Isolation and Characterization of Light-Insensitive Mutants of NEUROSPORA CRASSA

As part of a genetic analysis of blue light photoreception in Neurospora, three mutants were isolated that do not exhibit photosuppression of circadian conidiation, i.e., they show periodic conidiation in constant light. The mutations have been given the designations lis-1, lis-2 and lis-3 ("light insensitive"). The three mutations segregate as single nuclear genes, are nonallelic and are recessive to wild type in heterokaryon tests. The linkage groups of the mutations are as follows: lis-1, I; lis-2, VI; and lis-3, V. The light -insensitive phenotype of the mutants is restricted to the photosuppression response; other responses such as photoinduced phase shifting of the conidiation rhythm and photoinduced carotenogenesis are not altered. The physiological or biochemical defects of the mutants have not been established, but they are not similar to previous reported cases (i.e., rib and poky) in which a reduction in light sensitivity has been observed.     

Isolation and Characterization of Temperature-Sensitive Respiratory Mutants of NEUROSPORA CRASSA

Filtration-enrichment and inositol-less death methods of mutant isolation, coupled with a screen for cyanide-insensitive respiration, proved to be highly efficient methods for isolating temperature-sensitive (ts) nuclear Neurospora mutants having defective respiration. Eighteen different ts respiratory mutants have been isolated. Most of them are pleiotropic and defective in one or more of the following phenotypes: cytochrome aa3, b, and c (individual or multiple defects); oligomycin inhibition of ATPase activity; respiration and its inhibition by KCN and salicyl hydroxamic acid; and growth rates in liquid and solid media at 25 degrees and 38 degrees. Among these mutants are the first cytochrome c mutant of Neurospora and an extranuclear ts ATPase mutant. An added bonus was the fact that over half of the mutants were affected either in ribosome assembly or in protein synthesis in the mitochondrion. We have yet to find any mutants completely lacking activities associated with the respiratory chain. However, the wide spectrum of mutants isolated here, along with those currently available, constitutes a considerable resource for investigating respiration in obligate aerobes.     

Mutation Induction by Difunctional Alkylating Agents in NEUROSPORA CRASSA

The genetic characterization of ad-3 mutants of Neurospora crassa induced by two carcinogenic difunctional akylating agents, 1,2,4,5-diepoxypentane (DEP) and 1,2,7,8-diepoxyoctane (DEO), has shown that point mutations at the ad-3B locus have similar complementation patterns. In addition to the induction of point mutations, DEP induces a low frequency (7.5%) of multilocus deletions, whereas DEO induces an extremely high frequency (42.0%). The distribution of the different classes of ad-3 mutants and the frequency of multilocus deletion mutants among DEP-induced mutants are not significantly different from those induced by the monofunctional alkylating agents EI, EMS and ICR-177 at comparable forward-mutation frequencies. Moreover, the frequencies of DEP-induced ad-3B mutants showing allelic completion or having nonpolarized complementation patterns are similar to those of ad-3B mutants induced by monofunctional agents. It is suggested, therefore, that the mechanism of mutation-induction by DEP in N. crassa is similar to that of monofunctional alkylating agents. Mutation-induction by DEO probably results both from the mechanism of action of monofunctional alkylating agents and from inter-strand cross-linkage of the DNA molecular by the two functional epoxy groups.     

The Isolation and Characterization of Mutants Defective in Nitrate Assimilation in NEUROSPORA CRASSA

The isolation and characterization of mutants altered for nitrate assimilation in Neurospora crassa is described. The mutants isolated can be subdivided into five classes on the basis of growth tests that correspond to the growth patterns of existing mutants at six distinct loci. Mutants with growth characteristics like those of nit-2, nit-3 and nit-6 are assigned to those loci on the basis of noncomplementation and lack of recombination. Mutants that, from their growth patterns, appear to lack the molybdenum-containing co-factor for both nitrate reductase and xanthine dehydrogenase subdivide into three loci (nit-7, nit-8 and nit-9), all of which are genetically distinct from nit-1. nit-9 is a complex locus consisting of three complementation groups and thus appears similar to the cnxABC locus of Asperillus nidulans. Extensive complementational and recombinational analyses reveal that nit-4 and nit-5 are alleles of the same locus, and two new alleles of that locus have been isolated. The results indicate that, as in A. nidulans, nitrate assimilation in N. crassa requires at least four loci (nit-1, 7, 8 and 9) to produce the molybdenum co-factor for nitrate reductase (and xanthine dehydrogenase), one locus (nit-3) to code for the nitrate reductase apoprotein, one locus (nit-6) to code for the nitrite reductase approtein and only one locus (nit-4/5) for the regulation of induction of the pathway by nitrate and nitrite.     

STUDIES ON A CYTOPLASMIC CHARACTER IN NEUROSPORA CRASSA

Two morphologically distinctive slow growing strains of Neurospora crassa have been isolated and studied. These, abn-1 and abn-2, differ from wild type in that their growth rates are greatly reduced and often irregular, aerial hyphae are absent, conidia are extremely rare, and no protoperithecia are formed. Growth was not improved by addition of any nutrients tested, oxygen consumption was similar to that of wild type, and cytochrome c appeared abnormally high, and b low or absent. Both abn strains gave rise only to normal progeny in crosses with normal strains. The abn characteristics appear in heterocaryons, and have been transmitted to other genetic strains by means of heterocaryosis followed by plating of conidia. Conidia formed by such heterocaryons typically showed low viability, and gave rise to cultures with great variability in growth rate, morphology, and survival. Even apparently normal derived cultures often later became abnormal or died. It is concluded that the abnormal characteristics are determined primarily by cytoplasmic factors. This conclusion was strengthened by the transmission of the typical characteristics to normal strains by microinjection of cytoplasm from abn cultures, even without demonstrable transfer of nuclei. This constitutes the first time microinjection techniques have been successfully applied to the analysis of a cytoplasmic character in Neurospora.     

Isolation and Properties of Selenomethionine-Resistant Mutants of NEUROSPORA CRASSA

Mutants resistant to selenomethionine were isolated, and their properties studied. Mapping studies indicate that the mutation sites are located near the eth-1(r) locus in linkage group I, about ten map units away from the mating type locus. The sites of new mutation are either allelic to or very close to eth-1(r). They are resistant not only to selenomethionine but also to ethionine, while the ethionine-resistant mutant, eth-1(r), is sensitive to selenomethionine. The selenomethionine-resistant mutants are also temperature-sensitive mutants. However, they can grow at higher temperatures in medium containing 1 M glycerol.-It is very unlikely that the resistance is due to a change in the permeability of the membrane. Aryl sulfatase of se-met(r) mutants is not repressed by a high concentration of methionine (5 mM), although inorganic sulfate (2 mM) still can cause total repression. The gamma-cystathionase levels of the mutants are normal, but the S-adenosylmethionine synthetase levels are only one-tenth of that observed in the wild-type strain. The heat-stability of this enzyme in the mutant is also different from that of the wild-type enzyme suggesting that the mutation might affect the structural gene of S-adenosylmethionine synthetase.     

Isolation and Classification of Extranuclear Mutants of NEUROSPORA CRASSA

Four extranuclear mutants, [exn-1], [exn-2],[exn-4], and [stp-C], were obtained from N-methyl-N'-nitro-N-nitrosoguanidine-treated conidia and mycelium of Neurospora crassa. The three exn mutants grow with a pronounced lag from conidia and ascospores and are female fertile, whereas [stp-C] has a stop-start growth phenotype and is female sterile. The mitochondria from all four mutants are deficient in cytochromes a+a(3) and b, but contain an excess of cytochrome c. On the basis of growth and fertility, nuclear suppressors and complementation in heteroplasmons, 16 of the extranuclear mutants now available in Neurospora can be divided into three groups. Group I consists of 8 female-fertile variants with both poky-like growth and cytochrome defects. Their slow growth is suppressed by the nuclear factor, f, but not by a second nuclear suppressor, su-1([mi-3]). They complement with group III mutants in mixed cytoplasmons. Group II is represented by a single variant, [mi-3]. It is phenotypically modified by the su-1([mi-3]) factor, but not by f. Its unique cytochrome spectrum shows a deficiency of cytochrome a, but c and b are present. It complements in heteroplasmons with group I and III mutants. Group III included 7 female-sterile variants with stopper growth phenotypes and the same cytochrome defects as group I. Group III mutants complement both with group I and II isolates, but they are unaffected by either f or su-1.     

The Isolation of Mms- and Histidine-Sensitive Mutants in NEUROSPORA CRASSA

A simple method of replica plating has been used to isolate mutants of Neurospora crassa that have increased sensitivity to methyl methanesulfonate (MMS) and/or to histidine. Twelve mutants with increased sensitivity to MMS and one mutant with increased sensitivity to histidine showed Mendelian segregation of the mutant phenotypes. Three mutants were mapped to loci not previously associated with MMS sensitivity. Two others were allelic to the UV- and MMS-sensitive mutant, mei-3. Survival curves indicate that conidia (mutant or wild-type) survive on much higher concentrations of MMS at 25° than at 37°. In contrast, mycelial growth is more resistant to MMS at 37°. The possibility of qualitatively different repair processes at these two temperatures is discussed.     

FORMATION OF MITOCHONDRIA IN NEUROSPORA CRASSA : A Quantitative Radioautographic Study

Cells of a choline-requiring mutant of Neurospora crassa, labeled with radioactive choline, were transferred to unlabeled medium. At various times during their subsequent logarithmic growth, a highly purified mitochondrial fraction was prepared by sucrose density gradient centrifugation, and the distribution of label among individual mitochondria was determined by quantitative autoradiography. Preliminary experiments indicated that, under the conditions of this "washout" experiment, choline served as a stable mitochondrial label. Radioautographic analysis showed that, in fully labeled mycelia and for three mass doubling cycles in the unlabeled medium, radioactivity was randomly distributed among all mitochondria; i.e., the distribution of autographic grains among individual mitochondria followed a Poisson distribution. In experiments in which pulse labeling for 10 minutes was used, the label was randomly distributed among all mitochondria. The data suggest that the mitochondrial mass is increased by a continuous process of addition of new lecithin units to the already existing mitochondrial framework.     

A CYTOPLASMIC CHARACTER IN NEUROSPORA CRASSA : The Role of Nuclei and Mitochondria

Nuclear fractions isolated from mutants of Neurospora produced no effect when microinjected into mutants with complementary biochemical requirements. DNA isolated from the nuclear fractions similarly injected also had no effect. Mitochondrial fractions isolated from an abnormal inositolless strain (abn-1) produced drastic changes in the rate of growth, morphology, reproductive characteristics, and cytochrome spectra of normal inositolless strains when single hyphal compartments were microinjected and isolated, whereas the mitochondrial fractions of the wild type produced no effect. These results provide evidence for the transmission of biochemical and biological characters when mitochondria are transferred to new nucleocytoplasmic environments.     

A RELATIONSHIP BETWEEN CELL WALL STRUCTURE AND COLONIAL GROWTH IN NEUROSPORA CRASSA

de Terra, Noël, and E. L. Tatum. (Rockefeller Inst., New York, N. Y.) A relationship between cell wall structure and colonial growth in Neurospora crassa . Amer.Jour. Bot. 50(7): 669–677. Illus. 1963.—Cell walls were isolated from morphological mutants of Neurospora crassa and from their corresponding wild-type strains. Acid hydrolysates prepared from these cell walls were then studied, qualitatively and quantitatively, with respect to their reducing sugar content. Paper chromatography revealed the presence of glucose and glucosamine in the cell walls of all strains studied. Quantitative analysis has shown that a group of 4 colonial mutants which strongly resemble each other in morphology all have significantly less glucose and more glucosamine per unit weight of cell wall than do their corresponding wild-type strains. These data strongly suggest that a particular type of morphological aberration in Neurospora is associated with similar changes in cell wall composition.     

FORMATION OF MITOCHONDRIA IN NEUROSPORA CRASSA : A Study Based on Mitochondrial Density Changes

The choline concentration used in the growth medium influences the density of mitochondria produced by the chol-1 mutant of Neurospora. Isopycnic centrifugation in sucrose gradients can be used to determine the density of mitochondria, and can resolve into two populations, mitochondria derived from a mixture of cells grown at low (1 µg/ml choline chloride) and high (10 µg/ml choline chloride) choline levels. In an experiment in which cells are shifted from low to high choline growth conditions, mitochondria obtained after varying time periods show a gradual decrease in density tending toward the level typical of high choline mitochondria. Over a 90-minute period of observation, during which time there is an increase of mitochondrial protein mass of ~ 50 per cent over that initially present, the mitochondria change density as a single population. These results are consistent with the view that mitochondria grow by random accretion of new lecithin into existing mitochondrial structures, and also that the mitochondrial population increases by division.     

Super Suppressors in NEUROSPORA CRASSA I. Induction, Genetic Localization and Relationship to a Missense Suppressor

Genetic analyses have been made to test the feasibility of using coincident reversions to prototrophy of multiple mutants to select super suppressors (ssu) in Neurospora crassa. Of five double-mutant strains examined, only those mutant combinations in which both members had the properties of nonsense mutations did revert coincidently. Forty-eight genetically purified coincident revertants were crossed to the wild type, and each was shown to contain a suppressor mutation. Five super suppressors were examined more thoroughly. Tetrad and random spore analysis was used to demonstrate that each behaved as a single gene in crosses. Two super suppressors, ssu-1 and ssu-4 were localized respectively on the right and left arm of linkage group 7. Two others, ssu-2 and ssu-3, appear to map on the right arm of linkage group 1. The fifth super suppressor mapped, ssu-7, lies between ad-8 and ylo-1 on linkage group 6. One super suppressor, ssu-1, was interesting because it mapped near the location reported for the suppressor of the missense mutant tryp-3(td201) (Yourno and Suskind 1964a). However, no overlap was found in action spectrum of the two suppressors. Tetrad analysis showed the two suppressors were located about 10 map units apart, the missense suppressor being the more distal to the centromere.     

Regulation of Phosphate Metabolism in NEUROSPORA CRASSA: Isolation of Mutants Deficient in the Repressible Alkaline Phosphatase

Mutants of Neurospora crassa have been isolated that lack the repressible alkaline phosphatase, but, unlike nuc-1 and nuc-2 mutants, are able to make the repressible acid phosphatase and the repressible phosphate permease under conditions of derepression (phosphate deprivation). The new mutants, called pho-2, map in Linkage Group V, and are unlinked to the putative control mutants, nuc-1, nuc-2-pcon(c), and preg(c). Three of the pho-2 mutants do not make detectable amounts of repressible alkaline phosphatase, but the fourth makes about 1% of the level found in wild type. The small amount of alkaline phosphatase made by this strain appears to be qualitatively similar or identical to the wild-type enzyme, as judged by electrophoretic mobility, heat stability, and titration with specific antibody to the wild-type enzyme. Several revertants of this strain have been examined in the same way, and the alkaline phosphatase of these strains also appears to be qualitatively normal. Reversion events can occur at, or near, the pho-2 locus, but also occur in at least two unlinked sites (suppressor mutations). One suppressor maps very close to nuc-1.     

Meiosis in NEUROSPORA CRASSA. II. Genetic and Cytological Characterization of Three Meiotic Mutants

Three recessive meiotic mutants, asc(DL95), asc(DL243) and asc(DL879), were detected by the abortion of many of their ascospores and were analyzed using both cytological and genetic methods. Even though asc(DL95), asc (DL243) and the previously studied meiotic mutant, mei-1 (Smith 1975; Lu and Galeazzi (1978), complement one another in crosses, they apparently do not recombine (DeLange and Griffiths (1980). Thus, they may represent alleles of the same gene or comprise a gene cluster. Ascospore abortion in these mutants is caused by abnormal disjunction of meiotic chromosomes. In crosses homozygous for asc(DL95), asc(DL879) or mei-1, both pairing of homologs and meiotic recombination frequencies are reduced. In each case, this primary defect is followed by the formation of univalents at metaphase I and their irregular segregation. The mutant asc(DL243) has a defect in ascus formation, and later in disjunction during the second meiotic and post-meiotic divisions. The first-acting defect before or during karyogamy results in the abortion of most cells. Some cells manage to proceed past this block. During the second meiotic division, most chromosomes of the few resulting asci are attached to only one of the two spindle-pole bodies. Disjunction at the post-meiotic division is also highly irregular. This mutant appears to be defective in the attachment of one spindle-pole body to a set of chromosomes. The defect may involve either a centromere-associated product or a spindle-pole body.     

The frq Locus in NEUROSPORA CRASSA: A Key Element in Circadian Clock Organization

Four new circadian clock mutants of Neurospora crassa have been isolated that alter the period length of the circadian conidiation rhythm. Three of these are at the frq locus on linkage group VIIR, where four other clock mutants are located. In contrast to wild type, which has a period length of 21.6 hr, frq-6 has a period length of 19 hr, while frq-7 and frq-8 have period lengths of 29 hr and represent the largest effects of any single gene mutants on circadian periodicity. Thus, seven mutants have now been isolated that map to the frq locus, with period lengths ranging from 16.5 to 29 hr, and each mutant alters clock periodicity by an integral multiple of 2.5 hr. In addition, all frq mutants show incomplete dominance in heterokaryons. The large percentage of clock mutants that map to this locus, coupled with their unique properties, suggests that the frq locus plays an important role in clock organization.—The fourth mutant, designated chrono (chr), has a period length of 23.5 hr, shows incomplete dominance and is unlinked to either of the previously identified clock loci, frq or prd (formerly called frq-5). Double mutants between various combinations of clock mutants show additive effects and indicate no significant gene interaction among mutants at these three loci.