HETEROKARYOSIS AND PARASEXUALITY IN THE FUNGUS ASCOCHYTA IMPERFECTA

The object of this investigation was to discover whether heterokaryosis and parasexuality occur in the imperfect fungus Ascochyta imperfecta. Both phenomena have been observed. The wild type of A. imperfecta grows on a minimal medium containing only salts plus a carbon source. Auxotrophic and morphological mutants have been isolated after treatment with ultraviolet light. When 2 different mutant auxotrophs are inoculated together onto minimal medium, colonies are consistently formed. These colonies might be due, a priori, to back-mutation, diploidy, syntrophism or heterokaryosis. Back-mutation and diploidy have been eliminated, since no back-mutant nuclei have been isolated from any heterokaryon, and since the frequency of diploid nuclei is very low. The combination is primarily syntrophic (only 2% heterokaryotic hyphal tips) when the nicotinamide mutant is one component. The combination is primarily heterokaryotic (over 50% heterokaryotic hyphal tips) when both components are auxotrophs for amino acids. From the heterokaryotic hyphal tips, the 2 unaltered nuclear components have been isolated. Heterozygous diploid nuclei (4.2 X 10^−-7 per haploid nucleus) can be isolated from heterokaryons by plating, onto minimal medium, the primarily uninucleate conidia from a heterokaryon of 2 auxotrophs. The resulting colonies are isolated as potential diploids. Three properties of these isolates establish their diploid nature: (1) the isolates are wild type for nutrition and morphology; (2) their conidial length is uniformly greater than that of the haploids (1.21 times); (3) the isolates produce segregants with nonparental combinations of the marker genes. The diploid isolates are much more stable than heterokaryons. The recombinants from the diploids are still diploid, since (1) their conidial length falls in the diploid range, and (2) one of the recombinants has segregated a second-order recombinant. Many of the expected classes of recombinants have not been detected.     

Vegetative compatibility and parasexual segregation in Colletotrichum lindemuthianum, a fungal pathogen of the common bean

The heterokaryotic and vegetative diploid phases of Colletotrichum lindemuthianum are described using nutritional and biochemical markers. Nitrate non-utilizing mutants (nit), derived from R2047, R89, R73, R65, and R23 isolates, were paired in all possible combinations to obtain heterokaryons. Although pairings R2047/R89, R2047/R73, R65/R73, and R73/R23 showed complete vegetative incompatibility, prototrophic heterokaryons were obtained from pairings R2047/R65, R2047/R23, R65/R89, R65/R23, R73/R89, R89/R23, R2047/R2047, R65/R65, R89/R89, R73/R73, and R23/R23. Heterokaryons gave rise to spontaneous mitotic segregants which carried markers corresponding to one or the other of the parental strains. Heterokaryons spontaneously produced prototrophic fast-growing sectors too, characterized as diploid segregants. Diploids would be expected to yield auxotrophic segregants following haploidization in basal medium or in the presence of benomyl. Parental haploid segregants were in fact recovered from diploid colonies growing in basal medium and basal medium containing the haploidizing agent. Although barriers to the formation of heterokaryons in some crosses were detected, the results demonstrate the occurrence of parasexuality among vegetative compatible mutants of C. lindemuthianum.     

Heterokaryosis and the role of cytoplasmic inheritance in dark resting structure formation in Verticillium spp

Summary Auxotrophic and morphological mutants of Verticillium albo-atrum (producing darkly pigmented resting mycelium) and V. dahliae (forming dark microsclerotia) were isolated after treatment of conidia (haploid and uninucleate) with ultraviolet light. Hyphal tip and conidial analysis revealed that complementation between pairs of auxotrophs on minimal medium was due to a mosaic of homokaryotic and heterokaryotic regions with some hyphal tips growing syntrophically. A degree of incompatibility was observed in a few intraspecific, but in most of the interspecific, heterokaryon tests. Heterozygous diploid conidia (6–11 in length compared with 3–6 for haploids) were recovered at a frequency of 1 in 8x10⁶ by plating spores at high density on MM. Young diploid colonies segregated to give haploid and diploid sectors, some of which were recombinant types (parasexual cycle). Heterokaryons between complementary auxotrophs which were wild-type for dark pigmentation (hyl⁺) resembled wild-type and only darkly pigmented colonies were recovered by conidial analysis. Heterokaryons between hyl⁺ and hyaline (hyl) auxotrophs again resembled hyl⁺ morphology and usually only hyl⁺ colonies of both auxotrophic genotypes were recovered. Conidia from heterokaryons formed by stable hyl auxotrophs produced only hyl colonies of both auxotrophic genotypes. The important role played by cytoplasmic factors in the inheritance of darkly-pigmented resting structures in Verticillium was strongly confirmed by the present work.     

Diploids in Microsporum gypseum

The paper studies diploids in dermatophyteMicrosporum gypseum. They were isolated as the more rapidly growing sectors from heterokaryons on minimal medium. They are characterized by their wild morphology, conidiation and growth rate, and they are prototrophic. In their genome they contain all the markers present in both mutant components.     

Tests which distinguish induced crossing-over and aneuploidy from secondary segregation in Aspergillus treated with chloral hydrate or gamma-rays

A system of tests with the ascomycete Aspergillus nidulans was devised that can detect 3 primary effects of genotoxic agents: (1) increases in mitotic crossing-over; (2) induced aneuploidy; and (3) clastogenic effects which cause chromosomal imbalance. Conidia of a new diploid tester strain, heterozygous for 4 recessive markers which alter conidial color, are treated and plated onto nonselective media. In cases of induced crossing-over, large color segments are found in normal green colonies, frequently adjacent to reciprocal twin segments. In contrast, both malsegregation and chromosome breakage produce unbalanced types which grow poorly and segregate further. Cases with yellow segregants are replated and their secondary diploid sectors tested for markers which are located on both chromosome arms in coupling with yA. Induced aneuploidy can be distinguished from chromosome breakage by the pattern of marker segregation. Any aneuploid type will produce euploid sectors solely by segregation of whole chromosomes; trisomic colonies (yA / yA / +) will show 1:2 ratios for yellow (homozygous yA) to parental green (yA/+) sectors and have characteristic phenotypes. Other induced unbalanced types, if heterozygous for deletions or aberrations may produce yellow diploid sectors by secondary crossing-over as well as by nondisjunction and such cases show unique patterns of genetic segregation and non- predictable phenotypes. As a complementary test, haploid strains are treated and induced abnormally growing types are replated and classified by phenotype. Aneuploids are unstable and produce many normal sectors, and some of these disomic or trisomic types can be visually identified.In contrast, induced deletions are lethal, and duplications or 'morphological' mutants show much more stable abnormal phenotypes. This test system was used to characterize the primary effects of gamma-rays and chloral hydrate. Results and evidence were as follows: (1) A dose-dependent increase of color segments resulting from reciprocal crossing-over was found after treatment of dividing nuclei in germinating diploid conidia with gamma-rays, but not with chloral hydrate. (2) Highly aneuploid and polyploid types were induced in diploid and haploid germinating conidia by chloral hydrate but not to any significant extent by gamma-rays. (3) gamma-Rays caused a dose- dependent increase off abnormally growing colonies when dormant or germinating diploid conidia were treated. These colonies produced secondary euploid sectors by spontaneous nondisjunction and frequently also by crossing-over, which provided evidence for induced semidominant and recessive lethal mutations of many types.     

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.     

Nonparental progeny resulting from protoplast fusion inTrichoderma in the absence of parasexuality

The purpose of this study was to characterize a number of progeny from intra- and interstrain protoplast fusion within the genusTrichoderma. We wished to determine whether parasexuality or other genetic mechanisms occur in these fungi. When two different auxotrophs of the same strain were fused, rapidly growing prototrophic progeny were obtained in high frequencies. When single spore isolates of these strains were prepared, equal numbers of strains indistinguishable from the two parental auxotrophic strains were obtained, even though 10⁹–10¹⁰ conidia were tested per strain. Thus, progeny from intrastrain fusions all appeared to be balanced heterokaryons, and no evidence of recombination between the two parental strains was obtained. When 16 separate interstrain fusions were conducted, very different results were obtained, regardless of whether fusions were within or between species. Following interstrain fusions, presumptive somatic hybrids developed very slowly and in low numbers as compared with hybrids from intrastrain fusions. Most were weakly prototrophic. These slow-growing progeny were unstable and sectors developed from them. Such sectors themselves were unstable and gave rise to other progeny. Usually sectors were more strongly prototrophic and more rapid growing than the original progeny strain. Sectoring gave rise to a very wide range of morphotypes. Most of these morphotype variants were stable through conidiation; thus, these types did not occur as a consequence of heterokaryosis. Isozyme analysis was conducted on over 1000 progeny strains. Nearly all progeny were identical to one or the other parental isozyme phenotypes. A few progeny, when tested as soon as possible after fusion, exhibited the isozyme phenotypes of both parents, but such biparental banding patterns were rapidly lost upon subsequent reculturing. Isozyme banding patterns of multimeric enzymes never gave band patterns indicative of heterokaryosis or heterozygosis. Banding patterns indicative of heterozygous diploids or recombinants were never detected. Despite the extreme variation in morphotype and nutritional requirements among progeny, isozyme banding patterns of derived progeny from any fusion were invariably identical to one or the other parental strains. From these results, we conclude that protoplast fusion in the genusTrichoderma gives rise to great variability, but that the classical parasexual cycle is not required for variation to occur.     

Interspecific hybridization between Penicillium chrysogenum and Penicillium cyaneo-fulvum following protoplast fusion

Summary Slow-growing interspecific heterokaryons were isolated on minimal medium following the induced fusion of protoplasts from auxotrophic mutants of Penicillium chrysogenum and Penicillium cyaneo-fulvum. After 5–7 days cultivation the heterokaryons produced vigorously growing sectors which on transfer gave genetically stable colonies. Cultivation of these colonies on a complete medium supplemented with p-fluorophenylalanine or benomyl broke down this stability and several different prototrophic and auxotrophic colony types were isolated. Many of these behaved as diploids or aneuploids showing sectoring either spontaneously, or in the presence of an haploidizing agent. Some of the latter isolates were recombinants for parental spore colour and auxotrophic markers.     

Parasexual analysis of common-A crosses in the basidiomycete Agrocybe aegerita

Summary Crosses were performed between homokaryons of Agrocybe aegerita having the same allele at the A incompatibility gene but different B alleles. Heterokaryotic mycelia originating from crosses between two complementary auxotrophs were characterized by their instability on complete medium and extensive anastomosis between hyphae. Diploid mycelia were selected by plating oidia recovered from these heterokaryons onto minimal medium. These mycelia were characterized by the production of larger oidia than those of homokaryons, the release of a brown pigment when growing on complete medium and extensive hyphal anastomoses. Diploids retained the two B incompatibility functions of their homokaryotic parents and gave rise to a diploid/haploid dikaryon when crossed with a compatible homokaryon. Nearly 1% of the oidia recovered from heterokaryons were diploid. These nuclear fusion frequencies as well as the production of brown pigments enabled the identification of diploid strains on complete medium. In this way, crosses between wild prototrophic strains were successfully performed. Somatic recombination was induced following the treatment of diploid mycelia with haploidizing compounds. Selection based on the inability of mycelia to produce the brown pigments on complete medium led to selection of strains homoallelic at the B locus.     

Hybridization of Candida albicans through fusion of protoplasts

Protoplasts of complementing auxotrophs of Candida albicans can fuse in the presence of polyethylene glycol and generate prototrophic cells. The yields of prototrophs from fusion mixtures depend greatly on the particular combinations of auxotrophies involved but not on other features of the strain backgrounds of protoplasts. The initial cellular products of fusions isolated on selective media are heterokaryons which replicate slowly but also segregate single parental nuclei into blastospores in high frequency. Karyogamy within heterokaryons produces hybrid nuclei which, on segregation, give rise to rapidly growing, uninucleate substrains. Analyses of the substrains show that hybrid nuclei either stabilize as diploid or undergo random loss of chromosomes to stabilize at various levels of aneuploidy prior to segregation. Chromosome losses and radiation induced mitotic crossing-over can effect recombination for parental auxotrophic markers in hybrids; patterns of recombination for ade^r and arg markers provide the first documented example of chromosomal linkage in C. albicans. Thus, protoplast fusions offer opportunities otherwise unavailable for applying the incisive tools of genetic recombination to analysis of this important, asexual yeast.     

Selection of auxotrophic mutants inSaccharomyces cerevisiae by a snail enzyme digestion method

Yeast cells in the stationary phase of growth are relatively resistant to snail enzyme digestion. This resistance was shown to decrease abruptly in the course of only 3–5 duplications, when stationary cells were allowed to grow in a fresh medium. The selective digestion of growing prototrophs from a mutagenized culture in minimal medium by snail enzyme was applied to increase the proportion of auxotrophs which remained relatively resistant.     

Intraspecific hybridisation of Trichoderma pseudokoningii by anastomosis and by protoplast fusion

Double auxotrophic and morphological mutants of Trichoderma pseudokoningii Rifai were fused by anastomosis and by protoplast fusion. The recovery of recombinants from heterokaryons on different selective media and from heterokaryotic colonies indicated the occurrence of parasexual events. Prototrophic colonies growing on minimal medium produced binucleate spores, green in colour, revealing a non-autonomous system for conidial pigmentation. Recombinants were obtained from these dikaryotic colonies suggesting the occurrence of a highly unstable diploid phase.     

Improved production of citric acid by a diploid strain of Aspergillus niger

Aspergillus niger strain CGU 87 was treated with UV radiation and some auxotrophic mutants were obtained. These mutants were less productive than CGU 87, which produced an average of 7.4% citric acid. All possible crosses in pair wise combinations were carried out between these auxotrophs, and three heterokaryons were synthesised. Finally, one heterozygous diploid was isolated from each of them. These heterokaryons and diploids showed improved productivity when compared with their component parents, but except in one diploid D5, all others produced less citric acid than CGU 87. The yield of D5 exceeded that of CGU 87 by 1.2 times and it produced 9% citric acid. This is a significant improvement and the increased productivity seems to be the result of successful adaptation of D5 to its fermentation environment.     

Direct selection of complementing diploids from PEG-induced fusion of Bacillus subtilis protoplasts

Summary A minimal medium containing horse serum is described on which Bacillus subtilis protoplasts revert to bacillary forms at high frequency (ca. 30%). Used as a plating medium for a mixture of polyethyleneglycol-treated protoplasts from two complementary polyauxotrophic parental strains, it selects the prototrophic fusion products efficently, and also allows isolation of various auxotrophic recombinants. These prototrophs and recombinants amount respectively to 1% and 10% of the regenerated bacteria.We confirm that two types of prototrophs can be isolated after fusion: stable recombinants and complementing diploids, the latter segregating into various types of recombinants. Based on easily recognized colonial aspects, an approximate estimation of the proportion of the two types becomes possible when a spoOA mutation has been introduced in one of the parents. At least 50% of the prototrophic fusion products are complementing diploids. Incidently, the data also settle a controversy by showing the dominance of spoOA mutations in heterozygotic bacteria.This work was supported by the Centre National de la Recherche Scientifique (Contrat L.A. 136).     

Parasexuality in Race 65 Colletotrichum lindemuthianum Isolates

ABSTRACT. Heterokaryosis is the initial step of the parasexual cycle, a process that provides genetic variability in filamentous fungi through the production of heterozygous diploid nuclei. To characterize the parasexual cycle in Colletotrichum lindemuthianum, we evaluated the presence of heterokaryosis, vegetative compatibility reactions, and diploid formation among isolates of Race 65 collected from different Brazilian states. Vegetative compatibility groups were identified among the isolates according to their ability to form heterokaryons. Two heterozygous diploids were selected from compatible heterokaryons, which were characterized by the segregation of the parental auxotrophic markers and by RAPD profiles.     

产黄青霉ds RNA病毒通过原生质体融合的转移

将国内青霉素产生菌(Penicillium chrysogenum)的黄孢子系统及绿孢子(包括淡绿,灰绿)系统的十多个菌株,经过病毒提取、电镜观察、奥氏免疫双扩散、凝胶电泳及放射免疫测定,证明黄孢子系统的菌株含有不同滴定度的、直径40nm的球形病毒,而绿孢子系统中检查不出病毒。从营养要求、孢子颜色不同的带病毒和无病毒菌体中分离原生质体,进行不同组合的原生质体的融合杂交,获得营养互补融合的异核体。异核体1中,病毒通过胞质融合转移到原来无病毒的灰绿孢子菌株及细胞核融合后的杂合二倍体中。灰绿孢子的病毒量接近二倍体的1/3。二倍体菌落生长稳定,低温保存二年后经0.01—0.02M对氟苯丙氨酸(PFA)诱发和分离,产生亲本类型的分离子,分离子及二倍体仍然含有病毒。异核体2作亲本性分离,黄孢子仍有病毒,淡绿孢子及细胞核融合后产生的二倍体均无病毒,表明非感染性为显性。此种淡绿孢子的突变体中存在非感病菌系,它不支持病毒的复制。提取各杂交组二倍体内的病毒所特有的dsRNA时,可看出dsRNA的存在和病毒的存在一致。多数杂合二倍体的青霉素产量比亲本高。     

Hybridization and breeding of the benomyl resistant mutant, Trichoderma harziantum antagonized to phytopathogenic fungi by protoplast fusion

A diploid strain obtained from heterokaryons of Trichoderma harzianum by protoplast fusion grew on minimal medium containing 100ppm benomyl. This strain inhibited the growth of the phytopathogenic fungus Fusarium oxysporum f. sp. raphani on paired cultures and also protected against radish yellows and a drop in germination induced by F. oxysporum f. sp. raphani.     

A red/white selection for Saccharomyces cerevisiae auxotrophs

Red pigment production in yeast cells with adel or ade2 mutations has been exploited to develop a method of identifying specific amino acid auxotrophs. Amino acid auxotrophs carrying mutations in adel or ade2 show delayed pigment production at sub-optimal amino acid levels. This delay allows selection of amino acid auxotrophs following mutagenesis, since red pigment is produced in prototrophs whilst auxotrophs remain white. This differential colour reaction has been applied to select leucine, lysine and serine auxotrophs. Large numbers of colonies could easily be screened without the need for extensive replica plating.     

Rich culture medium for the radiochemical labeling of proteins and nucleic acids.

Yeast extract was treated with tyrosine decarboxylase and used to prepare a rich, complex medium virtually free of tyrosine. The medium supported maximal growth rates for Escherichia coli prototrophs, as well as for defined and undefined auxotrophs. It has made possible the efficient radiochemical labeling of cells growing optimally in complex medium and the characterization of mutants with undefined requirements. Similarly prepared media may be useful for the study of fastidious organisms and organisms for which no defined medium has been described.     

Systems and results of tests for chemical induction of mitotic malsegregation and aneuploidy in Aspergillus nidulans

In Aspergillus several types of test systems have been developed for detection of chemicals which induce aneuploidy and/or malsegregation of chromosomes. Results from 23 papers were reviewed in which numerical data for 42 chemicals had been reported. The test systems fall into two groups. One group includes all purely genetic tests that detect euploid mitotic segregants from heterozygous diploids and identify these either as products of malsegregation of chromosomes or as products of crossing-over (13 papers, several reviewed in detail previously; K?fer et al. (1982) and Scott et al. (1982)). The other group includes tests that treat haploid or diploid strains and detect aneuploids as unstable abnormally growing segregants which can be identified as specific disomics or trisomics by their characteristic phenotypes. In addition, such tests characterize abnormal segregants from heterozygous diploids by correlating phenotypes with patterns of genetic segregation in spontaneous euploid sectors. This analysis makes it possible to distinguish between induced primary aneuploidy of whole chromosomes and partial tri- or monosomy resulting from chromosome breakage and secondary spontaneous malsegregation (10 papers). Based on results of both types of tests, it is postulated that chemicals which cause increases of euploid malsegregants, but not of crossovers, normally induce aneuploids as primary products (as shown for 7 of the 14 cases). These include compounds which damage spindles or membranes (especially the well-known haploidizing agents) and generally are effective only when growing cells are exposed. (8 chemicals that may belong in this category could not be classified for certain, because information was insufficient.) On the other hand, chemicals which cause increases of all types of euploid segregants (11 cases), mostly induce drastic mutations and aberrations as primary effects and cause spontaneous malsegregation or crossing-over only as secondary events (as demonstrated for radiation-induced abnormals). In addition, a few chemicals were negative, because they increased only crossing-over or showed no increased segregation at all at concentrations which reduced survival or growth rate (9 cases). Recommendations are made for standardization of methods and protocols. New tester strains and specific procedures are outlined which should be useful for conclusive tests of chemicals that may induce aneuploidy.