GENETICS OF SORDARIA FIMICOLA. V. ABERRANT SEGREGATION AT THE G LOCUS

Kitani , Y., L. S. Olive , and Arif S. El -Ani . (Columbia U., New York City.) Genetics of Sordaria fimicola. V. Aberrant segregation at the g locus. Amer. Jour. Bot. 49(7): 697–706. Illus. 1962.—Aberrant segregation of the gray-spore color locus in Sordaria fimicola was studied with the aid of closely linked markers. It was found that 6:2 and 5:3 asci occur with about the same frequency, but asci with an excess of wild-type spores occur with a frequency 5.5 times that of asci with an excess of gray spores. Also, the frequency of related crossing over (occurring close to the miscopied loeus and involving the miscopying strand) was much higher than the expected value, and in 5:3 asci it appears to be at least twice that found in 6:2 asci. Nine aberrant 4:4 asci, each with 2 spore pairs heterogeneous for color, were found. These are believed to have resulted from reciprocal double transreplication. The rarest aberrant type was represented by a single 7:1 ascus, which is difficult to explain on the basis of a single meiotic process. Miscopying is discussed with relation to an 8-strand model of paired homologues and the occurrence of localized chromosome pairing during prezygotene DNA synthesis. Several possible explanations for the occurrence of aberrant tetrads are considered. Miscopying has also been found to involve several spore-color loci not previously studied; whereas, several other such mutant loci fail to show evidence of it. One locus (m) shows abnormal segregation of the 6:2 but not the 5:3 type.     

GENETICS OF SORDARIA FIMICOLA. III. CROSS-COMPATIBILITY AMONG SELF-FERTILE AND SELF-STERILE CULTURES

Carr , A. J. H. (Univ. Coll. Wales, Aberystwyth), and Lindsay S. Olive . Genetics of Sordaria fimicola. III. Cross compatibility among self-fertile and self-sterile cultures. Amer. Jour. Bot. 46(2) : 81-91. Illis. 1959.—Cross-compatibility in Sordaria fimicola is shown to be dependent upon a number of factors controlling the sexual process, from hyphal anastomosis and nuclear migration on through to perithecial formation and nuclear compatibility. Fertile cultures which were incompatible through inability to anastomose were induced to cross by the use of a third culture which would anastomose with both. Certain spontaneous or irradiation-produced sterility mutants were found to be compatible if the sterility genes were at different loci, through complementation by the wild-type alleles. In some pairings, cross-karyogamy was preferential, and in one case, only hybrid perithecia were produced. Fully fertile recombinants segregated from these crosses in frequencies which indicated that the sterility loci were unlinked. Certain sterility genes were found to influence hyphal anastomosis, nuclear migration, and the development of fertile sector heterokaryons from the zone of anastomosis. Mutant factors at two loci in a U.V. mutant causing self-sterility were found also to be responsible for lethality in ascospore germination. Factors in one sterility mutant controlled the production of a sterility-inducing substance which diffused into the medium. In some crosses, complementation of two sterile cultures towards fertility is shown to require a balanced nuclear ratio. Factors are described which increase the inhibitory effect of one sterility gene, while another factor was found to suppress its effect and thereby make the culture self-fertile. It is concluded that, since there is recombination between the sterility loci, these results do not represent the derivation of balanced heterothallism from a normally homothallic system, although it may lead by evolutionary progression to such a life cycle. The possible physiologic action of the sterility genes is discussed.     

GENETICS OF SORDARIA FIMICOLA. IX. LINKAGE GROUP II

Ten mutant sites have been located in linkage group II of Sordaria fimicola, nine of them affecting fertility. Two different regions of the chromosome are marked with allelic mutations or mutant sites in closely linked loci involved in sexual reproduction. Mutants of one of these two regions also have an arginine deficiency. Crosses between the self-sterile mutants of each region yield hybrid perithecia containing asci with four spores of each parental genotype and few or no asci with recombinant spores. The bearing that these findings have upon the evolution of heterothallism is discussed.     

Duplicated chromosome segments in maize (Zea mays L.): further evidence from hexokinase isozymes

Summary The genetic control of hexokinase isozymes (ATP: d-hexose-6-phosphotransferase, E.C. 2.7.7.1, HEX) in maize (Zea mays L.) was studied by starch gel electrophoresis. Genetic analysis of a large number of inbred lines and crosses indicates that the major isozymes observed are encoded by two nuclear loci, designated Hex1 and Hex2. Five active allozymes and one null variant are associated with Hex1, while Hex2 has nine active alleles in addition to a null variant. Alleles at both loci govern the presence of single bands, with no intragenic or intergenic heteromers visible, suggesting that maize HEX's are active as monomers. Organelle preparations demonstrate that the products of both loci are cytosolic. All alleles, including the nulls, segregate normally in crosses. Vigorous and fertile plants were synthesized that were homozygous for null alleles at both loci, suggesting that other hexosephosphorylating enzymes exist in maize that are undetected with our assay conditions. Linkage analyses and crosses with B-A translocation stocks place Hex1 on the short arm of chromosome 3, 27 centimorgans from Pgd2 (phosphogluconate dehydrogenase) and Hex2 on the long arm of chromosome 6, approximately 45 centimorgans from Pgd1. It is suggested that the parallel linkages among these two pairs of duplicated genes reflects an evolutionary history involving chromosome segment duplication or polyploidy.Paper No. 10170 of the Journal Series of the North Carolina Agricultural Research Service, Raleigh, NC     

<Emphasis Type="Italic">Ophiocordyceps pulvinata</Emphasis> sp. nov., a pathogen of ants with a reduced stroma

Ophiocordyceps pulvinata, a pathogen of ants, is formally described as a new species. Genus level designation of this species is difficult due to several apparently conflicting morphological and ecological characters. Affinity with Ophiocordyceps is suggested by the dark color stroma and ascospore morphology. However, the species was included in a book of entomopathogenic fungi of Japan as Torrubiella sp. due to the production of perithecia on an astipitate stroma. Phylogenetic analyses of molecular data support a close relationship with O. unilateralis, a finding consistent with morphological characteristics of the color, asci and ascospores and ecological traits of host affiliation. Thus, O. pulvinata represents another example of the loss of stipe for the hypocrealean arthropod pathogenic fungi and highlights the utility of asci and ascospore morphology as taxonomically informative characters of closely related taxa.     

Two new male-sterile mutants of Zea mays (Poaceae) with abnormal tapetal cell morphology

Two new recessive male-sterile mutants of Zea mays (Poaceae), or maize, were studied to identify the timing of pollen abortion and to examine the involvement of anther wall cell layers. The results of test crosses indicated that these mutants were not allelic with any known male-sterile mutants of maize. Light and transmission electron microscopy were used to compare pollen development in homozygous male-sterile mutants to that in fertile heterozygous siblings. In both mutants, microspores abort soon after release from the meiotic tetrad. However, the two mutations have strikingly different phenotypes. Large lipid bodies accumulate in the tapetal cells as the microspores vacuolate and die in the mutant ms25. Large vacuoles appear in both the tapetal cells and the young microspores as they begin to disintegrate in the mutant ms26. Because abnormal tapetal cell morphology is detected in both mutants, it is possible that both of these mutations affect the expression of genes in tapetal cells.     

Ascus development in two temperature-sensitive four-spore mutants of Neurospora crassa

Two nonallelic Four-spore mutants are known in which ascospore walls enclose the four immediate products of meiosis rather than the normal eight products of a postmeiotic mitosis. Expression depends on temperature. The Four-spore phenotype is expressed when the developing asci are subjected either to high temperatures (25-30 degrees C) for Fsp-1 or to low temperatures (15-20 degrees C) for Fsp-2. Heterozygous Fsp-1 X Fsp-1+ crosses make eight-spored asci at 15-20 degrees C but produce many four-spored asci at 25 degrees C and mostly four-spored asci at 30 degrees C. Homozygous Fsp-1 X Fsp-1 crosses respond similarly to increasing temperature but make 40-50% four-spored asci even at 20 degrees C. Heterozygous Fsp-2 X Fsp-2+ crosses produce almost exclusively four-spored asci at 15 degrees C but a mixture of four- and eight-spored asci at 20, 25, and 30 degrees C. Homozygous Fsp-2 X Fsp-2 crosses make all four-spored asci at 15 and 20 degrees C and a mixture of four- and eight-spored asci at 25 and 30 degrees C. When both Fsp-1 and Fsp-2 are present in a cross, either homozygous or heterozygous, no asci contain more than four ascospores at any temperature. Limited temperature-shift experiments with Fsp-1 and Fsp-2 show that the sensitive period for Four-spore expression is sometime after meiotic prophase, possibly at interphase II.     

A Mutant Affecting Meiosis in Neurospora

Many mutants affecting meiosis increase the occurrence of aneuploid meiotic products. In Neurospora, mutants of this type cause ascospore abortion which is reflected by an increase in the proportion of ascospores failing to develop black pigment. The usefulness of the criterion white-ascospore-production as a signal for the presence of a mutant affecting meiosis is demonstrated by the recovery of several such mutants. One of these is mei-1 (meiotic-1), a recessive mutant on linkage group IV. Crosses homozygous for mei-1 produce 90% white ascospores (vs. 5% in wild-type crosses). Viable ascospores, invariably black, are always disomic for one or more linkage groups; the chromatids assorted into viable ascospores do not engage in crossing over in meiosis. The distribution of viable ascospores in individual asci suggests that all meioses are defective in the first meiotic division, and that most meioses are defective in both divisions.     

Mechanism of gene conversion in Ascobolus immersus

Summary Sixty two ascospore colour mutants have been induced in Ascobolus immersus: 25 by an acridine (ICR₁₇₀), 18 by N-methyl-N-nitro-N-nitrosoguanidine (NG) and 19 by ethyl methanesulfonate (EMS). All these mutants have been crossed to the wild type strain and their conversion spectrum has been determined. It appears that the conversion spectrum is closely related to the origin of the mutants studied with respect to the mutagen by which they were induced. All NG mutants gave numerous asci with postmeiotic segregation and an excess of conversion to wild type over conversion to the mutant type. ICR mutants gave no postmeiotic segregation and an excess of conversion to the mutant type. The majority of EMS mutants behave like NG mutants, but some showed only meiotic segregation with either an excess of conversion to the mutant type or an excess of conversion to wild type. These data are in good agreement with the hypothesis that the nature of the mutation has a strong influence on the conversion spectrum.     

Ultraviolet-sensitive mutants of Neurospora. I. Genetic basis and effect on recombination

Summary Three new UV-sensitive mutants were obtained using replica plating of the colonial crisp ragged strain of Neurospora crassa — uvs-3 (near cys-10, linkage group IVL), uvs-4 (4 units left of ad-4 IIIR) and uvs-5 (<1 unit from vel, IIIR). These are genetically distinct from uvs-1 (Chang and Tuveson, 1967) and uvs-2 (IVR, Stadler and Smith, 1968). They are two to three times more sensitive to UV than wild type. Heterokaryons between any two mutations are not sensitive, showing that all three are recessive. In heterozygous condition, none of the mutants affects crossing over. In homozygous condition, uvs-4 does not affect gene conversion as measured by prototroph frequency in crosses of pan-2 (B2) x pan-2 (B36), nor does it affect crossing over between cot-1 and tryp-4. Neither uvs-3 nor uvs-5 is fertile in homozygous crosses; asci do not develop beyond the multinucleate ascogenous hypha stage. — Mitotic effects were studied using strains haploid for UV-sensitivity but duplicated and heterozygous for mating type. In(ILR) H 4250 and Tp(III) 39311 were used to generate such duplications. Release from a slow-growing phenotype occurs when a mitotic event makes mating type homo-or hemizygous. With uvs-3, but not uvs-4 or uvs-5, release occurs 2 days earlier than in controls. Thus uvs-3 may affect chromosome breakage or mitotic recombination. The number of chromosome rearrangements present in a sample of colonies grown from single conidia of uvs-3 stocks is the same as in controls, but in test crosses 13% of the colonies produced barren perithecia of a type that is characteristic of duplications.A portion of a dissertation submitted to the Graduate Division of Stanford University in partial fulfillment of the requirements for the degree of Doctor of Philosophy.This work was supported by a National Science Foundation predoctoral fellowship and Public Health Service Research grant AI-01462.     

Abnormal ascospore morphology in the bud mutant of Neurospora tetrasperma

A recessive ascospore mutant of Neurospora tetrasperma, named bud, was isolated from a wild-collected heterokaryotic strain with four different nuclear components. bud segregates as a single mendelian gene. When bud is homozygous, meiosis is apparently normal but postmeiotic events are not. Abnormal orientation of spindles at the postmeiotic mitosis often results in failed pair-wise association of nuclei and their irregular distribution along the length of the ascus prior to spore delimitation. Consequently, many asci cut out more than four ascospores; some contain no nuclei while others contain more than two. The most dramatic effect of bud is on ascospore delimitation itself. Many ascospores are irregularly shaped and are often interconnected, because of incomplete spore delimitation. Ascospores also show one or two lobes or bud-like extensions of varying sizes. Over 75% of ascospores from bud x bud remain white or tan and are inviable. The interaction of bud with a dominant Eight-spore mutant (E) was examined in both heterozygous and homozygous crosses. When both bud and E are heterozygous, bud has no effect on ascospore delimitation or on the phenotype of E because bud is recessive; many asci produce 5-8 ascospores just as in E x E(+). And when bud is homozygous and E is heterozygous, ascospore delimitation is less affected than when E is absent. Moreover, when both bud and E are homozygous, the effect on ascospore development is less extreme than when E is homozygous singly.     

Gene conversion spectrum of 15 mutants giving post-meiotic segregation in the b2 locus of Ascobolus immersus

Summary The conversion spectrum of fifteen mutants giving post-meiotic segregations and located in the b2 locus of Ascobolus immersus was studied in 77 mutant x wild-type crosses. These mutants all yield aberrant 4:4 asci, mutants located in the right portion of the locus yielding more aberrant 4:4 than left mutants. The basic frequency of conversion is higher in the left portion. The frequency of hybrid DNA, its symmetrical or asymmetrical distribution and the frequency of correction of the mismatch in hybrid DNA were estimated. The left region shows a higher frequency of hybrid DNA formation than the right region. The fraction of hybrid DNA with a symmetrical distribution tends to increase from left to right in the locus. The frequencies of mismatch correction show considerable variation from one mutant to another and have no relationship to their location. The implications of these observations on the molecular models of genetic recombination are discussed.     

Inactivation of the gene coding for the 30.4-kDa subunit of respiratory chain NADH dehydrogenase: is the enzyme essential for Neurospora?

We have isolated and characterised the nuclear gene that codes for the 30.4-kDa subunit of the peripheral arm of complex I from Neurospora crassa. The single-copy gene was localised on chromosome VI of the fungal genome by restriction fragment length polymorphism mapping. An extra copy of the gene was introduced into a strain of N. crassa by transformation. This strain was crossed with another strain in order to inactivate, by repeat-induced point mutations, both copies of the duplication carried by the parental transformant. Ascospore progeny from the cross were analysed and a mutant strain lacking the 30.4-kDa protein, nuo30.4, was isolated and further characterised. The mutant appears to assemble the membrane arm of complex I, while formation of the peripheral arm is prevented. Nevertheless, the mutant grows reasonably well – indicating that this well conserved protein is not essential for vegetative growth – and is able to mate with other strains both as male or female. Strains with multiple mutations are readily obtained from heterozygous crosses between different complex I mutants of N. crassa. On the other hand, homozygous crosses between several mutants, including nuo30.4, fail to produce ascospores. These results suggest that complex I plays an essential role during the sexual phase of the life cycle of the fungus. Received: 24 February 1997 / Accepted: 23 September 1997     

The Mutation SK(ad-3A) Cancels the Dominance of ad-3A+ over ad-3A in the Ascus of Neurospora

A newly induced mutant of Neurospora, when crossed with an ad-3A mutant, produces asci with four viable black and four inviable white ascospores. The survivors always contain the new mutant allele, never ad-3A. The new allele, which is called SK(ad-3A) (for spore killer of ad-3A), is located at or very near the ad-3A locus.--In crosses homozygous for ad-3A, each ascus contains only inviable white ascospores. This defect in ascospore maturation is complemented by the wild-type allele, ad-3A+ (crosses heterozygous for ad-3A and ad-3A+ produce mainly viable ascospores), but it is not complemented by the new SK(ad-3A) allele (all ad-3A ascospores from crosses heterozygous for SK(ad-3A) and ad-3A are white and inviable). In crosses homozygous for SK(ad-3A) or heterozygous for SK(ad-3A) and ad-3A+, each ascus contains only viable black ascospores. SK(ad-3A) does not require adenine for growth, and forced heterokaryons between SK(ad-3A) and ad-3A grow at wild-type rates and produce conidia of both genotypes with approximately equal frequency. Thus, the action of SK(ad-3A) is apparently restricted to ascospore formation. Possible mechanisms of the action of this new allele are discussed.     

Expression of Meiotic Drive Elements Spore Killer-2 and Spore Killer-3 in Asci of Neurospora Tetrasperma

It was shown previously that when a chromosomal Spore killer factor is heterozygous in Neurospora species with eight-spored asci, the four sensitive ascospores in each ascus die and the four survivors are all killers. Sk-2K and Sk-3K are nonrecombining haplotypes that segregate with the centromere of linkage group III. No killing occurs when either one of these killers is homozygous, but each is sensitive to killing by the other in crosses of Sk-2K x Sk-3K. In the present study, Sk-2K and Sk-3K were transferred by recurrent backcrosses from the eight-spored species Neurospora crassa into Neurospora tetrasperma, a pseudohomothallic species which normally makes asci with four large spores, each heterokaryotic for mating type and for any other centromere-linked genes that are heterozygous in the cross. The action of Sk-2K and Sk-3K in N. tetrasperma is that predicted from their behavior in eight-spored species. A sensitive nucleus is protected from killing if it is enclosed in the same ascospore with a killer nucleus. Crosses of Sk-2K x Sk-2S, Sk-3K x Sk-3S, and Sk-sK x Sk-3K all produce four-spored asci that are wild type in appearance, with the ascospores heterokaryotic and viable. The Eight-spore gene E, which shows variable penetrance, was used to obtain N. tetrasperma asci in which two to eight spores are small and homokaryotic. When killer and sensitive alleles are segregating in the presence of E, only those ascospores that contain a killer allele survive. Half of the small ascospores are killed. In crosses of Sk-2K x Sk-3K (with E heterozygous), effectively all small ascospores are killed. The ability of N. tetrasperma to carry killer elements in cryptic condition suggests a possible role for Spore killers in the origin of pseudohomothallism, with adoption of the four-spored mode restoring ascospore viability of crosses in which killing would otherwise occur.     

Unstable ascospore color mutants of Ascobolus immersus

Summary New unstable mutants of Ascobolus immersus involving the color or size of ascospores were sought among spontaneous mutants. Among the 34 unstable mutants isolated, 31 had white spores, 2 had pink spores and 1 had a large sized spores. The unstable mutants involve 11 loci whose mutation leads to white spores and 2 loci whose mutations give pink spores, among the 19 loci known to be implicated in this character; 1 locus is defined by only one large spore mutant. All these genes are localized on at least 7 different chromosomes. Unstable mutants of the same locus may correspond to several different sites, but the number of these sites is very limited.The frequency of unstable mutations was estimated: among 36 mutants belonging to 8 different genes, 20 were stable and 16 were unstable. This high frequency of unstable mutants is undoubtedly underestimated. The moment of reversion of 23 of these new mutants was also sought: 15 of them revert as does mutant B, previously studied, in the very young mycelium, at high temperature and with a reversion frequency of 0.004 to 0.34, according to the mutant; 5 of them revert as mutant 301, also previously studied, during the development of the fruit-body and with a frequency of 0.009 to 0.035; two of these mutants revert very early in the ascospore as soon as the first mitoses or in the very young mycelium at 22° C, with a very high reversion frequency that may reach 1.0; finally, the last mutant studied reverts in the fruit-body with a frequency reaching 0.40, but with modalities different from mutant 301. The mutants of the same locus may revert with different modalities. The same modality may correspond to different sites of the same gene.In unstable double-mutant strains involving two different genes, the reversion of one is independent of the reversion of the other, whether or not the reversion modailities of each mutant are identical.Results indicate the existence of inducers common to several unstable mutants which present the same modalities of reversion.These data support the previously formulated hypothesis of transposable elements.     

Freshwater ascomycetes: Wicklowia aquatica, a new genus and species in the Pleosporales from Florida and Costa Rica

During a latitudinal survey of freshwater ascomycetes, an unidentified fungus with bitunicate asci was found on submerged wood and herbaceous material from Florida and Costa Rica. Based on morphological characteristics and 28S rDNA large subunit (LSU) sequence data, this fungus is described as a new genus and species, Wicklowia aquatica, and placed in the Pleosporales (Pleosporomycetidae, Dothideomycetes). Phylogenetic analyses based on LSU sequences did not resolve the familial placement of W. aquatica within the Pleosporales. The characteristic features of W. aquatica are subglobose, dorsiventrally flattened, ostiolate, immersed to erumpent, black ascomata; a peridial wall composed of 4–5 layers of darkened pseudoparenchymatic cells; cellular pseudoparaphyses immersed in a gel matrix; broadly clavate, bitunicate asci; and cylindrical, hyaline, one-septate ascospores with rounded apices and surrounded by a gelatinous sheath that expands in water; ascospore sheath attached at the ascospore base with a gelatinous curtain extending from the base that fragments into basal filamentous appendages which radiate from the base of the ascospore.     

Mutations at the smo genetic locus affect the shape of diverse cell types in the rice blast fungus

Teflon film surfaces are highly conducive to the formation of infection structures (appressoria) in the plant pathogenic fungus, Magnaporthe grisea. We have utilized Teflon films to screen and select for mutants of M. grisea that are defective in appressorium formation. This approach and several others yielded a group of 14 mutants with a similar phenotype. All the mutant strains make abnormally shaped conidia and appressoria. When two mutant strains are crossed, abnormally shaped asci are formed. Ascus shape is normal when a mutant strain is crossed with a wild-type strain. Despite dramatic alterations in cell shape these strains otherwise grow, form conidia, undergo meiosis, and infect plants normally. This mutant phenotype, which we have termed Smo(-), for abnormal spore morphology, segregates in simple Mendelian fashion in crosses with wild-type strains. Some ascospore lethality is associated with smo mutations. In genetic crosses between mutants, smo mutations fail to recombine and do not demonstrate complementation of the abnormal ascus shape phenotype. We conclude that the smo mutations are alleles of a single genetic locus and are recessive with regard to the the ascus shape defect. Mutations at the SMO locus also permit germinating M. grisea conidia to differentiate appressoria on surfaces that are not normally conducive to infection structure formation. A number of spontaneous smo mutations have been recovered. The frequent occurrence of this mutation suggests that the SMO locus may be highly mutable.     

Genic heterozygosity, chromosomal interchanges and fitness in rye: any relationship?

Relationship between heterozygosity at allozyme loci, chromosomal interchanges and fitness was analyzed in a rye cultivar showing a polymorphism for such rearrangements. Nine allozyme systems (ACO, ACPH, GOT, GPI, LAP, MDH, PER, PGD and PGM) and five components of fitness (number of fertile tillers, total offspring, egg cell fertility, flowers/ear and seeds/ear) were studied. The estimated selection coefficients against interchange heterozygotes ranged from s = 0.12 to s = 0.34. A significant effect of the genic heterozygosity on some fitness components was observed in interchange heterozygotes (tillering and total offspring), in their standard homozygous sibs (flowers/ear and seeds/ear) and in the descendants of the crosses between standard karyotypes (flowers/ear, seeds/ear and egg cell fertility). However, the main effect was linked to genetic background associated to different crosses. Significant differences for Acph-1, Gpi-1, Lap-1, Mdh-1, Mdh-4, Pgd-2 and Pgm-1 loci were also found in some of these crosses although these differences were inconsistent. This suggests that probably the allozyme loci analyzed were not directly contributing to the fitness and that they are linked, in some cases, to different deleterious alleles depending on both cross and locus. This fact could support the local effect hypothesis as explanation although we do not discard the existence of some inbreeding level (general effect hypothesis) since all crosses and loci studied show a overall consistent trend of increased fitness with increased heterozygosity.