A chromosome assay method for the detection of heterokaryon incompatibility (het) genes operating between members of different heterokaryon compatibility (h-c) groups in Aspergillus nidulans

Protoplast fusion has made possible the isolation of a diploid strain from haploid parents belonging to heterokaryon compatibility (h-c) groups Q and Gl of Aspergillus nidulans. This diploid was not fully heterokaryon compatibility tests conducted between selected pairs of parasexually derived progeny strains facilitated a chromosome assay method for the detection of heterokaryon incompatibility (het) genes. Despite the lack of segregation for the linkage group VI marker, it proved possible to locate het genes on linkage groups III, V, VI and VII. Backcross data detected five het gene differences operating between the h-cQ and h-cGl parental strains. Two het loci were located on linkage group III.     

Ultraviolet Light-Induced Heterokaryon Formation and Parasexuality in Cryphonectria parasitica

Rizwana, R., and Powell, W. A. 1995. Ultraviolet light-induced heterokaryon formation and parasexuality in Cryphonectria parasitica. Experimental Mycology 19, 48-60. The effect of ultraviolet-light on heterokaryon formation, vegetative compatibility, and parasexuality in Cryphonectria parasitica was examined. Heterokaryons of complementary auxotrophic strains could not be made by hyphal anastomosis if the strains belonged to different vegetative compatibility groups. Protoplast fusions overcame incompatibility of strains differing in the alleles of a single but not multiple vegetative incompatibility loci. Fusion of protoplasts from ultraviolet light-treated complementary auxotrophs increased heterokaryon formation by 10⁴ to 10⁵ using the strains differing in alleles of a single vegetative incompatibility gene but had no detectable effect on strains differing in multiple vegetative incompatibility genes. Vegetative compatibility tests of single conidial isolates resolved from these heterokaryons suggest that diploids had formed followed by the loss of one of the VIC alleles. Presence of both auxotrophic markers in some of these single conidial isolates confirms the occurrence of a parasexual cycle. These experiments demonstrate that ultraviolet-light can enhance heterokaryon formation and parasexuality in C. parasitica .     

Molecular and functional analyses of incompatibility genes at het-6 in a population of Neurospora crassa

Two closely linked genes, un-24 and het-6, associated with the het-6 heterokaryon incompatibility functional haplotype were examined in 40 Neurospora crassa strains from a Louisiana sugarcane field. Partial diploid analyses were used to determine that half of the strains were functionally Oak Ridge (OR) and half were non-OR and indistinguishable from the standard Panama (PA) form. PCR-based markers were developed to identify polymorphisms within both un-24 and het-6. Two common forms of each gene occur based on these molecular markers. Rare forms of both un-24 and het-6 were identified as variants of the non-OR form by a DNA transformation assay. The heterokaryon incompatibility function of haplotypes, based on partial diploid analyses, was perfectly correlated with the PCR-based markers at both loci. This correlation indicates that the two loci are in severe linkage disequilibrium in this population sample and may act as an incompatibility gene complex. Southern hybridizations using OR- and PA-derived cloned probes from the region that spans un-24 and het-6 showed that the apparent absence of recombination in this approximately 25-kbp region is associated with low levels of overall sequence identity between the PA and OR forms.     

Control of mating type heterokaryon incompatibility by the tol gene in Neurospora crassa and N. tetrasperma.

The mating-type of Neurospora crassa (A and a) have a dual function: A and a individuals are required for sexual reproduction, but only strains of the same mating type will form a stable vegetative heterokaryon. Neurospora tetrasperma, in contrast, is a naturally occurring A+a heterokaryon. It was shown previously that the mating-type genes of both species are functionally the same and are not responsible for this difference in heterokaryon incompatibility. This suggests that a separate genetic system determines the heterokaryon incompatibility function of mating type. The mutant tolerant (tol) in N. crassa, unlinked to mating type, acts as a specific suppressor of A+a heterokaryon incompatibility. In the present study, the wild-type alleles at the tol locus were introgressed reciprocally, from N. crassa into N. tetrasperma and from N. tetrasperma into N. crassa, to investigate the action of these alleles in the A+a heterokaryon incompatibility systems of these species. The wild-type allele from N. tetrasperma (tolT) acts as a recessive suppressor of A+a heterokaryon incompatibility in N. crassa. Furthermore, the wild-type allele from N. crassa (tolC) causes A and a to become heterokaryon incompatible in N. tetrasperma, while having no effect on the sexual reproduction. Therefore, the tol gene plays a major role in determining the heterokaryon compatibility of mating type in these species: tolC is an active allele that causes incompatibility and tolT an inactive allele that suppresses incompatibility by its inactivity.     

Escape from mating-type incompatibility in bisexual (A + a) Neurospora heterokaryons.

In Neurospora crassa, strains of opposite mating type generally do not form stable heterokaryons because the mating type locus acts as a heterokaryon incompatibility locus. However, when one A and one a strain, having complementing auxotrophic mutants, are placed together on minimal medium, growth may occur, although the growth is generally slow. In this study, escape from such slow growth to that at a wild type or near-wild type rate was observed. The escape cultures are stable heterokaryons, mostly having lost the mating type allele function from one component nucleus, so that the nuclear types are heterokaryon compatible. Either A or a mating type can be lost. This loss of function has been attributed to deletion since only one nuclear type could be recovered in all heterokaryons except one, but deletion spanning adjacent loci has been directly demonstrated in a minority of cases. Alternatively when one component strain is tol and the other tol+ (tol being a recessive mutant suppressing the heterokaryon incompatibility associated with mating type), escape may occur by the deletion or mutation of tol+, also resulting in heterokaryon compatibility. An induction mechanism for escape is speculated upon.     

Heterokaryon incompatibility function of barrage-associated vegetative incompatibility genes (vic) in Cryphonectria parasitica

Six vegetative incompatibility (vic) loci have been identified in Cryphonectria parasitica based on barrage formation during mycelial interactions. We used hygromycin B- and benomyl-resistance as forcing markers in C. parasitica strains to test whether heteroallelism at each vic locus prevents heterokaryon formation following mycelial interactions. Paired strains that had allelic differences at any of vic1, 2, 3, 6 or 7 but not vic4 displayed heterokaryon incompatibility function, as recognized by slow growth or aberrant morphology. While clearly forming barrages in mycelial interactions, paired strains with different alleles at vic4 formed stable heterokaryons. With examples from other fungi, this inconsistency at vic4 suggests that barrage formation and heterokaryon incompatibility are not different manifestations of the same process. Rather, the evidence indicates that heterokaryon incompatibility represents a component of a vegetative incompatibility system that may also use cell-surface or extracellular factors to trigger programmed cell death to modulate nonself recognition in fungi.     

Heterokaryon incompatibility in fungi—more than just another way to die

In filamentous fungi heterokaryon (vegetative) compatibility is regulated by a number of different loci. Vegetative incompatibility is most often detected as the inability to form a prototrophic heterokaryon under forcing conditions, or as the formation of a barrage when two incompatible strains interact. Vegetative compatibility has been used as a multilocus phenotype in analysis of fungal populations. In some highly clonal populations the vegetative-compatibility phenotype is correlated with pathogenicity. The molecular basis for vegetative compatibility is not well understood. Fourhet loci have been cloned fromNeurospora crasset orPodospora anserina, inch but no two are alike and it is clear that thehet genes themselves do not encode the gene products that are directly responsible for cell death. We suggest that a broader view of vegetative compatibility would include genes that are responsible for prefusion, fusion, and postfusion activities. Postfusion activities could include the fungal apoptotic apparatus since microscopic observations of cell death resemble those in higher plants and animals.     

On the independence of barrage formation and heterokaryon incompatibility in Neurospora crassa

A barrage is a line or zone of demarcation that may develop at the interface where genetically different fungi meet. Barrage formation represents a type of nonself recognition that has often been attributed to the heterokaryon incompatibility system, which limits the co-occurrence of genetically different nuclei in the same cytoplasm during the asexual phase of the life cycle. While the genetic basis of the heterokaryon incompatibility system is well characterized in Neurospora crassa, barrage formation has not been thoroughly investigated. In addition to the previously described Standard Mating Reaction barrage, we identified at least three types of barrage in N. crassa; dark line, clear zone, and raised aggregate of hyphae. Barrage formation in N. crassa was evident only when paired mycelia were genetically different and only when confrontations were carried out on low nutrient growth media. Barrages were observed to occur in some cases between strains that were identical at all major heterokaryon incompatibility (het) loci and the mating-type locus, mat, which acts as a heterokaryon incompatibility locus during the vegetative phase of N. crassa. We also found examples where barrages did not form between strains that had genetic differences at het-6, het-c, and/or mat. Taken together, these results suggest that the genetic control of barrage formation in N. crassa can operate independently from that of heterokaryon incompatibility and mating type. Surprisingly, barrages were not observed to form when wild-collected strains of N. crassa were paired. However, an increase in the frequency of pairings that produced barrages was observed among strains obtained by back-crossing wild strains to laboratory strains, or through successive rounds of inbreeding of wild-derived strains, suggesting the presence in wild strains of genes that suppress barrage.     

Cytoplasmic Incompatibility and Bacterial Density in Nasonia Vitripennis

Cytoplasmically (maternally) inherited bacteria that cause reproductive incompatibility between strains are widespread among insects. In the parasitoid wasp Nasonia, incompatibility results in improper condensation and fragmentation of the paternal chromosomes in fertilized eggs. Some form of genome imprinting may be involved. Because of haplodiploidy, incompatibility results in conversion of (diploid) female eggs into (haploid) males. Experiments show that bacterial density is correlated with compatibility differences between male and female Nasonia. Males from strains with high bacterial numbers are incompatible with females from strains with lower numbers. Temporal changes in compatibility of females after tetracycline treatment are generally correlated with decreases in bacterial levels in eggs. However, complete loss of bacteria in mature eggs precedes conversion of eggs to the ``asymbiont' compatibility type by 3-4 days. This result is consistent with a critical ``imprinting' period during egg maturation, when cytoplasmic bacteria determine compatibility. Consequent inheritance of reduced bacterial numbers in F(1) progeny has different effects on compatibility type of subsequent male vs. female progeny. In some cases, partial incompatibility occurs which results in reduced offspring numbers, apparently due to incomplete paternal chromosome elimination resulting in aneuploidy.     

Sexual diploids of Aspergillus nidulans do not form by random fusion of nuclei in the heterokaryon

The sexual stage of Aspergillus (Emericella) nidulans consists of cleistothecia containing asci, each with eight ascospores. The fungus completes the sexual cycle in a homokaryotic or a heterokaryotic mycelium, respectively. The common assumption for the last 50 years was that different nuclear types are not distinguishable when sexual development is initiated. When cultured on a medium limited for glucose supplemented with 2% sorbitol, sexual development of A. nidulans is slowed and intact tetrads can be isolated. Through tetrad analysis we found that unlike haploid nuclei fuse preferentially to the prezygotic diploid nucleus. When heterokaryons are formed between nuclei of different genetic backgrounds, then recombinant asci derived from opposite nuclei are formed exclusively. Strains in the same heterokaryon compatibility group with moderate differences in their genetic backgrounds can discriminate between the nuclei of a heterokaryon and preferentially form a hybrid diploid nucleus, resulting in 85% recombinant tetrads. A. nidulans strains that differ at only a single genetic marker fuse the haploid nuclei at random for formation of diploid nuclei during meiosis. These results argue for a genetically determined "relative heterothallism" of nuclear recognition within a heterokaryon and a specific recruitment of different nuclei for karyogamy when available.     

Investigation of the het genes that control heterokaryon incompatibility between members of heterokaryon-compatibility (h-c) groups A and G1 of Aspergillus nidulans

A chromosome assay method was used to determine the heterokaryon compatibility relationships between strains belonging to heterokaryon-compatibility (h-c) groups A and G1 of Aspergillus nidulans. A hybrid strain (RD15) was isolated following protoplast fusion of strains 65-5 (h-cA) and 7-141 (h-cG1). The morphology of RD15 was severely abnormal compared to diploid strains of A. nidulans produced from heterokaryon-compatible haploid parents. Inocula of RD15 were induced to haploidize on medium containing Benlate and a parasexual progeny sample of 291 haploid segregants was obtained. The progeny strains were genotyped for standard markers. Allelic ratios and pairwise marker segregations were determined. Pairs of progeny strains that carried different alleles for the standard markers on each linkage group in turn were tested for compatibility. Strain pairs that possessed different alleles for the markers on linkage groups II, III, V, VI and VII were incompatible indicating the presence of heterokaryon-incompatible (het) genes on these linkage groups. Backcrosses to an h-cGl strain showed that two het genes were located on linkage group III and confirmed a total of six het gene differences between the h-cA and h-cGl strains.     

The Use of Duplication-Generating Rearrangements for Studying Heterokaryon Incompatibility Genes in Neurospora

Heterokaryon (vegetative) incompatibility, governing the fusion of somatic hyphal filaments to form stable heterokaryons, is of interest because of its widespread occurrence in fungi and its bearing on cellular recognition. Conventional investigations of the genetic basis of heterokaryon incompatibility in N. crassa are difficult because in commonly used stocks differences are present at several het loci, all with similar incompatibility phenotypes. This difficulty is overcome by using duplications (partial diploids) that are unlikely to contain more than one het locus. A phenotypically expressed incompatibility reaction occurs when unlike het alleles are present within the same somatic nucleus, and this parallels the heterokaryon incompatibility reaction that occurs when unlike alleles in different haploid nuclei are introduced into the same somatic hypha by mycelial fusion.—Nontandem duplications were used to confirm that the incompatibility reactions in heterokaryons and in duplications are alternate expressions of the same genes. This was demonstrated for three loci which had previously been established by conventional heterokaryon tests—het-e, het-c and mt. These were each obtained in duplications as recombinant meiotic segregants from crosses heterozygous for duplication-generating chromosome rearrangements. The particular method of producing the duplications is irrelevant so long as the incompatibility alleles are heterozygous.—The duplication technique has made it possible to determine easily the het-e and het-c genotypes of numerous laboratory and wild strains of unknown constitution. In laboratory strains both loci are represented simply by two alleles. Analysis of het-c is more complicated in some wild strains, where differences have been demonstrated at one or more additional het loci within the duplication used and multiple allelism is also possible.—The results show that the duplication method can be used to identify and map additional vegetative incompatibility loci, without the necessity of heterokaryon tests.     

Allelic Specificity at the Het-C Heterokaryon Incompatibility Locus of Neurospora Crassa Is Determined by a Highly Variable Domain

In filamentous fungi, the ability to form a productive heterokaryon with a genetically dissimilar individual is controlled by specific loci termed het loci. Only strains homozygous for all het loci can establish a heterokaryon. In Neurospora crassa, 11 loci, including the mating-type locus, regulate the capacity to form heterokaryons. An allele of the het-c locus (het-c(OR)) of N. crassa has been previously characterized and encodes a nonessential 966 amino acid glycine-rich protein. Herein, we describe the genetic and molecular characterization of two het-c alleles, het-c(PA) and het-c(GR), that have a different specificity from that of het-c(OR), showing that vegetative incompatibility is mediated by multiple alleles at het-c. By constructing chimeric alleles, we show that het-c specificity is determined by a highly variable domain of 34-48 amino acids in length. In this regard, het-c is similar to loci that regulate recognition in other species, such as the (S) self-incompatibility locus in plants, the sexual compatibility locus in basidiomycetes and the major histocompatibility complex (MHC) genes in vertebrates.     

Heteroallelism at the het-c locus contributes to sexual dysfunction in outcrossed strains of Neurospora tetrasperma.

Neurospora tetrasperma is naturally heterokaryotic, with cells possessing haploid nuclei of both a and A mating types. As a result, isolates are self-fertile (pseudohomothallic). Occasional homokaryotic ascospores and conidia arise, however, and they produce strains that are self-sterile and must outcross to complete sexual reproduction. Invariably, laboratory crosses employing sibling a and A strains from the same parental heterokaryon restore the pseudohomothallic, heterokaryotic state. In contrast, outcrosses employing a and A strains from different wild isolates typically result in sexual dysfunction. Diverse sexual dysfunction types have been observed, ranging from complete sterility to reduced viability. We report that one type of dysfunction, characterized by spontaneous loss of the heterokaryotic state upon ascospore germination, can result from the interaction of incompatible alleles at heterokaryon incompatibility loci. Specifically, we demonstrate that homoallelism at the het-c locus in N. tetrasperma is required for heterokaryon stability. Heterokaryon incompatibility therefore provides an obstacle to outcrossing in this species, an observation with important implications for fungal life-cycle evolution.     

Adaptive Significance of Vegetative Incompatibility in NEUROSPORA CRASSA

Certain features reminiscent of sexuality occur in the vegetative life cycle of some filamentous fungi such as Neurospora crassa. Hyphal fusions can occur between genetically different individuals, thereby endowing the new composite mycelium, a heterokaryon, with some of the advantages of heterozygosity usually associated with diploid organisms. In N. crassa, however, there are a number of incompatibility loci which prevent formation of heterokaryons unless the alleles at the incompatibility loci are identical in the two mycelia. The selection pressures that maintain incompatibility polymorphisms are not known. We suggest here that they are maintained because they prevent a kind of exploitation of heterokaryons by nuclei that are nonadaptive in homokaryons but that enjoy a proliferative advantage over other nuclei in heterokaryons. A mathematical model that abstracts the major features of the vegetative life cycle of Neurosopra crassa has been developed, and the action of selection in this model and various extensions of it is such as to maintain polymorphisms of vegetative incompatibility factors.     

Intergenic Complementation of Glucoamylase and Citric Acid Production in Two Species of Aspergillus

All auxotrophs of Aspergillus foetidus and all but two auxotrophs of A. niger which we isolated yield glucoamylase and citric acid, respectively, at levels below that of the prototrophic strain from which they were derived. Results of representative heterokaryon tests suggest that the nucleus was principally responsible for the inheritance of citric acid or glucoamylase production. Most somatic diploid strains of A. foetidus gave rise to higher yields of glucoamylase when compared to their haploid component strains. Both heterokaryons and somatic diploid strains of A. niger synthesized between auxotrophs which were simultaneously reduced in citric acid yields also gave rise to enhanced yields when compared with their haploid components. The yields of a heterokaryon and somatic diploid synthesized between two high producers of citric acid were not higher than those of respective haploid components. We concluded from these results that gene dosage (or ploidy) does not increase the yield of citric acid. The apparent enhancement in yields observed in diploids or heterokaryons synthesized between auxotrophs with reduced yields in both species can be interpreted as resulting from intergenic complementation.     

Multilocus self-recognition systems in fungi as a cause of trans-species polymorphism

Trans-species polymorphism, meaning the presence of alleles in different species that are more similar to each other than they are to alleles in the same species, has been found at loci associated with vegetative incompatibility in filamentous fungi. If individuals differ at one or more of these loci (termed het for heterokaryon), they cannot form stable heterokaryons after vegetative fusion. At the het-c locus in Neurospora crassa and related species there is clear evidence of trans-species polymorphism: three alleles have persisted for approximately 30 million years. We analyze a population genetic model of multilocus vegetative incompatibility and find the conditions under which trans-species polymorphism will occur. In the model, several unlinked loci determine the vegetative compatibility group (VCG) of an individual. Individuals of different VCGs fail to form productive heterokaryons, while those of the same VCG form viable heterokaryons. However, viable heterokaryon formation between individuals of the same VCG results in a loss in fitness, presumably via transfer of infectious agents by hyphal fusion or exploitation by aggressive genotypes. The result is a form of balancing selection on all loci affecting an individual's VCG. We analyze this model by making use of a Markov chain/strong selection, weak mutation (SSWM) approximation. We find that trans-species polymorphism of the type that has been found at the het-c locus is expected to occur only when the appearance of new incompatibility alleles is strongly constrained, because the rate of mutation to such alleles is very low, because the number of possible incompatibility alleles at each locus is restricted, or because the number of incompatibility loci is limited.     

The homologue of het-c of Neurospora crassa lacks vegetative compatibility function in Fusarium proliferatum

For two fungal strains to be vegetatively compatible and capable of forming a stable vegetative heterokaryon they must carry matching alleles at a series of loci variously termed het or vic genes. Cloned het/vic genes from Neurospora crassa and Podospora anserina have no obvious functional similarity and have various cellular functions. Our objective was to identify the homologue of the Neurospora het-c gene in Fusarium proliferatum and to determine if this gene has a vegetative compatibility function in this economically important and widely dispersed fungal pathogen. In F. proliferatum and five other closely related Fusarium species we found a few differences in the DNA sequence, but the changes were silent and did not alter the amino acid sequence of the resulting protein. Deleting the gene altered sexual fertility as the female parent, but it did not alter male fertility or existing vegetative compatibility interactions. Replacement of the allele-specific portion of the coding sequence with the sequence of an alternate allele in N. crassa did not result in a vegetative incompatibility response in transformed strains of F. proliferatum. Thus, the fphch gene in Fusarium appears unlikely to have the vegetative compatibility function associated with its homologue in N. crassa. These results suggest that the vegetative compatibility phenotype may result from convergent evolution. Thus, the genes involved in this process may need to be identified at the species level or at the level of a group of species and could prove to be attractive targets for the development of antifungal agents.