Mild RIP — an alternative method for in vivo mutagenesis of thealbino-3 gene inNeurospora crassa

We have used a biological phenomenon that occurs inNeurospora crassa, termed Repeat-Induced Point mutation (RIP), to create partially functional mutant alleles of thealbino-3 (al-3) gene encoding geranylgeranyl pyrophosphate synthase, an enzyme involved in the biosynthesis of carotenoids and diverse prenylated compounds. A total of 70 RIP-inducedal- 3 mutants were identified by their pale albino phenotype, resulting from inactivation of carotenoid biosynthesis. Nucleotide sequence analysis of theal-3 gene in five of the RIP-induced mutants revealed that in each case RIP had introduced no more than six point mutations. The low frequency of RIP mutants (0.42%) and the isolation of only leaky mutants with very few mutations suggest that ascospores containing a heavily mutatedal-3 gene do not survive. These results are evidence that the RIP phenomenon, used to inactivate and silence duplicated genes inN. crassa, may be exploited in its mild version as a method of sequence-specific in vivo mutagenesis to obtain functional mutant alleles ofNeurospora genes. This mild form of mutagenesis may be particularly advantageous in selecting for leaky mutations in essentialNeurospora genes.     

Evidence for dominant suppression of repeat-induced point mutation (RIP) in crosses with the wild-isolatedNeurospora crassa strains Sugartown and Adiopodoume-7

A convenient assay to score repeat-induced point mutation (RIP) inNeurospora employs theerg-3 locus as a mutagenesis target. Using this assay we screened 132 wild-isolatedNeurospora crassa strains for ability to dominantly suppress RIP. RIP was exceptionally inefficient in crosses with the wild isolates Sugartown (P0854) and Adiopodoume-7 (P4305), thereby suggesting the presence of dominant RIP suppressors in these strains. In other experiments, we found no evidence for dominant RIP suppression by theSpore killer haplotypesSk-2 andSk-3.     

Calcineurin Subunit B Is Required for Normal Vegetative Growth inNeurospora crassa

A series ofNeurospora crassamutants affected in the ability to regulate entry into conidiation (an asexual developmental program) were isolated by using an insertional mutagenesis procedure followed by a screening protocol. One of the mutants isolated by this approach consisted entirely of cells with an abnormal morphology. The mutant produces chains of swollen septated cells. The developmentally regulatedccg-1gene is constitutively expressed in these cells, suggesting that they have entered the conidial developmental program. The insertionally disrupted genecnb-1was isolated by plasmid rescue and found to encode calcineurin B, the regulatory subunit of the Ca²⁺and calmodulin-dependent protein phosphatase calcineurin. The data demonstrate that calcineurin B is required for normal vegetative growth inN. crassaand suggest that thecnb-1mutant is unable to repress entry into the asexual developmental program. The results suggest that Ca²⁺may play an important role in regulating fungal morphology.     

Gene inactivation in Arabidopsis thaliana is not accompanied by an accumulation of repeat-induced point mutations

Chromosomal integration of multicopy transgene inserts in higher plants is often followed by loss of expression. We have analysed whether this inactivation can trigger repeat-induced point mutations (RIP) as has been observed in Neurospora crassa. We have previously characterized transgenic lines of Arabidopsis thaliana containing the hygromycin phosphotransferase (hpt) gene either as a unique sequence in plants expressing the gene, or as multimeric, closely linked repeats in clones that were resistant to hygromycin directly after transformation but exhibited gene inactivation in the subsequent generation. At the sequence level, we have determined the mutation frequencies in the promoter and coding regions of active and inactive copies of transgene inserts after passage through three sexual generations. No RIP-like mutations were found in inactivated genes. Comparison of our data with those from Neurospora suggest that sequence divergence within plant repetitive DNA is either much slower than in Neurospora or is generated by a different mechanism.     

The circadian conidiation rhythm inNeurospora crassa

The filamentous fungusNeurospora crassais one of the best organisms for analysing the molecular basis of the circadian rhythm observed in asexual spore formation, conidiation. Many clock mutants in which the circadian conidiation rhythm has different characteristics compared to those in the wild-type strain have been isolated since the early 1970s. With the cloning of one of these clock genes,frq, the molecular basis of the circadian clock inNeurosporahas become gradually clearer. Physiological and pharmacological studies have also contributed to our understanding of the physiological basis of the circadian clock inNeurospora. These studies strongly indicate that the circadian clock is based on or is closely related to a network of metabolic processes for cellular activities. Based on these studies, it may be possible to isolate new types of clock mutants which should contribute to a better understanding of the molecular basis of the circadian clock inNeurospora.     

Collateral damage: Spread of repeat-induced point mutation from a duplicated DNA sequence into an adjoining single-copy gene inNeurospora crassa

Repeat-induced point mutation (RIP) is an unusual genome defense mechanism that was discovered inNeurospora crassa. RIP occurs during a sexual cross and induces numerous G : C to A : T mutations in duplicated DNA sequences and also methylates many of the remaining cytosine residues. We measured the susceptibility of theerg-3 gene, present in single copy, to the spread of RIP from duplications of adjoining sequences. Genomic segments of defined length (1, 1.5 or 2 kb) and located at defined distances (0, 0.5, 1 or 2 kb) upstream or downstream of theerg-3 open reading frame (ORF) were amplified by polymerase chain reaction (PCR), and the duplications were created by transformation of the amplified DNA. Crosses were made with the duplication strains and the frequency oferg-3 mutant progeny provided a measure of the spread of RIP from the duplicated segments into theerg-3 gene. Our results suggest that ordinarily RIP-spread does not occur. However, occasionally the mechanism that confines RIP to the duplicated segment seems to fail (frequency 0.1–0.8%) and then RIP can spread across as much as 1 kb of unduplicated DNA. Additionally, the bacterialhph gene appeared to be very susceptible to the spread of RIP-associated cytosine methylation.     

Molybdenum hydroxylases in Drosophila. III. Further characterization of the low xanthine dehydrogenase gene

The biochemical effects of several newly induced low xanthine dehydrogenase (lxd) mutations in Drosophila melanogaster were investigated. When homozygous, all lxd alleles simultaneously interrupt each of the molybdoenzyme activities to approximately the same levels: xanthine dehydrogenase, 25%; aldehyde oxidase, 12%; pyridoxal oxidase, 0%; and sulfite oxidase, 2% as compared to the wild type. In order to evaluate potentially small complementation or dosage effects, mutant stains were made coisogenic for 3R. These enzymes require a molybdenum cofactor, and lxd cofactor levels are also reduced to less than 10% of the wild type. These low levels of molybdoenzyme activities and cofactor activity are maintained throughout development from late larval to adult stages. The lxd alleles exhibit a dosage-dependent effect on molybdoenzyme activities, indicating that these mutants are leaky for wild-type function. In addition, cofactor activity is dependent upon the number of lxd ⁺ genes present. The lxd mutation results in the production of more thermolabile XDH and AO enzyme activities, but this thermolability is not transferred with the cofactor to a reconstituted Neurospora molybdoenzyme. The lxd gene is localized to salivary region 68 A4-9, 0.1 map unit distal to the superoxide dismutase (Sod) gene.