Characterization of Neurospora crassa and Fusarium graminearum mutants defective in repeat-induced point mutation

Pomraning, Kyle R.

10 December 2014

Mutation of repetitive DNA by repeat-induced point mutation (RIP) is a process that occurs in many filamentous fungi of the Ascomycota during the sexual cycle. Concurrently, direct DNA repeats are often deleted by homologous recombination at high frequency during the sexual cycle. Thus, the processes of RIP and deletion compete to either mutate or remove repetitive DNA from the genome of filamentous fungi during sexual cycles. Both processes contribute to genome streamlining by controlling proliferation of transposable elements and by limiting expansion of gene families. While the genetic requirements for deletion by homologous recombination are well known, the mechanism behind the specific detection and mutation of repetitive DNA by RIP has yet to be elucidated as only a single gene essential for RIP, rid, has been identified. We have developed Fusarium graminearum as a model organism for the study of RIP by showing that it mutates repetitive DNA frequently during the sexual cycle and that the mutations due to RIP are dependent on rid. Further, we have sequenced a genetic mapping strain of F. graminearum (00-676-2) and identified 62,310 single nucleotide polymorphisms (SNPs) compared to the reference strain (PH-1). The SNP map will be useful for quickly mapping new mutants by bulk segregant analysis and high-throughput sequencing for which bioinformatic tools were specifically developed. The groundwork has thus been laid for identification of novel RIP mutants in F. graminearum, which being homothallic has a major advantage for identification of recessive mutations. We used a forward genetics approach to shed light on the mechanism of RIP in Neurospora crassa. Two rrr mutants that dominantly r��educe R��IP and r��ecombination were characterized and identified as different mutated alleles of the same gene, rrr-1[superscript L496P] and rrr-1[superscript G325N] by bulk segregant analysis and high-throughput sequencing. Bioinformatic characterization suggests RRR-1 belongs to a previously uncharacterized group of dynamin-like proteins, which are generally involved in membrane fission and fusion. RRR-1-GFP localizes to the nuclear membrane, but not DNA, suggesting it affects RIP and recombination frequency indirectly by altering nuclear membrane dynamics during sexual development and thereby altering temporal aspects of RIP and recombination. We used a reverse genetics approach to determine whether high frequency RIP and homologous recombination of repetitive DNA during the sexual cycle are linked mechanistically or spatio-temporally. We tested strains where genes important for deletion by homologous recombination were knocked out and found all to be completely RIP competent except mre11, which, while sterile in homozygous deletion crosses, displayed lower RIP frequency in heterozygous crosses. This suggests that mre11 has roles in homologous recombination as well as non-homologous end joining may be important for RIP. Collectively, this work developed methods for efficiently mapping mutations and identified a novel protein that reduces RIP and recombination frequency but did not identify any mechanistic link between the two processes. / Graduation date: 2013 / Access restricted to the OSU Community at author's request from Dec. 10, 2012 - Dec. 10, 2014

repeat-induced point mutation

RIP

Neurospora crassa

Neurospora crassa -- Molecular genetics

Fusarium -- Molecular genetics

Mutation (Biology)

Studies on the centromere-specific histone, CenH3, of Neurospora crassa and related ascomycetes

Phatale, Pallavi A.

10 December 2012

In eukaryotes, the defined loci on each chromosome, the centromeres, accomplish the critical task of correct cell division. In some organisms, centromeres are composed of a euchromatic central core region embedded in a stretch of heterochromatin and the inheritance and maintenance of centromeres are controlled by dynamic epigenetic phenomena. Although the size of centromeres differs between organisms, its organization, and the placement of euchromatic and heterochromatic regions is conserved from the fission yeast, Schizosaccharomyces pombe, to humans, Homo sapiens. However, relatively little is known about centromeres in the filamentous fungi from the Ascomycota, representing the largest group of fungi and fungal pathogens. Further, studies from humans, flies, yeast and plants have shown that the inheritance of centromeres is not strictly guided by centromeric DNA content, which is highly AT-rich, repetitive and constantly evolving. Therefore, it is difficult to align ans assemble the sequenced contigs of centromeric regions of higher eukaryotes, including most filamentous fungi. A genetic technique, tetrad (or octad) analysis has helped to map the centromeres of the filamentous fungus Neurospora crassa early on. The research presented in this dissertation used N. crassa as a model to focus on characterizing different features of centromeres with an emphasis on the centromere-specific histone H3 (CenH3) protein. Data included here represent the first study on centromere-specific proteins in Neurospora, and demonstrate that the central core of the centromeres are heterochromatic, showing enrichment of silent histone marks, which is in contrast to the centromere arrangement in fission yeast. The CenH3 protein, whose deposition on the genome licenses formation or maintenance of centromeres, shows highly divergent N-terminal regions and a conserved histone fold domain (HFD) in all eukaryotes. This bipartite nature of CenH3 is also observed in the Ascomycota, which provides an opportunity for functional complementation assays by replacing Neurospora CenH3 (NcCenH3) with CenH3 genes from other species within the Ascomycota. The results from this experimental approach provide good measures for (1) determining the specific regions of CenH3 required for the assembly of centromeres during meiotic and mitotic cell divisions and (2) analyzing the resistance to changes in the organization of centromeres in N. crassa. The genetic analysis showed that the divergent N-terminal region is essential for the proper assembly of centromeres, and that the conserved carboxy-terminus of CenH3 is important for the process of meiosis but not mitotic cell division. ChIP-seq analyses suggest that the observed loss of Podospora anserina CenH3 (PaCenH3- GFP) from certain N. crassa centromeres does not result in obvious phenotypic defects, e.g. diminished growth or evidence for aneuploidy. Further, the low enrichment of PaCenH3-GFP at certain centromeres is possibly predetermined during meiosis, which results in irreversible and progressive decreases in enrichment. It remains to be determined if this process is random as far as selection of centromeres is concerned. Together the results presented here suggest that during meiosis more stringent structural requirements for centromere assembly apply and that these are dependent on CenH3, and that depletion of CenH3 from centromeres does not critically affect mitosis in the asynchronously dividing nuclei of Neurospora hyphae. / Graduation date: 2013

histone

centromere

fungi

neurospora

heterochormatin

Neurospora crassa -- Molecular genetics

Histones

Heterochromatin

Centromere