Reduction of stability of arabidopsis genomic and transgenic DNA-repeat sequences (microsatellites) by inactivation of AtMSH2 mismatch-repair function

Highly conserved mismatch repair (MMR) systems promote genomic stability by correcting DNA replication errors, antagonizing homeologous recombination, and responding to various DNA lesions. Arabidopsis and other plants encode a suite of MMR protein orthologs, including MSH2, the constant component of various specialized eukaryotic mismatch recognition heterodimers. To study MMR roles in plant genomic stability, we used Arabidopsis AtMSH2::TDNA mutant SALK_002708 and AtMSH2 RNA-interference (RNAi) lines. AtMSH2::TDNA and RNAi lines show normal growth, development, and fertility. To analyze AtMSH2 effects on germ line DNA fidelity, we measured insertion-deletion mutation of dinucleotide-repeat sequences (microsatellite instability) at nine loci in 16 or more progeny of two to four different wild-type or AtMSH2-deficient plants. Scoring 992 total alleles revealed 23 (2.3%) unique and 51 (5.1%) total repeat length shifts ([+2], [-2], [+4], or [-4] bp). For the six longest repeat loci, the corresponding frequencies were 22/608 and 50/608. Two of four AtMSH2-RNAi plants showed similar microsatellite instability. In wild-type progeny, only one unique repeat length allele was found in 576 alleles tested. This endogenous microsatellite instability, shown for the first time in MMR-defective plants, is similar to that seen in MMR-defective yeast and mice, indicating that plants also use MMR to promote germ line fidelity. We used a frameshifted reporter transgene, (G)(7)GUS, to measure insertion-deletion reversion as blue-staining beta-glucuronidase-positive leaf spots. Reversion rates increased only 5-fold in AtMSH2::TDNA plants, considerably less than increases in MSH2-deficient yeast or mammalian cells for similar mononucleotide repeats. Thus, MMR-dependent error correction may be less stringent in differentiated leaf cells than in plant equivalents of germ line tissue.     

Cloning of the PpMSH-2 cDNA of Physcomitrella patens, a moss in which gene targeting by homologous recombination occurs at high frequency

In the moss Physcomitrella patens integrative transformants from homologous recombination are obtained at an efficiency comparable to that found for yeast. This property, unique in the plant kingdom, allows the knockout of specific genes. It also makes the moss a convenient model to study the regulation of homologous recombination in plants. We used degenerate oligonucleotides designed from AtMSH2 from Arabidopsis thaliana and other known MutS homologues to isolate the P. patens MSH2 (PpMSH2) cDNA. The deduced sequence of the PpMSH2 protein is respectively 60.8% and 59.6% identical to the maize and A. thaliana MSH2. Phylogenic studies show that PpMSH2 is closely related to the group of plant MSH2 proteins. Southern analysis reveals that the gene exists as a single copy in the P. patens genome.     

Effects of suppressing the DNA mismatch repair system on homeologous recombination in tomato

In plant breeding, the ability to manipulate genetic (meiotic) recombination would be beneficial for facilitating gene transfer from wild relatives of crop plants. The DNA mismatch repair (MMR) system helps maintain genetic integrity by correcting base mismatches that arise via DNA synthesis or damage, and antagonizes recombination between homeologous (divergent) DNA sequences. Previous studies have established that the genomes of cultivated tomato (Solanum lycopersicum) and the wild relative S. lycopersicoides are substantially diverged (homeologous) such that recombination between their chromosomes is strongly reduced. Here, we report the effects on homeologous recombination of suppressing endogenous MMR genes in S. lycopersicum via RNAi-induced silencing of SlMSH2 and SlMSH7 or overexpressing dominant negatives of Arabidopsis MSH2 (AtMSH2-DN) in an alien substitution line (SL-8) of S. lycopersicoides in tomato. We show that certain inhibitions of MMR (RNAi of SlMSH7, AtMSH2-DN) are associated with modest increases in homeologous recombination, ranging from 3.8 to 29.2% (average rate of 17.8%) compared to controls. Unexpectedly, only the AtMSH2-DN proteins but not RNAi-induced silencing of MSH2 was found to increase homeologous recombination. The ratio of single to double crossovers (SCO:DCO ratio) decreased by approximately 50% in progeny of the AtMSH2-DN parents. An increase in the frequency of heterozygous SL-8 plants was also observed in the progeny of the SlMSH7-RNAi parents. Our findings may contribute to acceleration of introgression in cultivated tomato.     

Four mismatch repair paralogues coexist in Arabidopsis thaliana : AtMSH2, AtMSH3, AtMSH6-1 and AtMSH6-2

By using degenerate oligonucleotides based on the sequence homology between known MutS homologues, three MSH cDNAs belonging to the MSH2, MSH3 and MSH6 families, as defined in eukaryotes, have been isolated from Arabidopsis thaliana (ecotype Columbia). Genomic sequences for two of these genes (AtMSH2 and AtMSH6-2) were also isolated and determined, whereas the genomic sequence of AtMSH3 was obtained through the Arabidopsis sequencing project, as was the sequence of a second, distinct AtMSH6 homologue (AtMSH6-1). Comparative analysis of the AtMSH2 Landsberg erecta genomic sequence (reported here) and the previously described AtMSH2 Columbia allele revealed several polymorphisms, including the presence of a small, transposon-like element in the 3′ untranscribed region of the former allele. Arabidopsis is the first organism to show such divergence of two AtMSH6 genes; the divergence is strongly supported by sequence data and phylogenetic analysis. Southern analysis revealed that the three genes we have isolated exist as single copies, and genetic mapping indicated that AtMSH2 and AtMSH6-2 both reside on chromosome III. Finally, expression of these three genes could only be observed in suspensions of A. thaliana cells. Such a cell suspension divides actively after subculture, and the AtMSH genes are most strongly expressed at this stage. Received: 23 February 1999 / Accepted: 5 May 1999     

Dissimilar mispair-recognition spectra of Arabidopsis DNA-mismatch-repair proteins MSH2*MSH6 (MutSalpha) and MSH2*MSH7 (MutSgamma)

Besides orthologs of other eukaryotic mismatch-repair (MMR) proteins, plants encode MSH7, a paralog of MSH6. The Arabidopsis thaliana recognition heterodimers AtMSH2·MSH6 (AtMutSα) and AtMSH2·MSH3 (AtMutSβ) were previously found to bind the same subsets of mismatches as their counterparts in other eukaryotes—respectively, base–base mismatches and single extra nucleotides, loopouts of extra nucleotides (one or more) only—but AtMSH2·MSH7 (AtMutSγ) bound well only to a G/T mismatch. To test hypotheses that MSH7 might be specialized for G/T, or for base mismatches in 5-methylcytosine contexts, we compared binding of AtMutSα and AtMutSγ to a series of mismatched DNA oligoduplexes, relative to their (roughly similar) binding to G/T DNA. AtMutSγ bound G/G, G/A, A/A and especially C/A mispairs as well or better than G/T, in contrast to MutSα, for which G/T was clearly the best base mismatch. The presence of 5-methylcytosine adjacent to or in a mispair generally lowered binding by both heterodimers, with no systematic difference between the two. Alignment of protein sequences reveals the absence in MSH7 of the clamp domains that in bacterial MutS proteins—and by inference MSH6 proteins—non-specifically bind the backbone of mismatched DNA, raising new questions as to how clamp domains enhance mismatch recogni tion. Plants must rigorously suppress mutation during mitotic division of meristematic cells that eventually give rise to gametes and may also use MMR proteins to antagonize homeologous recombination. The MSH6 versus MSH7 divergence may reflect specializations for particular mismatches and/or sequence contexts, so as to increase both DNA-replication and meiotic-recombination fidelity, or dedication of MSH6 to the former and MSH7 to the latter, consistent with genetic evidence from wheat.     

Cloning of the PpMSH-2 cDNA of Physcomitrella patens, a moss in which gene targeting by homologous recombination occurs at high frequency

In the moss Physcomitrella patens integrative transformants from homologous recombination are obtained at an efficiency comparable to that found for yeast. This property, unique in the plant kingdom, allows the knockout of specific genes. It also makes the moss a convenient model to study the regulation of homologous recombination in plants. We used degenerate oligonucleotides designed from AtMSH2 from Arabidopsis thaliana and other known MutS homologues to isolate the P. patens MSH2 (PpMSH2) cDNA. The deduced sequence of the PpMSH2 protein is respectively 60.8% and 59.6% identical to the maize and A. thaliana MSH2. Phylogenic studies show that PpMSH2 is closely related to the group of plant MSH2 proteins. Southern analysis reveals that the gene exists as a single copy in the P. patens genome.     

Four mismatch repair paralogues coexist in Arabidopsis thaliana: AtMSH2, AtMSH3, AtMSH6-1 and AtMSH6-2

By using degenerate oligonucleotides based on the sequence homology between known MutS homologues, three MSH cDNAs belonging to the MSH2, MSH3 and MSH6 families, as defined in eukaryotes, have been isolated from Arabidopsis thaliana (ecotype Columbia). Genomic sequences for two of these genes (AtMSH2 and AtMSH6-2) were also isolated and determined, whereas the genomic sequence of AtMSH3 was obtained through the Arabidopsis sequencing project, as was the sequence of a second, distinct AtMSH6 homologue (AtMSH6-1). Comparative analysis of the AtMSH2 Landsberg erecta genomic sequence (reported here) and the previously described AtMSH2 Columbia allele revealed several polymorphisms, including the presence of a small, transposon-like element in the 3′ untranscribed region of the former allele. Arabidopsis is the first organism to show such divergence of two AtMSH6 genes; the divergence is strongly supported by sequence data and phylogenetic analysis. Southern analysis revealed that the three genes we have isolated exist as single copies, and genetic mapping indicated that AtMSH2 and AtMSH6-2 both reside on chromosome III. Finally, expression of these three genes could only be observed in suspensions of A. thaliana cells. Such a cell suspension divides actively after subculture, and the AtMSH genes are most strongly expressed at this stage.     

Functional analysis of the Arabidopsis thaliana mismatch repair gene MSH2.

The Arabidopsis thaliana MSH2 (AtMSH2) gene encodes a protein that belongs to a family of highly conserved proteins (MutS homologues (MSH)) involved in DNA mismatch repair. Sequence analysis strongly suggests that this single copy gene is indeed a homologue of MSH2, a gene known to play a central role in eukaryotic mismatch repair. In this report, we show that the AtMSH2 protein has functional attributes characteristic of previously described mismatch repair proteins. First, over-expression of this protein in Escherichia coli leads to a mutator phenotype similar to that reported previously for known functional homologues. Second, gel retardation assays revealed that the AtMSH2 protein has a 10-fold greater affinity for DNA containing a single pair of mismatched nucleotides versus perfectly matched DNA. These results provide experimental evidence that AtMSH2 is indeed a functional homologue of MutS.     

Analysis of transitive RNA silencing after grafting in transgenic plants with the coat protein gene of <Emphasis Type="Italic">Sweet potato feathery mottle virus</Emphasis>

We have previously reported the graft transmission of target specificity for RNA silencing using transgenic Nicotiana benthamiana plants expressing the coat protein gene (CP, including the 3′ non-translated region) of Sweet potato feathery mottle virus. Transgenic plants carrying the 5′ 200 and 400 bp regions of CP were newly produced. From these plants, two silenced and two non-silenced lines were selected to investigate the manifestation of transitive RNA silencing by graft experiments. Non-silenced scions carrying the entire transgene were grafted onto either 5′ or 3′ silencing inducer rootstocks. When non-silenced scions were grafted onto 5′ silencing inducer rootstocks, RNA silencing was induced in the non-silenced scions and spread toward the 3′ region of the transgene mRNA. Similarly, when non-silenced scions were grafted onto 3′ silencing inducer rootstocks, RNA silencing was induced in the non-silenced scions, but was restricted to the 3′ region of the transgene and did not spread to the 5′ region. In addition, results from crossing experiments, involving non-silenced and 3′ silencing inducer plants, confirmed the above finding. This indicates that RNA silencing spreads in the 5′–3′ direction, not in the 3′–5′ direction, along the transgene mRNA.     

Molecular analysis of <Emphasis Type="Italic">Agrobacterium</Emphasis> T-DNA integration in tomato reveals a role for left border sequence homology in most integration events

Studies in several plants have shown that Agrobacterium tumefaciens T-DNA can integrate into plant chromosomal DNA by different mechanisms involving single-stranded (ss) or double-stranded (ds) forms. One mechanism requires sequence homology between plant target and ssT-DNA border sequences and another double-strand-break repair in which preexisting chromosomal DSBs “capture” dsT-DNAs. To learn more about T-DNA integration in Solanum lycopersicum we characterised 98 T-DNA/plant DNA junction sequences and show that T-DNA left border (LB) and right border transfer is much more variable than previously reported in Arabidopsis thaliana and Populus tremula. The analysis of seven plant target sequences showed that regions of homology between the T-DNA LB and plant chromosomal DNA plays an important role in T-DNA integration. One T-DNA insertion generated a target sequence duplication that resulted from nucleolytic processing of a LB/plant DNA heteroduplex that generated a DSB in plant chromosomal DNA. One broken end contained a captured T-DNA that served as a template for DNA repair synthesis. We propose that most T-DNA integrations in tomato require sequence homology between the ssT-DNA LB and plant target DNA which results in the generation of DSBs in plant chromosomal DNA.     

Characterization of an Extracellular Serine Protease Gene from the Nematophagous Fungus <Emphasis Type="Italic">Lecanicillium psalliotae</Emphasis>

The gene encoding a cuticle-degrading serine protease was cloned from three isolates of Lecanicillium psalliotae (syn. Verticillium psalliotae) by 3′ and 5′ RACE (rapid amplification of cDNA ends) method. The gene encodes for 382 amino acids and the protein shares conserved motifs with subtilisin N and peptidase S8. Comparison of translated cDNA sequences of three isolates revealed one amino acid polymorphism at position 230. The deduced protease sequence shared high degree of similarities to other cuticle-degrading proteases from other nematophagous fungi.     

<Emphasis Type="Italic">HLA-A</Emphasis> allele associations with viral <Emphasis Type="Italic">MER9-LTR</Emphasis> nucleotide sequences at two distinct loci within the <Emphasis Type="Italic">MHC alpha</Emphasis> block

The study of the association of the Human Leukocyte Antigen (HLA) alleles and polymorphic retrotransposons such as Alu, HERV, and LTR at various loci within the Major Histocompatibility Complex allows for a better identification and stratification of disease associations and the origins of HLA haplotypes in different populations. This paper provides sequence and association data on two structurally polymorphic MER9-LTR retrotransposons that are located 54 kb apart and in close proximity to the multiallelic HLA-A gene involved in the regulation of the human immune system. Direct DNA sequencing and analysis of the PCR products identified DNA nucleotide variations between the MER9-LTR sequences at the two loci and their associations with HLA-A alleles as potential haplotype and evolutionary markers. All MER9-LTR sequences were haplotypic when associated with common HLA-A alleles. The number of SNP loci was 2.5 times greater for the solo LTR at the AK locus, which is located closer to the HLA-A gene than the solo or 3′ LTR at the HG locus. Our study shows that the nucleotide variations of the MER9-LTR DNA sequences are additional informative markers in fine mapping HLA-A genomic haplotypes for future population, evolutionary, and disease studies.     

The Arabidopsis DNA mismatch repair gene <Emphasis Type="Italic">PMS1</Emphasis> restricts somatic recombination between homeologous sequences

The eukaryotic DNA mismatch repair (MMR) system contributes to maintaining the fidelity of genetic information by correcting replication errors and preventing illegitimate recombination events. This study aimed to examine the function(s) of the Arabidopsis thaliana PMS1 gene (AtPMS1), one of three homologs of the bacterial MutL gene in plants. Two independent mutant alleles (Atpms1-1 and Atpms1-2) were obtained and one of these (Atpms1-1) was studied in detail. The mutant exhibited a reduction in seed set and a bias against the transmission of the mutant allele. Somatic recombination, both homologous and homeologous, was examined using a set of reporter constructs. Homologous recombination remained unchanged in the mutant while homeologous recombination was between 1.7- and 4.8-fold higher than in the wild type. This increase in homeologous recombination frequency was not correlated with the degree of sequence divergence. In RNAi lines, a range of increases in homeologous recombination were observed with two lines showing a 3.3-fold and a 3.6-fold increase. These results indicate that the AtPMS1 gene contributes to an antirecombination activity aimed at restricting recombination between diverged sequences. Liangliang Li, Eric Dion contributed equally to this work.     

Evolutionary history of an MHC gene in two leporid species: characterisation of <Emphasis Type="Italic">Mhc-DQA</Emphasis> in the European brown hare and comparison with the European rabbit

We surveyed the genetic diversity of the expressed major histocompatibility complex class II DQA locus in natural populations of European brown hares, Lepus europaeus, from Austria and Belgium (267 individuals in total). Based on cDNA sequences, we designed hare-specific primers to amplify the highly variable second exon of the DQA gene. Using cloning–sequencing methodology and capillary electrophoresis single-strand conformation polymorphism, we found ten alleles of the DQA exon 2 locus across these two European regions, of which eight are described for the first time. To search for signals of selection and recombination in the evolution of the DQA gene within the leporids, we augmented our sample with orthologous DQA alleles from the European rabbit, Oryctolagus cuniculus, in order to carry out a species level, species pairwise comparison. We found evidence of recombination in the history of the DQA sequences in leporids with some recombinant alleles bridging the species divide. In both species, selection on peptide binding site codons can be detected, though stronger for the rabbit. This result suggests that there may be a differential selection pressure in the deeper evolutionary history of these two species due to differences in several demographic and ecological traits likely subjecting them to differential selection by parasites. Finally, evolutionary relationships show a widespread and statistically significant intermingling of alleles from the two species. The many macroparasites shared between hares and rabbits may explain this pattern of trans-species polymorphism. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. The nucleotide sequence data reported in this paper have been submitted to Genbank and have been assigned the accession numbers FJ225335–FJ225346.     

Efficient Agrobacterium-mediated transformation of Arabidopsis thaliana using the bar gene as selectable marker

Summary We have established an efficient Agrobacterium-mediated transformation procedure for Arabidopsis thaliana genotype C24 using the chimeric bialaphos resistance gene (bar) coding for phosphinothricin acetyltransferase (PAT). Hypocotyl explants from young seedlings cocultivated with agrobacteria carrying a bar gene were selected on shoot-inducing media containing different concentrations of phosphinothricin (PPT) which is an active component of bialaphos. We found that 20 mg/l of PPT completely inhibited the control explants from growing whereas the explants transformed with the bar gene gave rise to multiple shoots resistant to PPT after 3 weeks under the same selection conditions. The transformation system could also be applied to root explants. Resulting plantlets could produce viable seeds in vitro within 3 months after preparation of the explants. The stable inheritance of the resistance trait, the integration and expression of the bar gene in the progeny were confirmed by genetic tests, Southern analysis and PAT enzyme assay, respectively. In addition, the mature plants in soil showed tolerance to the herbicide Basta.Abbreviations bar bialaphos resistance gene - CIM callus-inducing medium - DTNB 5,5-dithiobis(2-nitrobenzoic acid) - GM germination medium - HPT hygromycin phosphotransferase - MS Murashige and Skoog salts - NPTII neomycin phosphotransferase II - PAT phosphinothricin acetyltransferase - PPT phosphinothricin - SIM shoot-inducing medium     

Characterization of an unusual <Emphasis Type="Italic">Ds</Emphasis> transposable element in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>: Insertion of an abortive circular transposition intermediate

The maize Ac/Dstransposable elements, which belong to the hAT transposon superfamily, are widely used as insertional mutagens in numerous plant species. Molecular studies suggest that Ac/Ds elements transpose in a conservative non-replicative fashion; however the molecular mechanism of transposition remains unclear. We describe here the identification of an unusual Ds element, Ds-mmd1, in a transgenic Arabidopsis line. Ds-mmd1 is rearranged relative to the original Ds element, such that the original 5 and 3 ends are internal and previously internal sequences are the new 5 and 3 termini of Ds-mmd1. Short duplications of plant genomic DNA and Ds sequences are present at the Ds-mmd1 junctions, suggesting that a circular Dsmolecule was part of the events that created the Ds-mmd1 element. In addition, a revertant analysis on mmd1 plants demonstrated that Ds-mmd1 can be eliminated from the genome in an Ac-dependent process.     

Molecular evolution and genome divergence at <Emphasis Type="Italic">RPB2</Emphasis> gene of the St and H genome in <Emphasis Type="Italic">Elymus</Emphasis> species

Molecular evolution of the second largest subunit of low copy nuclear RNA polymerase II (RPB2) in allotetrploid StH genomic species of Elymus is characterized here. Our study first reported a 39-bp MITE stowaway element insertion in the genic region of RPB2 gene for all tetraploid Elymus St genome and diploid Pseudoroegneria spicata and P. stipifolia St genome. The sequences on 3′-end are highly conserved, with AGTA in all sequences but H10339 (E. fibrosis), in which the AGTA was replaced with AGAA. All 12 Stowaway-containing sequences encompassed a 9 bp conserved TIRs (GAGGGAGTA). Interestingly, the 5′-end sequence of GGTA which was changed to AGTA or deleted resulted in Stowaway excision in the H genome of Elymus sepcies, in which Stowaway excision did not leave footprint. Another two large insertions in all St genome sequences are also transposable-like elements detected in the genic region of RPB2 gene. Our results indicated that these three transposable element indels have occurred prior to polyploidization, and shaped the homoeologous RPB2 loci in St and H genome of Eymus species. Nucleotide diversity analysis suggested that the RPB2 sequence may evolve faster in the polyploid species than in the diploids. Higher level of polymorphism and genome-specific amplicons generated by this gene indicated that RPB2 is an excellent tool for investigating the phylogeny and evolutionary dynamics of speciation, and the mode of polyploidy formation in Elymus species.     

The Arabidopsis MutS homolog AtMSH5 is required for normal meiosis

MSH5, a member of the MutS homolog DNA mismatch repair protein family, has been shown to be required for proper homologous chromosome recombination in diverse organisms such as mouse, budding yeast and Caenorhabditis elegans. In this paper, we show that a mutant Arabidopsis plant carrying the putative disrupted AtMSH5 gene exhibits defects during meiotic division, producing a proportion of nonviable pollen grains and abnormal embryo sacs, and thereby leading to a decrease in fertility. AtMSH5 expression is confined to meiotic floral buds, which is consistent with a possible role during meiosis. Cytological analysis of male meiosis revealed the presence of numerous univalents from diplotene to metaphase I, which were associated with a great reduction in chiasma frequencies. The average number of residual chiasmata in the mutant is reduced to 2.54 per meiocyte, which accounts for approximately 25% of the amount in the wild type. Here, quantitative cytogenetical analysis reveals that the residual chiasmata in Atmsh5 mutants are randomly distributed among meiocytes, suggesting that AtMSH5 has an essential role during interference-sensitive chiasma formation. Taken together, the evidence indicates that AtMSH5 promotes homologous recombination through facilitating chiasma formation during prophase I in Arabidopsis.