The function and specificity of the C-terminal tripeptide glyoxysomal targeting signal in Neurospora crassa

The function of the C-terminal tripeptide targeting signal responsible for microbody targeting in many eukaryotes has been investigated in the filamentous fugus Neurospora crassa. Using an in-vivo targeting assay that employs transformants carrying C-terminally-modified versions of the bacterial enzyme chloramphenicol acetyltransferase (CAT), it has been demonstrated that C-terminal tripeptide-dependent import occurs most efficiently in response to nutritional acetate-induction. Under these conditions Neurospora generates a specialized organelle, the glyoxysome, which carries the enzymes responsible for the glyoxylate cycle and can be distinguished from peroxisome-like microbodies that contain catalase. Moreover, several C-terminal peptides have been tested in this system to extend the tripeptide targeting consensus to A/C/G/S-H/K/Q/R-I/L/V. However, the tripeptide analogue, ARM, found at the C-terminus of the glyoxylate cycle enzyme isocitrate lyase in higher plants, does not apparently function here.     

Genetic analysis of ad-3 mutants induced by AF-2 and two other nitrofurans in neurospora crassa

Our previous studies have shown that the nitrofurans AF-2, SQ18506, and FANFT are potent mutagens in Neurospora crassa. The genetic damage produced by these chemicals at the ad-3 region in N crassa has been characterized by a series of genetic tests. The results of these tests indicate that all three agents induce a high frequency of point mutations and probably a low frequency of multilocus deletions. A comparison of the complementation patterns among the AF-2-induced ad-3B mutants and those induced by other chemical agents indicates that the spectra of intragenic alterations induced by AF-2 in N crassa are similar to those induced by monofunctional alkylating agents.     

Circadian rhythms

Circadian rhythms are a ubiquitous adaptation of eukaryotic organisms to the most reliable and predictable of environmental changes, the daily cycles of light and temperature. Prominent daily rhythms in behavior, physiology, hormone levels and biochemistry (including gene expression) are not merely responses to these environmental cycles, however, but embody the organism's ability to keep and tell time. At the core of circadian systems is a mysterious mechanism, located in the brain (actually the Suprachiasmatic nucleus of the hypothalamus) of mammals, but present even in unicellular organisms, that functions as a clock. This clock drives circadian rhythms. It is independent of, but remains responsive to, environmental cycles (especially light). The interest in temporal regulation — its organization, mechanism and consequences — unites investigators in diverse disciplines studying otherwise disparate systems. This diversity is reflected in the brief reviews that summarize the presentations at a meeting on circadian rhythms held in New York City on October 31, 1992. The meeting was sponsored by the Fondation pour l'Étude du Systéme Nerveux (FESN) and followed a larger meeting held 18 months earlier in Geneva, whose proceedings have been published (M. Zatz (Ed.), Report of the Ninth FESN Study Group on ‘Circadian Rhythms’, Discussions in Neuroscience, Vol. VIII, Nos. 2 + 3, Elsevier, Amsterdam, 1992). Some speakers described progress made in the interim, while others addressed aspects of the field not previously covered.     

Double stranded RNA in natural isolates ofNeurospora

Thirty-six wild type isolates ofNeurospora were surveyed for the presence of dsRNA. The survey identified seven strains which contain dsRNA molecules. These seven strains are all from different geographic locations. The sizes of the dsRNAs range from 500 bp to 18 kb and a total of seven distinct dsRNA species was identified. Cross homologies of some of the dsRNAs were apparent. There was homology between the 9.0 kb dsRNA and genomic DNA prepared from all strains in the survey, indicating a possible cellular rather than viral origin for this dsRNA species. None of the other dsRNAs hybridized with genomic DNA suggesting a viral origin for these dsRNAs.     

Highly efficient gene replacements in Neurospora strains deficient for nonhomologous end-joining

Gene disruption and overexpression play central roles in the analysis of gene function. Homologous recombination is, in principle, the most efficient method of disrupting, modifying, or replacing a target gene. Although homologous integration of exogenous DNA into the genome occurs readily in Saccharomyces cerevisiae, it is rare in many other organisms. We identified and disrupted Neurospora crassa genes homologous to human KU70 and KU80, which encode proteins that function in nonhomologous end-joining of double-stranded DNA breaks. The resulting mutants, named mus-51 and mus-52, showed higher sensitivity to methyl methanesulfonate, ethyl methanesulfonate, and bleomycin than wild type, but not to UV, 4-nitroquinoline 1-oxide, camptothecin, or hydroxyurea. Vegetative growth, conidiation, and ascospore production in homozygous crosses were normal. The frequency of integration of exogenous DNA into homologous sequences of the genome in the KU disruption strains of N. crassa was compared with that in wild type, mei-3, and mus-11. In mei-3 and mus-11, which are defective in homologous recombination, none or few homologous integration events were observed under any conditions. When mtr target DNA with approximately 2-kb 5' and 3' flanking regions was used for transformation of the KU disruption strains, 100% of transformants exhibited integration at the homologous site, compared to 10 to 30% for a wild-type recipient. Similar results were obtained when the ad-3A gene was targeted for disruption. These results indicate that KU disruption strains are efficient recipients for gene targeting.     

A recombinant plasmid carrying the mitochondrial plasmid sequence of Neurospora intermedia LaBelle yields new plasmid derivatives in Neurospora crassa transformants

Summary We have studied the efficacy of transformation of Neurospora crassa with a chimaeric plasmid. We constructed a recombinant plasmid, pMK2, consisting of the mitochondrial plasmid of N. intermedia LaBelle, a part of the qa gene cluster of Neurospora and the Escherichia coli plasmid pBR322. Compared to plasmid pVK88, not containing the LaBelle sequence, the pMK2 plasmid gives a five-fold increase in transformation of the qa2⁺ gene. Analysis of the DNA from Neurospora transformants revealed that the pMK2 plasmid is not stable. The qa insert as well as the LaBelle part of pMK2 are rapidly lost from the plasmid. In most cases the qa insert integrates into the nuclear DNA of the host. Plasmids recovered from Neurospora transformants are rearranged and show insertions or deletions. Some of these plasmids are described here. In most cases the qa insert and the LaBelle sequence of plasmid pMK2 have been deleted. Frequently plasmid dimers, carrying an insertion of mitochondrial DNA, are recovered.     

Molecular cloning and physical mapping of the Neurospora crassa 74-OR23-1A mitochondrial genome

Summary To provide for thorough sampling of the Neurospora crassa mitochondrial genome for evolutionary studies, recombinant plasmids containing each of the EcoRI digestion fragments of the genome were assembled and used to map the locations of 89 additional restriction endonuclease cleavage sites, representing 10 newly mapped enzymes and 2 previously unmapped HincII sites. Data used to locate new restriction sites were obtained from digestions of whole mitochondrial DNA, digestions of the cloned EcoRI mitochondrial DNA fragments and hybridizations between new restriction fragments and the cloned fragments. Length measurements of the total genome and of EcoRI fragment 1 are larger than commonly reported.     

Transfer of Neurospora kalilo plasmids among species and strains by introgression

There are four different variants of the kalilo “family” of linear mitochondrial plasmids. This family is found in several heterothallic species and one pseudohomothallic species of Neurospora, as well as in one homothallic species of Gelasinospora. The mode of dispersal of these plasmids is not known. Horizontal transmission has proved difficult to demonstrate. Another possibility is transfer by introgression, and this is modelled in the present paper. We have used introgression and subsequent heterokaryosis to successfully transfer the LA-kalilo plasmid from a Haitian strain of Neurospora crassa to the standard Oak Ridge N. crassa background, the LA-kalilo plasmid from the pseudohomothallic Neurospora tetrasperma to N. crassa, and the kalilo plasmid from N. crassa to N. tetrasperma. Thus, introgression is shown to be a possible avenue of dispersal between species. The recipient strains were all senescent but the mechanism of this senescence is not known. It could be caused by the plasmids, but if so the mechanism is novel since plasmid/mtDNA junction fragments of the type found in the standard mode of mtDNA insertion could not be detected. However, mtDNA changes were observed in the senescent recipients. Received: 15 February / 24 June 1999     

Characterization of Neurospora crassa mutants isolated following repeat-induced point mutation of the beta subunit of fatty acid synthase

Neurospora crassacel-2 mutants were isolated following repeat-induced point mutation using part of the gene encoding β-fatty acid synthase. These mutants are phenotypically less leaky than cel-1, which has a defective α-fatty acid synthase. The cel-2 mutant had a strict fatty acid (16:0) requirement for growth, and syn-thesized less fatty acid de novo than cel-1. Unlike cel-1, cel-2 has impaired fertility, and homozygous crosses are infertile, suggesting a low but strict requirement for fatty acid synthesis during sexual development. Like cel-1, cel-2 synthesized unusually high levels of the polyunsaturate 18:3^Δ9,12,15, and elongated 18:2^Δ9,12 and 18:3^Δ9,12,15 to 20:2^Δ11,14 and 20:3^Δ11,14,17, respectively. These fatty acids are not synthesized by wild-type, except following treatment with cerulenin (a fatty acid synthase inhibitor), demonstrating that inhibition of fatty acid biosynthesis results in a relative increase in both fatty acid desaturation and elongation activity. Received: 19 November 1998 / 15 March 1999