Repeat-induced point mutation (RIP) in crosses with wild-isolated strains of Neurospora crassa: evidence for dominant reduction of RIP

Seventy-one wild-isolated strains of Neurospora crassa were examined for their ability to support repeat-induced point mutation (RIP) in the erg-3 locus. RIP was exceptionally inefficient but detectable in crosses with the strain FGSC 430 from Adiopodoume, Ivory Coast. We could find no consistent differences in ascospore yields when wild isolates identified as "low-RIP" or "high-RIP" strains were crossed with strains bearing the segmental duplication Dp(IIIR > [I; II])AR17. This suggested that RIP may not be responsible for the barren phenotype of crosses involving segmental duplication strains.     

Chromosome segment duplications in Neurospora crassa and their effects on repeat-induced point mutation and meiotic silencing by unpaired DNA

The size and extent of four Neurospora crassa duplications, Dp(AR17), Dp(IBj5), Dp(OY329), and Dp(B362i), was determined by testing the coverage of RFLP markers. The first three duplications were all > approximately 350 kb and have been shown in earlier studies to act as dominant suppressors of repeat-induced point mutation (RIP) in gene-sized duplications, possibly via titration of the RIP machinery. Dp(B362i), which is only approximately 117 kb long, failed to suppress RIP. RIP suppression in gene-sized duplications by large duplications was demonstrated using another test gene, dow, and supposedly applies generally. Crosses homozygous for Dp(AR17) or Dp(IBj5) were as barren as heterozygous crosses. Barrenness of the heterozygous but not the homozygous crosses was suppressible by Sad-1, a semidominant suppressor of RNAi-dependent meiotic silencing by unpaired DNA. A model is proposed in which large duplications recessively suppress semidominant Sad-1 mutations. The wild-isolated Sugartown strain is hypothesized to contain a duplication that confers not only dominant suppression of RIP but also a barren phenotype, which is linked (9%) to supercontig 7.118 in LG VII.     

A factor in a wild isolated <Emphasis Type="BoldItalic">Neurospora crassa</Emphasis> strain enables a chromosome segment duplication to suppress repeat-induced point mutation

Repeat-induced point mutation (RIP) is a sexual stage-specific mutational process of Neurospora crassa and other fungi that alters duplicated DNA sequences. Previous studies from our laboratory showed that chromosome segment duplications (Dps) longer than ~300 kbp can dominantly suppress RIP, presumably by titration of the RIP machinery, and that although Dps <200 kbp did not individually suppress RIP, they could do so in homozygous and multiply heterozygous crosses, provided the sum of the duplicated DNA exceeds ~300 kbp. Here we demonstrate suppression of RIP in a subset of progeny carrying the normally sub-threshold 154 kbp Dp(R2394) from a cross of T(R2394) to the wild isolated Carrefour Mme. Gras strain (CMG). Thus, the CMG strain contains a factor that together with Dp(R2394) produces a synthetic RIP suppressor phenotype. It is possible that the factor is a cryptic Dp that together with Dp(R2394) can exceed the size threshold for titration of the RIP machinery and thereby causes RIP suppression.     

Specificity of Repeat-Induced Point Mutation (Rip) in Neurospora: Sensitivity of Non-Neurospora Sequences, a Natural Diverged Tandem Duplication, and Unique DNA Adjacent to a Duplicated Region

The process designated RIP (repeat-induced point mutation) alters duplicated DNA sequences in the sexual cycle of Neurospora crassa. We tested whether non-Neurospora sequences are susceptible to RIP, explored the basis for the observed immunity to this process of a diverged tandem duplication that probably arose by a natural duplication followed by RIP (the Neurospora zeta-eta region), and investigated whether RIP extends at all into unique sequences bordering a duplicated region. Bacterial sequences of the plasmid pUC8 and of a gene conferring resistance to hygromycin B were sensitive to RIP in N. crassa when repeated in the genome. When the entire 1.6-kb zeta-eta region was duplicated, it was susceptible to RIP, but was affected by it to a lesser extent than other duplications. Only three of 62 progeny from crosses harboring unlinked duplications of the region showed evidence of changes. We attribute the low level of alterations to depletion of mutable sites. The stability of the zeta-eta region in strains having single copies of the region suggests that the 14% divergence of the tandem elements is sufficient to prevent RIP. DNA sequence analysis of unduplicated pUC8 sequences adjacent to a duplication revealed that RIP continued at least 180 bp beyond the boundary of the duplication. Three mutations occurred in the 200-bp segment of bordering sequences examined.     

Genetic analysis of wild-isolated Neurospora crassa strains identified as dominant suppressors of repeat-induced point mutation

Repeat-induced point mutation (RIP) in Neurospora results in inactivation of duplicated DNA sequences. RIP is thought to provide protection against foreign elements such as retrotransposons, only one of which has been found in N. crassa. To examine the role of RIP in nature, we have examined seven N. crassa strains, identified among 446 wild isolates scored for dominant suppression of RIP. The test system involved a small duplication that targets RIP to the easily scorable gene erg-3. We previously showed that RIP in a small duplication is suppressed if another, larger duplication is present in the cross, as expected if the large duplication competes for the RIP machinery. In two of the strains, RIP suppression was associated with a barren phenotype--a characteristic of Neurospora duplications that is thought to result in part from a gene-silencing process called meiotic silencing by unpaired DNA (MSUD). A suppressor of MSUD (Sad-1) was shown not to prevent known large duplications from impairing RIP. Single-gene duplications also can be barren but are too short to suppress RIP. RIP suppression in strains that were not barren showed inheritance that was either simple Mendelian or complex. Adding copies of the LINE-like retrotransposon Tad did not affect RIP efficiency.     

Euploid derivatives of duplications from a translocation in neurospora

Nontandem terminal chromosome duplications derived from N. crassa translocation T(I-->VI)NM103 give rise mitotically to some daughter nuclei which have become euploid by loss of one or the other of the two duplicated segments. Loss of the segment in normal sequence occurs as often as loss of the translocated segment. This is in contrast to all of several other Neurospora duplications that have been studied, where loss of the segment in normal sequence is absent or rare.--T(NM103) has the distal two thirds of linkage group IR exchanged with the right tip of VI. Crosses to normal sequence produce a class of morphologically distinct progeny with IR chromosome duplications. For a few days after germination, test crosses of these progeny are barren (make perithecia but few or no spores, as observed commonly with Neurospora duplications). Growing duplication cultures become fertile by accumulating nuclei which have been reduced to either normal sequence (by loss of the segment in translocation sequence) or translocation sequence (by loss of the segment in normal sequence). Both types usually appear within the first week of growth. Naturally formed mixtures or heterokaryons of NM103 duplication nuclei and their reduced euploid products have been studied by plating and by progeny testing. Determination of nuclear type is based on culture morphology, expression of genetic markers, and crossing behavior. Within the limits of testing, loss is found to begin precisely at the interchange points. The unique finding of frequent breakdown of normal-sequence linkage group I chromosomes is not dependent on the strain from which the chromosome was derived. Many different strains were tested, and for each one evidence was found that nuclei reduced to translocation sequence had been produced from duplication nuclei by loss of the segment in normal sequence.     

Titration of repeat-induced point mutation (RIP) by chromosome segment duplications in <Emphasis Type="Italic">Neurospora crassa</Emphasis>

Repeat-induced point mutation (RIP) is a hypermutational process that alters duplicated DNA sequences in Neurospora crassa. In previous studies, five of six large (>100 kb) chromosome segment duplications (Dp’s) examined were shown to dominantly suppress RIP in smaller (<5 kb) duplications. The suppressor duplications were >270 kb, whereas the lone non-suppressor duplication was ∼117 kb. We have now screened another 33 duplications and found 29 more suppressors and four more non-suppressors. All 22 suppressor duplications whose size could be estimated were >270 kb, whereas two newly identified non-suppressor duplications examined were 140–154 kb. RIP was suppressed in a subset of crosses heterozygous for more than one ordinarily non-suppressor duplication. These results strengthen the hypothesis that large duplications titrate out the RIP machinery and suggest the “equivalence point” for the titration is close to 300 kb. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. This article is dedicated to the memory of Robert L. Metzenberg.     

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 ~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.     

Determining the order of genes,centromeres, and rearrangement breakpoints inNeurospora by tests of duplication coverage

Nontandem segmental duplications provide a useful alternative to conventional recombination mapping for determining gene order in a haploid organism such asNeurospora. When an insertional or terminal rearrangement is crossed by Normal sequence, a class of progeny is produced that have a precisely delimited chromosome segment duplicated. In such Duplication progeny, a recessive gene in the Normal-sequence donor chromosome may or may not be masked (“covered”) by its dominant wild-type allele in the translocation-sequence recipient chromosome. Coverage depends upon whether the gene in question is left or right of the rearrangement breakpoint. The recessive gene will be heterozygous and covered (not expressed) if its locus is within the duplicated segment, but it will be haploid and expressed if the locus is outside the segment. Not only genes but also centromeres can be mapped by means of duplications, because genes included in. the same viable duplication must reside in the same chromosome arm. - Numerous sequences in the current genetic maps ofN. crassa have been determined using duplications. Gene order in the albino region and in the centromere region of linkage group I provide examples. Over 50 insertional or terminal rearrangements are available from which nontandem duplications of defined content can be obtained at will; collectively these cover about 75% of the genome. - Intercrosses between partially overlapping chromosome rearrangements also produce Duplication progeny containing two copies of regions between the breakpoints. The 180 mapped reciprocal translocations and inversions include numerous overlapping combinations that can be used for duplication mapping.     

Heterokaryon Incompatibility Genes in NEUROSPORA CRASSA Detected Using Duplication-Producing Chromosome Rearrangements

Evidence is presented for five or six previously undetected heterokaryon incompatibility (het) loci, bringing to about ten the number of such genes known in Neurospora crassa. The genes were detected using chromosome duplications (partial diploids), on the basis of properties previously known for het genes in duplications. Duplications homozygous for het genes are usually normal in growth and morphology, whereas those heterozygous are strikingly different. The heterozygotes are inhibited in their initial growth, produce brown pigment on appropriate medium, and later "escape" from their inhibition, as a result of somatic events, to produce wild-type growth. - Five normal-sequence strains were crossed to 14 duplication-producing chromosome rearrangements, and the duplication progeny were examined for properties characteristic of duplications heterozygous for known het genes. Each cross produced duplications for a specific region of the genome, depending on the rearrangement. Normal-sequence strains were wild types from nature, chosen from diverse geographic locations to serve as sources of genetic variation. - The duplication method was very effective. Most of the longer duplications uncovered het genes. The genes are: het-5 (on linkage group IR, in the region covered by duplications produced using rearrangement T (IR LEADS TO VIR)NM103), het-6 (on IIL, covered by T(IIL LEADS TO VI)P2869 and T(IIL LEADS TO IIIR)AR18 duplications), het-7 (tentatively assigned to IIIR, T(IIIR LEADS TO VIL)D305), het-8 (VIL, T(VIL LEADS TO IR)T39M777), het-9 (VIR LEADS TO IVR)AR209), and het-10 (VIIR, T(VIIR LEADS TO IL)5936.     

Cytogenetics of an intrachromosomal transposition in Neurospora

Knowledge of intrachromosomal transpositions has until now been primarily cytological and has been limited to Drosophila and to humans, in both of which segmental shifts can be recognized by altered banding patterns. There has been little genetic information. In this study, we describe the genetic and cytogenetic properties of a transposition in Neurospora crassa. In Tp(IRIL)T54M94, a 20 map unit segment of linkage group I has been excised from its normal position and inserted near the centromere in the opposite arm, in inverted order. In crosses heterozygous for the transposition, about one-fifth of surviving progeny are duplications carrying the transposed segment in both positions. These result from crossing over in the interstitial region. There is no corresponding class of progeny duplicated for the interstitial segment. The duplication strains are barren in test crosses. A complementary deficiency class is represented by unpigmented, inviable ascospores. Extent of the duplication was determined by duplication-coverage tests. Orientation of the transposed segment was determined using Tp x Tp crosses heterozygous for markers inside and outside the transposed segment, and position of the insertion relative to the centromere was established using quasi-ordered half-tetrads from crosses x Spore killer. Quelling was observed in the primary transformants that were used to introduce a critical marker into the transposed segment by repeat-induced point mutation (RIP).     

The Instability of Neurospora Duplication Dp(IL-->IR)H4250 , and Its Genetic Control

Previous work (Newmeyer and Taylor 1967) showed that a nontandem duplication, Dp(IL-->IR)H4250, is regularly produced by recombination in crosses heterozygous for the effectively terminal pericentric inversion In(IL-->IR)H4250. The duplications initially have strongly inhibited growth because they are heterozygous for mating type, which behaves like a vegetative-incompatibility (het) locus. Such cultures "escape" from the inhibition as a result of events that eliminate the mating-type heterozygosity. The product of a given escape event may be barren or fertile. (Neurospora duplications are characteristically barren; that is, when crossed, they make many perithecia but few ascospores.)-The present paper reports on a genetic analysis of the instability of Dp(IL-->IR)H4250 . Most of the barren escape products behave as if due either to mitotic crossovers, which make mating type and distal markers homozygous, or to very long deletions which uncover mating type and all distal markers; presumably the latter would retain enough duplicated material to render them barren. It is difficult to distinguish between these two possibilities, but homozygosis seems more probable and has been clearly demonstrated in one case. Only a few barren escapes could be due to short deletions or to changes at the mating-type locus.-The fertile escape products appear to be euploid. Most of these behave as if they arose by precise deletion of one or the other duplicated segment, thus restoring one of the parental sequences. A large majority of the precise deletions restore normal sequence; only a few restore inversion sequence. Preferential restoration of the normal sequence has also been found by other workers for Neurospora duplications from several other rearrangements. A hypothesis is presented to explain these findings; it is posulated that the precise deletions result from mitotic crossing over in homologous material located at chromosome tips and tip-break-points.-There is a smaller group of fertile escapes that are unlike either parental sequence; at least one of these involves a chromosome break outside the duplicated region.-Duplications in which the vegetative incompatibility is suppressed by the unlinked modifier tol are extremely barren; they only rarely lose a duplicated segment so as to become fertile.-The instability of Dp(IL-->IR)H4250 , with and without tol, is markedly altered by factors in the genetic background. The two factors studied in detail have qualitatively different effects.     

High Frequency Repeat-Induced Point Mutation (Rip) Is Not Associated with Efficient Recombination in Neurospora

Duplicated DNA sequences in Neurospora crassa are efficiently detected and mutated during the sexual cycle by a process named repeat-induced point mutation (RIP). Linked, direct duplications have previously been shown to undergo both RIP and deletion at high frequency during premeiosis, suggesting a relationship between RIP and homologous recombination. We have investigated the relationship between RIP and recombination for an unlinked duplication and for both inverted and direct, linked duplications. RIP occurred at high frequency (42-100%) with all three types of duplications used in this study, yet recombination was infrequent. For both inverted and direct, linked duplications, recombination was observed, but at frequencies one to two orders of magnitude lower than RIP. For the unlinked duplication, no recombinants were seen in 900 progeny, indicating, at most, a recombination frequency nearly three orders of magnitude lower than the frequency of RIP. In a direct duplication, RIP and recombination were correlated, suggesting that these two processes are mechanistically associated or that one process provokes the other. Mutations due to RIP have previously been shown to occur outside the boundary of a linked, direct duplication, indicating that RIP might be able to inactivate genes located in single-copy sequences adjacent to a duplicated sequence. In this study, a single-copy gene located between elements of linked duplications was inactivated at moderate frequencies (12-14%). Sequence analysis demonstrated that RIP mutations had spread into these single-copy sequences at least 930 base pairs from the boundary of the duplication, and Southern analysis indicated that mutations had occurred at least 4 kilobases from the duplication boundary.     

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.     

Action of repeat-induced point mutation on both strands of a duplex and on tandem duplications of various sizes in Neurospora.

In Neurospora crassa, DNA sequence duplications are detected and altered efficiently during the sexual cycle by a process known as RIP (repeat-induced point mutation). Affected sequences are subjected to multiple GC-to-AT mutations. To explore the pattern in which base changes are laid down by RIP we examined two sets of strains. First, we examined the products of a presumptive spontaneous RIP event at the mtr locus. Results of sequencing suggested that a single RIP event produces two distinct patterns of change, descended from the two strands of an affected DNA duplex. Equivalent results were obtained using an exceptional tetrad from a cross with a known duplication flanking the zeta-eta (zeta-eta) locus. The mtr sequence data were also used to further examine the basis for the differential severity of C-to-T mutations on the coding and noncoding strands in genes. The known bias of RIP toward CpA/TpG sites in conjunction with the sequence bias of Neurospora accounts for the differential effect. Finally, we used a collection of tandem repeats (from 16 to 935 bp in length) within the mtr gene to examine the length requirement for RIP. No evidence of RIP was found with duplications shorter than 400 bp while all longer tandem duplications were frequently affected. A comparison of these results with vegetative reversion data for the same duplications is consistent with the idea that reversion of long tandem duplications and RIP share a common step.     

Mutation of msh-2 in Neurospora crassa does not reduce the incidence of recombinants with multiple patches of donor chromosome sequence

The Neurospora homologue msh-2 of the Escherichia coli mismatch repair gene mutS was mutated by repeat-induced point mutation (RIP) of a 1.9-kb duplication covering 1661bp of the coding sequence and 302 bp 5' of the gene. msh-2(RIP-LK1) exhibited a mutator phenotype conferring a 17-fold increase in the frequency of spontaneous mitotic reversion of his-3 allele K458. In msh-2(RIP-LK1) homozygotes, recombination frequency at the his-3 locus increased up to 2.9-fold over that in msh-2(+) diploids. Progeny of crosses homozygous msh-2(RIP-LK1), like those from crosses homozygous msh-2(+) frequently had multiple patches of donor chromosome sequence, suggesting that patchiness in msh-2(+) crosses is not explained by incomplete repair of heteroduplex DNA by MSH-2. These findings are consistent with data from the analysis of events in a Neurospora translocation heterozygote that suggested multiple patches of donor chromosome sequence arising during recombination reflect multiple template switches during DNA repair synthesis.     

基因倍增研究进展

基因倍增是指DNA片段在基因组中复制出一个或更多的拷贝,这种DNA片段可以是一小段基因组序列、整条染色体,甚至是整个基因组。基因倍增是基因组进化最主要的驱动力之一,是产生具有新功能的基因和进化出新物种的主要原因之一。本文综述了脊椎动物、模式植物和酵母在进化过程中基因倍增研究领域的最新进展,并讨论了基因倍增研究的发展方向。     

Translocations used to generate chromosome segment duplications in <Emphasis Type="Italic">Neurospora</Emphasis> can disrupt genes and create novel open reading frames

In Neurospora crassa, crosses between normal sequence strains and strains bearing some translocations can yield progeny bearing a duplication (Dp) of the translocated chromosome segment. Here, 30 breakpoint junction sequences of 12 Dp-generating translocations were determined. The breakpoints disrupted 13 genes (including predicted genes), and created 10 novel open reading frames. Insertion of sequences from LG III into LG I as translocation T(UK8-18) disrupts the eat-3 gene, which is the ortholog of the Podospora anserine gene ami1. Since ami1-homozygous Podospora crosses were reported to increase the frequency of repeat-induced point mutation (RIP), we performed crosses homozygous for a deficiency in eat-3 to test for a corresponding increase in RIP frequency. However, our results suggested that, unlike in Podospora, the eat-3 gene might be essential for ascus development in Neurospora. Duplication-heterozygous crosses are generally barren in Neurospora; however, by using molecular probes developed in this study, we could identify Dp segregants from two different translocation-heterozygous crosses, and using these we found that the barren phenotype of at least some duplication-heterozygous crosses was incompletely penetrant.     

A Combination Inversion and Translocation in Neurospora Crassa with Inviable Deficiency Progeny That Can Be Rescued in Heterokaryons

Chromosome rearrangement In(IL;IR)T(IL;IIIR)SLm-1, has a pericentric inversion in linkage group I associated with a reciprocal translocation between I and III. The rearrangement was identified cytologically in pairing with normal sequence chromosomes at pachynema. Rearrangement breakpoints were mapped genetically in IL, IR and IIIR by crosses with normal sequence strains and in crosses with an inversion that partially overlaps the SLm-1 inversion. When rearrangement SLm-1 is crossed to parents with normal sequence chromosomes, one class among the progeny has a small chromosome deficiency and large duplication. The ascospores containing this deficiency/duplication die either before germination or just after, when growth commences. Germ tubes of the deficiency/duplication progeny, which start to grow then stop, resemble the aborted growth of auxotrophic mutants germinated on minimal medium. Efforts to correct the deficiency with nutritional supplements were not successful. However, the defective class can be rescued by fusing the germinating hyphae of the deficiency ascospore with a complementary auxotrophic mutant to form a heterokaryon. A deficiency/duplication nucleus that is rescued in a heterokaryon can serve as a fertilizing nucleus in crosses with a normal sequence parent. One half of their progeny have the normal chromosome sequence and one half have the chromosome deficiency syndrome and die at germination.     

Chromosome segment duplications in Neurospora crassa: barren crosses beget fertile science

Studies on Neurospora chromosome segment duplications (Dps) performed since the publication of Perkins's comprehensive review in 1997 form the focus of this article. We present a brief summary of Perkins's seminal work on chromosome rearrangements, specifically, the identification of insertional and quasiterminal translocations that can segregate Dp progeny when crossed with normal sequence strains (i.e., T × N). We describe the genome defense process called meiotic silencing by unpaired DNA that renders Dp‐heterozygous crosses (i.e., Dp × N) barren, which provides a basis for identifying Dps, and discuss whether other processes also might contribute to the barren phenotype of Dp × N and Dp × Dp crosses. We then turn to studies suggesting that large Dps (i.e., >300 kbp) can allow smaller gene‐sized duplications to escape another genome defense process called repeat‐induced point mutation (RIP), possibly by titration of the RIP machinery. Finally, we assess whether in natural populations dominant RIP suppressor Dps provide an “RIP‐free” niche for evolution of new genes following the duplication of existing genes.