression level is linked to this divergent region, and thus to the mating type. Culturing N. tetrasperma on agar media that induce sexual/female or vegetative/male tissue, we found 196 genes significantly differentially expressed between mat A and mat a mating types. Our data show that the genes exhibiting mat-linked expression are enriched in the region genetically linked to mating type, and sequence and expression divergence are positively correlated. Our results indicate that the phenotype of mat A strains is optimized for traits promoting sexual/female development and the phenotype of mat a strains for vegetative/male development. This discovery of differentially expressed genes associated with mating type provides a link between genotypic and phenotypic divergence in this taxon and illustrates a fungal analogue to sexual dimorphism found among animals and plants.     

The trans action of HMRa in mating type interconversion

Summary HML and HMR are the sites of cryptic mating type genes in the yeast Saccharomyces cerevisiae. In the presence of the HO gene, the information from HML or HMR (an a or cassette) is transferred to the mating type locus (MAT). HML, HMR, and MAT are located on chromosome III, yet are widely separeted. Similarly, in other yeasts, at least some of the genes involved in mating type interconversion are linked to the mating type locus. We demonstrate here that a cassette donor (HMR) and the cassette target (MAT) need not be physically linked for successful mating type interconversion. In particular, we show that HMR a on one chromosome can donate an a cassette to the mating type locus on a homologous chromosome III.     

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.     

Cloning and analysis of the mating type genes from Cochliobolus heterostrophus

Cochliobolus heterostrophus, a heterothallic Ascomycete, has a single mating type locus with two alternate forms called MAT-1 and MAT-2. MAT-1 was cloned by complementing a MAT-2 strain using a cosmid library from a MAT-1 strain and screening for a homothallic transformant. The cosmid recovered from this transformant was able to re-transform a MAT-2 strain to homothallism and MAT identity was proven by restriction fragment length polymorphism and conventional genetic mapping. All homothallic transformants could mate with either MAT-1 or MAT-2 strains, although the number of ascospores produced by self matings or crosses to MAT-2 strains was low. Progeny of selfed homothallic transformants were themselves homothallic. MAT-2 was cloned by probing a cosmid library from a MAT-2 strain with a fragment of insert DNA from the MAT-1 cosmid. A 1.5 kb subclone of either MAT-containing cosmid was sufficient to confer mating function in transformants. Examination of the DNA sequence of these subclones revealed that MAT-1 and MAT-2 contain 1297 by and 1171 bp, respectively, of completely dissimilar DNA flanked by DNA common to both mating types. Putative introns were found (one in each MAT gene) which, when spliced out, would yield open reading frames (ORFs) that occupied approximately 90% of the dissimilar DNA sequences. Translation of the MAT-1 ORF revealed similarity to the Neurospora crassa MATA, Podospora anserina mat–, and Saccharomyces cerevisiae MAT1 proteins; translation of the MAT-2 ORF revealed similarity to the N. crassa MATa, P. anserina mat+, and Schizosaccharomyces pombe mat-Mc proteins. These gene products are all proven or proposed DNA binding proteins. Those with similarity to MAT-2 are members of the high mobility group.The first three authors contributed equally to the work     

What is a bona fide mating-type gene? Internuclear complementation of mat mutants in Podospora anserina

In the heterothallic ascomycete Podospora anserina, the mating-type locus is occupied by two mutually exclusive sequences termed mat+ and mat–. The mat+ sequence contains only one gene, FPR1, while the mat– sequence contains three genes: FMR1, SMR1 and SMR2. Previous studies have demonstrated that FPR1 and FMR1 are required for fertilization. Further analyses have led to the hypothesis that mat+ and mat– genes establish a mat+ and mat– nuclear identity, allowing recognition between nuclei of opposite mating type within the syncytial cells formed after fertilization. This hypothesis was based on the phenotypes of strains bearing mutations in ectopic mat genes. Here we present an analysis of mutations in resident mat– genes which suggests that, unlike FMR1 and SMR2, SMR1 is not involved in establishing nuclear identity. In fact, mutations in these two genes impair nuclear recognition, leading to uniparental progeny, while mutations in SMR1 block the sexual process, probably at a step after nuclear recognition. The nuclear identity hypothesis has also been tested through internuclear complementation tests. In these experiments, the mat– mutants were crossed with a mat+ strain carrying the wild-type mat– genes. Our rationale was that internuclear complementation should not be possible for nuclear identity genes: the relevant genes should show nucleus-restricted expression, and diffusion of their products to other nuclei should not occur. This test confirmed that SMR1 is not a bona fide mat gene since it can fulfill its function whatever its location, in either a mat− or a mat+ nucleus, and even when present in both nuclei. SMR2, but not FMR1, behaves like a nuclear identity gene with respect to internuclear complementation tests. A model is proposed that tentatively explains the ambiguous behaviour of the FMR1 gene and clarifies the respective functions of the three mat– proteins. Received: 15 October 1996 / Accepted: 25 April 1997