Occurrence of repeat induced point mutation in long segmental duplications of Neurospora.

Previous studies of repeat induced point mutation (RIP) have typically involved gene-size duplications resulting from insertion of transforming DNA at ectopic chromosomal positions. To ascertain whether genes in larger duplications are subject to RIP, progeny were examined from crosses heterozygous for long segmental duplications obtained using insertional or quasiterminal translocations. Of 17 distinct mutations from crossing 11 different duplications, 13 mapped within the segment that was duplicated in the parent, one was closely linked, and three were unlinked. Half of the mutations in duplicated segments were at previously unknown loci. The mutations were recessive and were expressed both in haploid and in duplication progeny from Duplication x Normal, suggesting that both copies of the wild-type gene had undergone RIP. Seven transition mutations characteristic of RIP were found in 395 base pairs (bp) examined in one ro-11 allele from these crosses and three were found in approximately 750 bp of another. A single chain-terminating C to T mutation was found in 800 bp of arg-6. RIP is thus responsible. These results are consistent with the idea that the impaired fertility that is characteristic of segmental duplications is due to inactivation by RIP of genes needed for progression through the sexual cycle.

Mapping chromosome landmarks in the centromere I region of Neurospora crassa.

Chromosome translocation breakpoints, RFLP heterozygosity in partial chromosome duplications, and RFLP-marked crossover events have been used as chromosomal landmarks to find the position and orientation of cloned regions flanking centromere I of Neurospora crassa. Determination of physical:genetic ratios in genomic regions flanking the loci mei-3, un-2, and his-2 supports previous evidence indicating that recombinational activity is lower in regions flanking centromere I than in the general N. crassa genome. The homogeneous distribution of crossover events found in these regions suggests that there is not a gradient of crossover inhibition in the vicinity of centromere I. Thus, a largely extended centromeric effect and/or a general crossover inhibitory effect operating on linkage group I (LGI) could constitute the basis of these abnormal physical:genetic ratios. A DNA element containing about 76% A+T was isolated from the centromeric end of a cloned region on LGIR. The fragment includes a previously undescribed DNA sequence, highly repeated in the Neurospora genome, which may correspond to centromeric DNA.

Physical mapping of meiotic crossover events in a 200-kb region of Neurospora crassa linkage group I.

We propose a general restriction fragment length polymorphism-based strategy to analyze the distribution of meiotic crossover events throughout specific genetic intervals. We have isolated 64 recombinant chromosomes carrying independent meiotic crossover events in the genetic interval eth-1-un-2 on linkage group I of Neurospora crassa. Thirty-eight crossover events were physically mapped with reference to a 200-kb region cloned by chromosome walking, using N. crassa lambda and cosmid libraries. Crossovers were homogeneously distributed at intervals of 5.0 +/- 2.3 kb along the entire cloned interval. The ratio of physical to genetic distance appears to be higher in the region than in the overall N. crassa genome, suggesting that recombinational activity is less in large chromosomes than in small ones. The present work provides a method for defining the centromeric-telomeric orientation of single cloned DNA fragments. Their physical distance can also be estimated with respect to linked loci, provided that crossover events are distributed homogeneously in the interval. This strategy overcomes typical difficulties in defining the position and direction of chromosome walking steps on conventional linkage maps.

Molecular cloning of a gene (cfp) encoding the cytoplasmic filament protein P59Nc and its genetic relationship to the snowflake locus of Neurospora crassa.

P59Nc is a 59-kD polypeptide associated with 8-10-nm diameter cellular filaments in normal Neurospora crassa strains. Abnormally sized and shaped bundles of these structures are present in N. crassa strains carrying mutations at the locus sn (snowflake). By using molecular cloning and restriction fragment length polymorphism (RFLP) segregation analysis strategies we show here that sn is not the genetic locus of P59Nc. Several P59Nc cDNAs were cloned from a N. crassa lambda GT11 library after immunoscreening with specific polyclonal anti-P59Nc antibodies. Additional longer cDNAs were obtained from a N. crassa cDNA-lambda ZAP library. When used as probes in Southern blots of total DNA from wild-type strains, multicent-2 (a multiple mutant strain), and snowflake mutants, the P59Nc cDNAs revealed comparable patterns of hybridizing bands for all of the restriction enzymes tested. Analysis of segregation of BclI and ClaI RFLPs, detected in the genomic region of the P59Nc gene (locus cfp: cellular filament polypeptide), among a set of strains designed for RFLP mapping, or among selected progeny of crosses involving a snowflake parent, respectively, indicate that (i) there is in N. crassa a single cfp locus positioned on the right arm of linkage group VII between the locus for and the proximal breakpoint of the translocation T(VII----I)5936; (ii) the sn mutations in the centromere region of chromosome I do not represent translocations of cfp; and (iii) the snowflake mutants possesses a normal copy of the P59Nc gene on their chromosomes VII.(ABSTRACT TRUNCATED AT 250 WORDS)