Microsynteny between pea and Medicago truncatula in the SYM2 region

The crop legume pea (Pisum sativum) is genetically well characterized. However, due to its large genome it is not amenable to efficient positional cloning strategies. The purpose of this study was to determine if the model legume Medicago truncatula, which is a close relative of pea, could be used as a reference genome to facilitate the cloning of genes identified based on phenotypic and genetic criteria in pea. To this end, we studied the level of microsynteny between the SYM2 region of pea and the orthologous region in M. truncatula. Initially, a marker tightly linked to SYM2 was isolated by performing differential RNA display on near-isogenic pea lines. This marker served as the starting point for construction of a BAC physical map in M. truncatula. A fine-structure genetic map, based on eight markers from the M. truncatula physical map, indicates that the two genomes in this region share a conserved gene content. Importantly, this fine structure genetic map clearly delimits the SYM2-containing region in pea and the SYM2-orthologous region in M. truncatula, and should provide the basis for cloning SYM2. The utility of the physical and genetic tools in M. truncatula to dissect the SYM2 region of pea should have important implications for other gene cloning experiments in pea, in particular where the two genomes are highly syntenic within the region of interest.     

A mutation affecting symbiosis in the pea line Risnod27 changes the ion selectivity filter of the DMI1 homolog

After identifying regions of cDNA conserved between the symbiotic gene DMI1 of the model species Medicago truncatula and the homologous genomic region of Arabidopsis thaliana, universal primers were designed from 8 of 12 exons to allow the routine amplification of plant homologs. As an example, the complete homologous sequence from the pea (Pisum sativum L.) was amplified and sequenced, although the poorly conserved 5′-end and 5′-flanking region of the gene had to be amplified using a modified TAIL-PCR strategy. The identity of this amplified homolog with the SYM8 gene was independently confirmed by the presence of a single nucleotide change in the coding sequence of the mutant line Risnod27 (sym8) that cosegregated with the asymbiotic phenotype. Five insertions in pea introns responsible for increasing the total length of SYM8 by 1443 bp, compared to the M. truncatula homolog DMI1, belong to known transposon and retrotransposon families of pea and legumes in general. In view of the predicted function of SYM8 as an ion channel, the Risnod27 mutation (His309Tyr) appears to be localized in the selectivity filter domain. This finding confirms the essential role of histidine 309 in the symbiotic function of SYM8 and provides a guide to its ionic specificity. In view of the Risnod27 symbiotic phenotype, we hypothesize that SYM8 does not have identical functions in the transduction of rhizobial and mycorrhizal signals. The variability of the N-proximal region of the known legume homologs of DMI1 suggests an interaction with a variable ligand.     

Floral development of the model legume <Emphasis Type="Italic">Medicago truncatula</Emphasis>: ontogeny studies as a tool to better characterize homeotic mutations

This work provides new evidence of the complex genetic regulation necessary to accomplish flower development in legumes. Using scanning electron microscopy (SEM) analysis, we have characterized the early developmental events of the wild type Medicago truncatula flower and selected morphological characters as markers to break it down into eight different developmental stages. The order of floral organ initiation in M. truncatula and pea (Pisum sativum L.), in contrast to Arabidopsis and Antirrhinum, is unidirectional in all whorls starting from the abaxial position of the flower with a high degree of overlap. Another main difference is the existence of four common primordia from which petals and stamens differentiate. The formation of common primordia, as opposed to discrete petal and stamen primordia, has been described in many legume and non-legume plants. The main differences between pea and M. truncatula floral ontogeny are in carpel and fruit development. We also used these morphological markers as tools to characterize early alterations in the flower development of a male-sterile M. truncatula floral homeotic mutant named mtapetala. This mutant displays a phenotype resembling those of weak class B mutants with homeotic conversions of floral organ whorls 2 and 3 into sepaloid and carpelloid structures, respectively. Ontogeny studies of the mtapetala mutant flowers showed similarities with the effects of previously described loss-of-B-function mutations. Differences between ontogeny of wild type and mtapetala flowers could not be detected during the first stages (1-5) of flower development. In late stage 5, abnormal-shaped petals with acute lobes and trichomes as well as abnormal-shaped stamens were visible in whorls 2 and 3. At stage 6, the morphology of petals began to change, developing enlarged sepaloid structures bearing trichomes and first the antesepalous stamens and then the antepetalous stamens began to differentiate carpelloid anthers from filaments. Third whorl organs presented different degrees of carpelloidy. The present study should provide tools for the characterization and comparative analyses of new Medicago floral homeotic mutants and could be useful in elucidating how floral organ identity functions work in legumes.     

Conversion of AFLP fragments tightly linked to SCMV resistance genes Scmv1 and Scmv2 into simple PCR-based markers

In a previous study, bulked segregant analysis with amplified fragment length polymorphisms (AFLPs) identified several markers closely linked to the sugarcane mosaic virus resistance genes Scmv1 on chromosome 6 and Scmv2 on chromosome 3. Six AFLP markers (E33M61-2, E33M52, E38M51, E82M57, E84M59 and E93M53) were located on chromosome 3 and two markers (E33M61-1 and E35M62-1) on chromosome 6. Our objective in the present study was to sequence the respective AFLP bands in order to convert these dominant markers into more simple and reliable polymerase chain reaction (PCR)-based sequence-tagged site markers. Six AFLP markers resulted either in complete identical sequences between the six inbreds investigated in this study or revealed single nucleotide polymorphisms within the inbred lines and were, therefore, not converted. One dominant AFLP marker (E35M62-1) was converted into an insertion/deletion (indel) marker and a second AFLP marker (E33M61-2) into a cleaved amplified polymorphic sequence marker. Mapping of both converted PCR-based markers confirmed their localization to the same chromosome region (E33M61-2 on chromosome 3; E35M62-1 on chromosome 6) as the original AFLP markers. Thus, these markers will be useful for marker-assisted selection and facilitate map-based cloning of SCMV resistance genes.     

Functional mapping in pea, as an aid to the candidate gene selection and for investigating synteny with the model legume Medicago truncatula

The identification of the molecular polymorphisms giving rise to phenotypic trait variability—both quantitative and qualitative—is a major goal of the present agronomic research. Various approaches such as positional cloning or transposon tagging, as well as the candidate gene strategy have been used to discover the genes underlying this variation in plants. The construction of functional maps, i.e. composed of genes of known function, is an important component of the candidate gene approach. In the present paper we report the development of 63 single nucleotide polymorphism markers and 15 single-stranded conformation polymorphism markers for genes encoding enzymes mainly involved in primary metabolism, and their genetic mapping on a composite map using two pea recombinant inbred line populations. The complete genetic map covers 1,458 cM and comprises 363 loci, including a total of 111 gene-anchored markers: 77 gene-anchored markers described in this study, 7 microsatellites located in gene sequences, 16 flowering time genes, the Tri gene, 5 morphological markers, and 5 other genes. The mean spacing between adjacent markers is 4 cM and 90% of the markers are closer than 10 cM to their neighbours. We also report the genetic mapping of 21 of these genes in Medicago truncatula and add 41 new links between the pea and M. truncatula maps. We discuss the use of this new composite functional map for future candidate gene approaches in pea.     

Molecular cloning and characterization of triterpene synthases from Medicago truncatula and Lotus japonicus

Cloning of OSCs required for triterpene synthesis from legume species that are amenable to molecular genetics will provide tools to address the importance of triterpenes and their derivatives during normal plant growth and development and also in interactions with symbionts and pathogens. Here we report the cloning and characterization of a total of three triterpene synthases from the legume species Medicago truncatula and Lotus japonicus. These include a -amyrin synthase from M. truncatula (MtAMYI) and a mixed function triterpene synthase from Lotus japonicus (LjAMY2). A partial cDNA predicted to encode a -amyrin synthase (LjAMY1) was also isolated from L. japonicus. The expression patterns of MtAMY1, LjAMY1 and LjAMY2 and of additional triterpene synthases previously characterised from M. truncatula and pea differ in different plant tissues and during nodulation, suggesting that these enzymes may have distinct roles in plant physiology and development.     

Construction of a bacterial artificial chromosome library of Medicago truncatula and identification of clones containing ethylene-response genes

 To facilitate genome analysis and map-based cloning of symbiotic genes in the model legume Medicago truncatula, a bacterial artificial chromosome (BAC) library was constructed. The library consists of 30 720 clones with an average insert size of approximately 100 kb, representing approximately five haploid-genome equivalents. The frequency of BAC clones carrying inserts of chloroplast DNA was estimated to be 1.4%. Screening of the library with single- or low-copy genes as hybridization probes resulted in the detection of 1–12 clones per gene. Hybridization of the library with repeated sequences such as rDNA genes and transposon-like elements of M. truncatula revealed the presence of 60 and 374 BAC clones containing the two sequences, respectively. The BAC library was pooled for screening by polymerase chain reaction (PCR)-amplification. To demonstrate the utility of this system, we used primers designed from a conserved region of the ein3-like loci of Arabidopsis thaliana and isolated six unique BAC clones from the library. DNA gel-blot and sequence analyses showed that these ein3-like clones could be grouped into three classes, an observation consistent with the presence of multiple ein3-like loci in M. truncatula. These results indicate that the BAC library represents a central resource for the map-based cloning and physical mapping in M. truncatula and other legumes. Received: 27 July 1998 / Accepted: 5 August 1998     

Fine mapping and DNA fiber FISH analysis locates the tobamovirus resistance gene <Emphasis Type="Italic">L</Emphasis><Superscript>3</Superscript> of <Emphasis Type="Italic">Capsicum chinense</Emphasis> in a 400-kb region of R-like genes cluster embedded in highly repetitive sequences

The tobamovirus resistance gene L ³ of Capsicum chinense was mapped using an intra-specific F2 population (2,016 individuals) of Capsicum annuum cultivars, into one of which had been introduced the C. chinense L ³ gene, and an inter-specific F2 population (3,391 individuals) between C. chinense and Capsicum frutescence. Analysis of a BAC library with an AFLP marker closely linked to L ³-resistance revealed the presence of homologs of the tomato disease resistance gene I2. Partial or full-length coding sequences were cloned by degenerate PCR from 35 different pepper I2 homologs and 17 genetic markers were generated in the inter-specific combination. The L ³ gene was mapped between I2 homolog marker IH1-04 and BAC-end marker 189D23M, and located within a region encompassing two different BAC contigs consisting of four and one clones, respectively. DNA fiber FISH analysis revealed that these two contigs are separated from each other by about 30 kb. DNA fiber FISH results and Southern blotting of the BAC clones suggested that the L ³ locus-containing region is rich in highly repetitive sequences. Southern blot analysis indicated that the two BAC contigs contain more than ten copies of the I2 homologs. In contrast to the inter-specific F2 population, no recombinant progeny were identified to have a crossover point within two BAC contigs consisting of seven and two clones in the intra-specific F2 population. Moreover, distribution of the crossover points differed between the two populations, suggesting linkage disequilibrium in the region containing the L locus. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. R. Tomita and J. Murai contributed equally to this work.     

Mapping of the nodulation loci sym9 and sym10 of pea ( Pisum sativum L.)

Several mutants defective in the nodulation process during rhizobial or endomycorrhizal endosymbiosis of pea have been identified previously. We have integrated the map positions of two such nodulation mutations, sym9 and sym10, into the molecular map of pea by applying molecular-marker techniques combined with bulked segregant analysis (BSA). Lines P2 and P54 were found to carry alleles of sym9, line P56 carried an allele of sym10. F2 populations were derived from crosses of P2, P54 and P56, to JI281 and JI15, two of the parental lines that have been used previously to generate a molecular map of pea. sym9 was located on linkage group IV by AFLP-BSA analysis and subsequently mapped by RFLP in both F2 populations, P2 2 JI281 and P54 2 JI281. RFLP-BSA analysis was applied to assign sym10 to linkage group I. The RFLP marker locus, chs2, co-segregates with sym10 in the F2 population of P56 2 JI15.     

High-resolution mapping of the bolting gene <Emphasis Type="Italic">B</Emphasis> of sugar beet

Sugar beet (Beta vulgaris L.) is a biennial species. Shoot elongation (bolting) starts after a period of low temperature. The dominant allele of locus B causes early bolting without cold treatment. This allele is abundant in wild beets whereas cultivated beets carry the recessive allele. Fifteen AFLP markers, tightly linked to the bolting locus, have been identified using bulked segregant analysis. The F₂-population consisted of 2,134 individuals derived after selfing a single F₁-plant (Bb). In a first step, a linkage map was established with 249 markers based on 775 F₂-individuals with a coverage of 822.3 cM. The loci are dispersed over nine linkage groups corresponding to the haploid chromosome number of Beta species. Seventeen marker loci were placed at a distance less than 3.2 cM around the bolting gene. In a second step, four of those markers most closely linked to B were mapped with the entire F₂-population. Two of the markers were mapped flanking the B gene at distances of 0.14 and 0.23 cM. The other two markers were mapped at a distance of 0.5 cM from the gene. The tight linkage could be verified by testing 88 unrelated plants from a breeding program. The closely linked markers will enable breeders to select for the non-bolting character without laborious test crossings. Moreover, these markers are being used for map-based cloning of the bolting gene.     

Cross-species amplification of Medicago truncatula microsatellites across three major pulse crops

Model plants are facilitating the genetic characterization and comparative mapping of a number of traditional crops. Medicago truncatula has been widely accepted as a model plant to this end as it provides the essential tools for multiple aspects of legume genetics and genomics. A large set of markers from highly conserved M. truncatula gene regions is being created and used to establish a worldwide framework for comparative genomic studies in legumes. We have investigated the potential for cross-species amplification of 209 expressed sequence tag (EST)-based and 33 bacterial artificial chromosome (BAC)-based microsatellites from M. truncatula in the three most important European legume pulses—pea, faba bean and chickpea—that might facilitate future comparative mapping. Our results revealed significant transferability of M. truncatula microsatellites to the three pulses (40% in faba bean, 36.3% in chickpea and 37.6% in pea). The percentage of M. truncatula EST-SSRs (simple sequence repeats) amplified in the three crops (39–43%) was twofold higher than that of the genomic SSRs (21–24%). Sequence analysis determined that the level of conservation in the microsatellite motif was very low, while the flanking regions were generally well conserved. The variations in the sequences were mainly due to changes in the number of repeat motifs in the microsatellite region combined with indel and base substitutions. None of the functional microsatellites showed direct polymorphism among the parental genotypes tested, consequently preventing their immediate use for mapping purposes.Electronic Supplementary Material Supplementary material is available for this article at     

A complex genetic network involving a broad-spectrum locus and strain-specific loci controls resistance to different pathotypes of Aphanomyces euteiches in Medicago truncatula

A higher understanding of genetic and genomic bases of partial resistance in plants and their diversity regarding pathogen variability is required for a more durable management of resistance genetic factors in sustainable cropping systems. In this study, we investigated the diversity of genetic factors involved in partial resistance to Aphanomyces euteiches, a very damaging pathogen on pea and alfalfa, in Medicago truncatula. A mapping population of 178 recombinant inbred lines, from the cross F83005.5 (susceptible) and DZA045.5 (resistant), was used to identify quantitative trait loci for resistance to four A. euteiches reference strains belonging to the four main pathotypes currently known on pea and alfalfa. A major broad-spectrum genomic region, previously named AER1, was localized to a reduced 440 kb interval on chromosome 3 and was involved in complete or partial resistance, depending on the A. euteiches strain. We also identified 21 additive and/or epistatic genomic regions specific to one or two strains, several of them being anchored to the M. truncatula physical map. These results show that, in M. truncatula, a complex network of genetic loci controls partial resistance to different pea and alfalfa pathotypes of A. euteiches, suggesting a diversity of molecular mechanisms underlying partial resistance.     

Detection of partial resistance quantitative trait loci against Didymella pinodes in Medicago truncatula

Ascochyta blight caused by Didymella pinodes (formerly Mycosphaerella pinodes) is one of the most important fungal diseases of pea (Pisum sativum) worldwide that can also infect the model legume Medicago truncatula. The objective of this study was to identify quantitative trait loci (QTLs) controlling resistance to D. pinodes in M. truncatula. Response to D. pinodes was studied under controlled conditions in seedlings of a population derived from the cross J6 × F83005.5, two M. truncatula lines that are, respectively, resistant and susceptible to D. pinodes. A combined map using two different recombinant inbred line populations was then used to identify the genomic regions bearing putative QTLs and to improve the position of the QTLs. A single QTL associated with resistance to D. pinodes was detected on linkage group 2, explaining up to 13 % of the total phenotypic variation for relative disease severity against the pathogen. Two simple sequence repeat markers, MTE80 and mtic890 (3 cM apart) were the ones most significantly associated with the QTL. These markers are located in bacterial artifical chromosomes AC119409 and AC125474, respectively, both of them overlapping on M. truncatula chromosome 2. The integration of QTL analysis and genomics in M. truncatula will contribute to the development of new markers and facilitate the identification of candidate genes for Ascochyta blight resistance.     

Mapping of a thermo-sensitive earliness <Emphasis Type="Italic">per se</Emphasis> gene on <Emphasis Type="Italic">Triticum monococcum</Emphasis> chromosome 1A<Superscript>m</Superscript>

An earliness per se gene, designated Eps-A^m1, was mapped in diploid wheat in F₂ and single-seed descent mapping populations from the cross between cultivated (DV92) and wild (G3116) Triticum monococcum accessions. A QTL with a peak on RFLP loci Xcdo393 and Xwg241, the most distal markers on the long arm of chromosome 1A^m, explained 47% of the variation in heading date (LOD score 8.3). Progeny tests for the two F_2:3 families with critical recombination events between Xcdo393 and Xwg241 showed that the gene was distal to Xcdo393 and linked to Xwg241. Progeny tests and replicated experiments with line #3 suggested that Eps-A^m1 was distal to Xwg241. This gene showed a large effect on heading date in the controlled environment experiments, and a smaller, but significant, effect under natural conditions. Eps-A^m1 showed significant epistatic interactions with photoperiod and vernalization treatments, suggesting that the different classes of genes affecting heading date interact as part of a complex network that controls the timing of flowering induction. Besides its interactions with other genes affecting heading date, Eps-A^m1 showed a significant interaction with temperature. The effect of temperature was larger in plants carrying the DV92 allele for late flowering than in those carrying the G3116 allele for early flowering. Average differences in heading date between the experiments performed at 16 °C and 23 °C were approximately 11 days (P < 0.001) for the lines carrying the Eps-A^m1 allele for early flowering but approximately 50 days (P < 0.0001) for the lines carrying the allele for late flowering. The large differences in heading time (average 80 days) observed between plants carrying the G3116 and DV92 alleles when grown at 16 °C, suggest that it would be possible to produce very detailed maps for this gene to facilitate its future positional cloning.     

Comparative mapping between<Emphasis Type="Italic"> Medicago sativa</Emphasis> and<Emphasis Type="Italic"> Pisum sativum</Emphasis>

Comparative genome analysis has been performed between alfalfa ( Medicago sativa) and pea ( Pisum sativum), species which represent two closely related tribes of the subfamily Papilionoideae with different basic chromosome numbers. The positions of genes on the most recent linkage map of diploid alfalfa were compared to those of homologous loci on the combined genetic map of pea to analyze the degree of co-linearity between their linkage groups. In addition to using unique genes, analysis of the map positions of multicopy (homologous) genes identified syntenic homologs (characterized by similar positions on the maps) and pinpointed the positions of non-syntenic homologs. The comparison revealed extensive conservation of gene order between alfalfa and pea. However, genetic rearrangements (due to breakage and reunion) were localized which can account for the difference in chromosome number (8 for alfalfa and 7 for pea). Based on these genetic events and our increasing knowledge of the genomic structure of pea, it was concluded that the difference in genome size between the two species (the pea genome is 5- to 10-fold larger than that of alfalfa) is not a consequence of genome duplication in pea. The high degree of synteny observed between pea and Medicago loci makes further map-based cloning of pea genes based on the genome resources now available for M. truncatula a promising strategy.Electronic Supplementary Material Supplementary material is available in the online version of this article at Communicated by W. R. McCombie     

A family of repeated sequences dispersed through the genome of Lilium henryi

A family of dispersed repeats longer than 7 kilobase pairs (kbp) has been identified in the very large genome of Lilium henryi, and two subregions cloned. Initially a rapidly reannealing probe (C₀t<1 M s) was prepared by hydroxyapatite chromatography. Half the copies of all sequences repeated 15000 times per genome are expected to reanneal by this C₀t value. The probe hydridized to abundant fragments of 2, 5, and 7 kbp released from genomic DNA by Bam HI digestion. Twelve 2-kb fragments and ten 5-kb sequences were cloned into pBR322. Restriction mapping of the two sets of clones showed individual members to be quite similar. Length variation was no more than 200 base pairs (bp) between repeats, and consensus sites were present on 80%–90% of occasions. In situ hybridization using representative 2-kbp and 5-kbp clones showed each sequence to be dispersed throughout all chromosomal regions. Studies on the genomic organization suggested that the 2-kbp and 5-kbp sequences are usually adjacent, and that occasional absence of the internal Bam HI site results in the release of the 7-kbP fragment. There are at least 13000 copies of the full repeat per L. henryi genome, thus accounting for approximately 0.3% of the total of 32 million kbp.     

Identification of DNA amplification fingerprinting (DAF) markers close to the symbiosis-ineffective sym31 mutation of pea (Pisum sativum L.)

 We demonstrate efficient genome mapping through a combination of bulked segregant analysis (BSA) with DNA amplification fingerprinting (DAF). Two sets of 64 octamer DAF primers, along with two PCR programs of low- and high-annealing temperatures (30°C and 55°C, respectively), appeared to be enough to locate molecular markers within 2–5 cM of a gene of interest. This approach allowed the rapid identification of four BSA markers linked to the pea (Pisum sativum L.) Sym31 gene, which is responsible for bacteroid and symbiosome differentiation. Three of these markers are shown to be tightly linked to the sym31 mutation. Two markers flanking the Sym31 gene, A21-310 and B1-277, cover a 4–5 cM interval of pea linkage group 3. Both markers were converted to sequence-characterized amplified regions (SCARs). The flanking markers may be potential tools for marker-assisted selection or for positional cloning of the Sym31 gene. Received: 2 July 1998 / Accepted: 8 October 1998     

An insertion of Escherichia coli transposable element IS1K into the site immediately before tetracycline-resistance determinant of Bacillus subtilis chromosomal DNA fragment in cloning in E. coli

In cloning in Escherichia coli C600 of a 4.5-kbp HindIII DNA fragment with the tetracycline-resistance determinant (tetBS908) from Bacillus subtilis GSY908 chromosome using a plasmid vector, a 5.2-kbp HindIII DNA fragment was also isolated at a ratio of 2 to 89. The two independently obtained 5.2-kbp fragments were an insertion derivative of the 4.5-kbp fragment and carried E. coli transposable element ISlK, which was inserted at the same site immediately before tetBS908 in the same direction. For the ISlK insertions, the 8-bp sequence CAAATTTT was used as a target, this having no similarity to any published sequences.