Degenerate MAGGY elements in a subgroup of Pyricularia grisea: a possible example of successful capture of a genetic invader by a fungal genome

The LTR-retrotransposon MAGGY is found sporadically in isolates of Pyricularia grisea (Magnaporthe grisea). Based on a dendrogram constructed by RFLP analysis of rDNA, isolates that carry MAGGY elements were classified into a single cluster that comprised four rDNA types. However, in a few members of this cluster, exemplified by isolates from common millet (Panicum miliaceum), the MAGGY element has distinct features. Southern analysis suggested that these isolates possessed a single copy of a MAGGY-related sequence whose restriction map differed from that of MAGGY itself. Sequence analysis revealed that the MAGGY-related sequence was a degenerate form of MAGGY, characterized by numerous C:G to T:A transitions, which have often been reported to result from RIP (Repeat-induced point mutation) or RIP-like processes. However, the favored target site for C:G to T:A transitions in this fungus, determined by examining a total of 501 sites, was (A/T)pCp(A/T), which differs from that for the RIP process originally reported in Neurospora (CpA), and from that reported in Aspergillus (CpG). The fact that certain members of the cluster of MAGGY carriers retain a single copy of a degenerate MAGGY element implies that the ancestor of these isolates successfully “captured” the invading MAGGY element.     

Degenerate MAGGY elements in a subgroup of Pyricularia grisea : a possible example of successful capture of a genetic invader by a fungal genome

The LTR-retrotransposon MAGGY is found sporadically in isolates of Pyricularia grisea (Magnaporthe grisea). Based on a dendrogram constructed by RFLP analysis of rDNA, isolates that carry MAGGY elements were classified into a single cluster that comprised four rDNA types. However, in a few members of this cluster, exemplified by isolates from common millet (Panicum miliaceum), the MAGGY element has distinct features. Southern analysis suggested that these isolates possessed a single copy of a MAGGY-related sequence whose restriction map differed from that of MAGGY itself. Sequence analysis revealed that the MAGGY-related sequence was a degenerate form of MAGGY, characterized by numerous C:G to T:A transitions, which have often been reported to result from RIP (Repeat-induced point mutation) or RIP-like processes. However, the favored target site for C:G to T:A transitions in this fungus, determined by examining a total of 501 sites, was (A/T)pCp(A/T), which differs from that for the RIP process originally reported in Neurospora (CpA), and from that reported in Aspergillus (CpG). The fact that certain members of the cluster of MAGGY carriers retain a single copy of a degenerate MAGGY element implies that the ancestor of these isolates successfully “captured” the invading MAGGY element. Received: 1 February 1999 / Accepted: 8 April 1999     

Genome quality control: RIP (repeat-induced point mutation) comes to Podospora

RIP (repeat-induced point mutation) is a silencing process discovered in Neurospora crassa and so far clearly established only in this species as a currently occurring process. RIP acts premeiotically on duplicated sequences, resulting in C-G to T-A mutations, with a striking preference for CpA/TpG dinucleotides. In Podospora anserina, an RIP-like event was observed after several rounds of sexual reproduction in a strain with a 40 kb tandem duplication resulting from homologous integration of a cosmid in the mating-type region. The 9 kb sequenced show 106 C-G to T-A transitions, with 80% of the replaced cytosines located in CpA dinucleotides. This led to the alteration of at least six genes, two of which were unidentified. This RIP-like event extended to single-copy genes between the two members of the repeat. The overall data show that the silencing process is strikingly similar to a light form of RIP, unaccompanied by C-methylation. Interestingly, the N. crassa zeta-eta sequence, which acts as a potent de novo C-methylation RIP signal in this species, is weakly methylated when introduced into P. anserina. These results demonstrate that RIP, at least in light forms, can occur beyond N. crassa.     

Altering a gene involved in nuclear distribution increases the repeat-induced point mutation process in the fungus Podospora anserina

Repeat-induced point mutation (RIP) is a homology-dependent gene-silencing mechanism that introduces C:G-to-T:A transitions in duplicated DNA segments. Cis-duplicated sequences can also be affected by another mechanism called premeiotic recombination (PR). Both are active over the sexual cycle of some filamentous fungi, e.g., Neurospora crassa and Podospora anserina. During the sexual cycle, several developmental steps require precise nuclear movement and positioning, but connections between RIP, PR, and nuclear distributions have not yet been established. Previous work has led to the isolation of ami1, the P. anserina ortholog of the Aspergillus nidulans apsA gene, which is required for nuclear positioning. We show here that ami1 is involved in nuclear distribution during the sexual cycle and that alteration of ami1 delays the fruiting-body development. We also demonstrate that ami1 alteration affects loss of transgene functions during the sexual cycle. Genetically linked multiple copies of transgenes are affected by RIP and PR much more frequently in an ami1 mutant cross than in a wild-type cross. Our results suggest that the developmental slowdown of the ami1 mutant during the period of RIP and PR increases time exposure to the duplication detection system and thus increases the frequency of RIP and PR.     

The Neurospora Transposon Tad Is Sensitive to Repeat-Induced Point Mutation (Rip)

RIP (repeat-induced point mutation) efficiently mutates repeated sequences in the sexual phase of the Neurospora crassa life cycle. Nevertheless, an active LINE-like retrotransposon, Tad, was found in a N. crassa strain from Adiopodoume. The possibility was tested that Tad might be resistant to RIP, or that the Adiopodoume strain might be incompetent for RIP. Tad elements derived from the Adiopodoume strain were found to be susceptible to RIP. In addition, strains lacking active Tad elements, including common laboratory strains and strains representing seven species of Neurospora, were found to have sequences closely related to Tad but with numerous mutations of the type resulting from RIP (G:C to A:T). Even the Adiopodoume strain showed Tad-like elements with mutations characteristic of RIP. Results of crossing of an Adiopodoume transformant with progeny of Adiopodoume suggest that the Adiopodoume strain is proficient at RIP. We conclude that Tad is an old transposable element that has been inactivated by RIP in most strains. Finding relics of RIP in both heterothallic and homothallic species of Neurospora implicates RIP across the genus.     

Homology-dependent inactivation of LTR retrotransposons in genomes of Aspergillus fumigatus and A. nidulans

Repeat-induced point mutation (RIP) is the most intriguing among the known mechanisms of repeated sequences inactivation because of its ability to produce irreversible mutation of repeated DNA. Discovered for the first time in Neurospora crassa, RIP is characterized by C:G to T:A transitions in duplicated sequences. The mechanisms and distribution of RIP are still purely investigated. Mobile elements are a common target for the processes which lead to homology-dependent silencing because of their ability to propagate themselves. We have done comparative analysis of LTR retrotransposons in genomic scale from genomes of two aspergilli fungi--Aspergillus funmigatus and A. nidulans, based on several copies we reconstructed "de-RIP" retroelements. Investigations of frequencies of CpG, CpA and TpG sites, which are potential targets for mutagenesis, showed the much lower frequencies of these sites in mobile elements in comparison with structural genes. LTR retrotransposons from A. fumigatus and A. nidulans have different ratio of types of substitutions. Our analysis indicates that two investigated fungi have or had the RIP-like processes for repeated sequences inactivation, in various modes. Whereas in A. fumigatus the context for mutagenesis consists of both CpG and CpA sites, in A. nidulans inactivation seems to proceed only on CpG dinucleotides. The present investigation gives a theoretical background for planning of experimental studying of RIP inactivation in aspergilli.     

Repeat-induced point (RIP) mutation in the industrial workhorse fungus Trichoderma reesei

Trichoderma reesei (syn. Hypocrea jecorina) is a filamentous ascomycete. Due to its capability of producing large amounts of lignocellulolytic enzymes and various heterologous proteins, this fungus has been widely used for industrial applications for over 70 years. It is also a model organism for lignocellulosic biomass degradation and metabolic engineering. Recently, we experimentally and computationally demonstrated that Trichoderma reesei exhibits high homology pairing and repeat-induced point (RIP) mutation activities at a premeiotic stage, i.e., between fertilization and karyogamy or premeiotic DNA replication. The discovery of RIP in Trichoderma reesei not only reveals significant impacts of sexual reproduction on evolution and chromosome architecture but also provides intriguing perspectives for industrial strain improvement. This review emphasizes two major points about RIP and RIP-like processes in Pezizomycotina fungi. First, the molecular mechanisms of RIP and RIP-like processes in Trichoderma reesei and other Pezizomycotina fungi are apparently distinct from those originally described in the model fungus Neurospora crassa. Second, orthologs of the rid1 (deficient in RIP-1) DNA methyltransferase gene were shown to be essential for sexual development in at least four Pezizomycotina fungi, including Trichoderma reesei. In contrast, rid1 is dispensable for Neurospora crassa sexual development. We suggest that the rid1-like gene products and/or their DNA methyltransferase activities play critical roles in promoting fungal sexual development. The Neurospora crassa rid1 gene might have lost this evolutionarily conserved function.

     

Development of simple sequence repeat markers for Japanese isolates of Magnaporthe grisea

We developed nine simple sequence repeat (SSR) markers useful for differentiating Japanese isolates of Magnaporthe grisea through a bioinformatic approach. Repeat sequences in the genome of M. grisea were identified by a Tandem Repeat Finding program. Length polymorphisms at 28 loci were examined, nine of which were selected on the basis of detected polymorphisms. These nine SSR markers showed a Nei's gene diversity ranging from 0.23 to 0.91 among 48 field isolates of two natural populations. These SSR markers are well suited for M. grisea epidemiology and population genetics.     

In vivo levels of S-adenosylmethionine modulate C:G to T:A mutations associated with repeat-induced point mutation in Neurospora crassa

In Neurospora crassa, the mutagenic process termed repeat-induced point mutation (RIP) inactivates duplicated DNA sequences during the sexual cycle by the introduction of C:G to T:A transition mutations. In this work, we have used a collection of N. crassa strains exhibiting a wide range of cellular levels of S-adenosylmethionine (AdoMet), the universal donor of methyl groups, to explore whether frequencies of RIP are dependent on the cellular levels of this metabolite. Mutant strains met-7 and eth-1 carry mutations in genes of the AdoMet pathway and have low levels of AdoMet. Wild type strains with high levels of AdoMet were constructed by introducing a chimeric transgene of the AdoMet synthetase (AdoMet-S) gene fused to the constitutive promoter trpC from Aspergillus nidulans. Crosses of these strains against tester duplications of the pan-2 and am genes showed that frequencies of RIP, as well as the total number of C:G to T:A transition mutations found in randomly selected am(RIP) alleles, are inversely correlated to the cellular level of AdoMet. These results indicate that AdoMet modulates the biochemical pathway leading to RIP.     

The evolution of transposon repeat-induced point mutation in the genome of Colletotrichum cereale: reconciling sex, recombination and homoplasy in an 'asexual" pathogen

Mobile transposable elements are among the primary drivers of the evolution of eukaryotic genomes. For fungi, repeat-induced point mutation (RIP) silencing minimizes deleterious effects of transposons by mutating multicopy DNA during meiosis. In this study we identify five transposon species from the mitosporic fungus Colletotrichum cereale and report the signature pattern of RIP acting in a lineage-specific manner on 21 of 35 unique transposon copies, providing the first evidence for sexual recombination for this species. Sequence analysis of genomic populations of the retrotransposon Ccret2 showed repeated rounds of RIP mutation acting on different copies of the element. In the RIPped Ccret2 population, there were multiple inferences of incongruence primarily attributed to RIP-induced homoplasy. This study supports the view that the sequence variability of transposon populations in filamentous fungi reflects the activities of evolutionary processes that fall outside of typical phylogenetic or population genetic reconstructions.     

The evolution of transposon repeat-induced point mutation in the genome of Colletotrichum cereale: reconciling sex, recombination and homoplasy in an 'asexual" pathogen.

Mobile transposable elements are among the primary drivers of the evolution of eukaryotic genomes. For fungi, repeat-induced point mutation (RIP) silencing minimizes deleterious effects of transposons by mutating multicopy DNA during meiosis. In this study we identify five transposon species from the mitosporic fungus Colletotrichum cereale and report the signature pattern of RIP acting in a lineage-specific manner on 21 of 35 unique transposon copies, providing the first evidence for sexual recombination for this species. Sequence analysis of genomic populations of the retrotransposon Ccret2 showed repeated rounds of RIP mutation acting on different copies of the element. In the RIPped Ccret2 population, there were multiple inferences of incongruence primarily attributed to RIP-induced homoplasy. This study supports the view that the sequence variability of transposon populations in filamentous fungi reflects the activities of evolutionary processes that fall outside of typical phylogenetic or population genetic reconstructions.     

Detection of Magnaporthe grisea in infested rice seeds using polymerase chain reaction

AIM: To develop a diagnostic assay based on polymerase chain reaction for the detection of Magnaporthe grisea from infested rice seeds. METHODS AND RESULTS: Primers were designed based on the nucleotide sequence of the mif 23, an infection-specific gene of M. grisea. The primers amplified target DNA from genetically and geographically diverse isolates of the pathogen. The lowest concentration of template DNA that led to amplification was 20 rhog. No PCR product was detected when DNA from other fungi was used, indicating the specificity of the primers. With this PCR based seed assay, M. grisea was detected in rice seedlots with infestation rates as low as 0.2%. CONCLUSION: The PCR detection of M. grisea is simple, rapid, specific, sensitive and suitable for the routine detection of the pathogen in infested seeds. SIGNIFICANCE AND IMPACT OF THE STUDY: Introduction of the blast fungus into new areas where it has not been previously recorded could be avoided by the detection of infested seedlots. A PCR-based seed assay could facilitate risk assessment of naturally infested rice seeds; help design management programs and optimize fungicide use.     

DNA methylation associated with repeat-induced point mutation in Neurospora crassa.

Repeat-induced point mutation (RIP) is a process that efficiently detects DNA duplications prior to meiosis in Neurospora crassa and peppers them with G:C to A:T mutations. Cytosine methylation is typically associated with sequences affected by RIP, and methylated cytosines are not limited to CpG dinucleotides. We generated and characterized a collection of methylated and unmethylated amRIP alleles to investigate the connection(s) between DNA methylation and mutations by RIP. Alleles of am harboring 84 to 158 mutations in the 2.6-kb region that was duplicated were heavily methylated and triggered de novo methylation when reintroduced into vegetative N. crassa cells. Alleles containing 45 and 56 mutations were methylated in the strains originally isolated but did not become methylated when reintroduced into vegetative cells. This provides the first evidence for de novo methylation in the sexual cycle and for a maintenance methylation system in Neurospora cells. No methylation was detected in am alleles containing 8 and 21 mutations. All mutations in the eight primary alleles studied were either G to A or C to T, with respect to the coding strand of the am gene, suggesting that RIP results in only one type of mutation. We consider possibilities for how DNA methylation is triggered by some sequences altered by RIP.     

RIPCAL: a tool for alignment-based analysis of repeat-induced point mutations in fungal genomic sequences

Background  

Repeat-induced point mutation (RIP) is a fungal-specific genome defence mechanism that alters the sequences of repetitive DNA, thereby inactivating coding genes. Repeated DNA sequences align between mating and meiosis and both sequences undergo C:G to T:A transitions. In most fungi these transitions preferentially affect CpA di-nucleotides thus altering the frequency of certain di-nucleotides in the affected sequences. The majority of previously published in silico analyses were limited to the comparison of ratios of pre- and post-RIP di-nucleotides in putatively RIP-affected sequences – so-called RIP indices. The analysis of RIP is significantly more informative when comparing sequence alignments of repeated sequences. There is, however, a dearth of bioinformatics tools available to the fungal research community for alignment-based RIP analysis of repeat families.     

Retrotransposon-microsatellite amplified polymorphism (REMAP) markers for genetic diversity assessment of the rice blast pathogen (Magnaporthe grisea).

This present study is the first report of the application of the retrotransposon-microsatellite amplified polymorphism (REMAP) technique in fungi. Genome fingerprinting has a major role in the characterization of population structure and in the analysis of the variability in fungi. Retrotransposon-microsatellite amplified polymorphism assay was used in virulent isolates of a rice blast pathogen (Magnaporthe grisea) as a new assay system for genetic variability studies that overcomes the limitations of previous techniques. The high polymorphism observed in REMAP could be due to past or recent actions of retrotransposon in M. grisea. Retrotransposon-microsatellite amplified polymorphism, with its superior marker utility, was concluded to be the marker of choice for characterizing M. grisea isolates.     

Analysis of the structure of the AVR1-CO39 avirulence locus in virulent rice-infecting isolates of Magnaporthe grisea

The AVR1-CO39 gene that came from a Magnaporthe grisea isolate from weeping lovegrass controls avirulence on the rice cultivar CO39. AVR1-CO39 was not present in the genome of the rice-infecting M. grisea isolate Guyll from French Guyana, suggesting that the gene had been deleted. Molecular analysis of the deletion breakpoints in the AVR1-CO39 locus revealed the presence of a truncated copy of a previously unknown retrotransposon at the left-hand border. At the right-hand border was a truncated copy of another repetitive element that is present at multiple locations in the genome of Guyll. The structures of avr1-CO39 loci were further examined in 45 rice-infecting isolates collected in Brazil, China, Japan, India, Indonesia, Mali, and the Philippines. Most isolates showed no hybridization signal with the AVR1-CO39 probe and had the same locus structure as Guyll. Some isolates from Japan showed a signal with the AVR1-CO39 probe, but the region specifying avirulence activity was rearranged. These findings suggest that widespread virulence to 'CO39' among rice-infecting M. grisea isolates is due to ancestral rearrangements at the AVR1-CO39 locus that may have occurred early in the evolution of pathogenicity to rice.