Ecological–genetic feedback in DNA repair in wild barley, Hordeum spontaneum

Regulation of genetic variation in natural populations is a problem of primary importance to evolutionary biology. In the reported study, the repair efficiency of double strand DNA breaks was compared in six wild barley accessions from Israeli natural populations of H. spontaneum: three from mesic populations (one from Maalot and two from Mount Meron, Upper Galilee) and three from xeric populations (one from Wadi Quilt in the Judean Desert and two from Sede Boqer, in the northern Negev Desert). Pulsed field gel electrophoresis was used to score double-strand breaks of DNA (DSBs) caused by methyl methanesulphonate (MMS) treatment. All six accessions were also tested for heat tolerance: four of these, three xeric and one mesic (from Maalot population), were scored as heat tolerant whereas both accessions from Mount Meron population displayed heat sensitivity. MMS caused a significant increase in the level of DSBs relative to the control in all accessions. The major questions were whether and how the efficiency of DNA repair after mutagenic treatment is affected by the environmental conditions and accession’s adaptation to these conditions. Differences were found among the accessions in the repair pattern. Plants of two out of the four heat tolerant accessions did not manage to repair DNA neither at 25°C nor at 37°C. The remaining two heat tolerant accessions significantly repaired the breaks at 37°C, but not at 25°C. By contrast, plants of the two heat susceptible accessions significantly lowered the level of DSBs at 25°C but not at 37°C. Therefore, the accessions that proved capable to repair the induced damages in DNA at one of the two temperatures displayed a pattern that may imply the existence of a negative feedback mechanism in regulation of genetic variation. Such a dependence of DNA integrity on environment and genotype may serve an important factor for maintaining relatively high level of mutability without increasing the genetic load.     

Natural variation in a subtelomeric region of Arabidopsis: implications for the genomic dynamics of a chromosome end

We investigated genome dynamics at a chromosome end in the model plant Arabidopsis thaliana through a study of natural variation in 35 wild accessions. We focused on the single-copy subtelomeric region of chromosome 1 north (approximately 3.5 kb), which represents the relatively simple organization of subtelomeric regions in this species. PCR fragment-length variation across the subtelomeric region indicated that the 1.4-kb distal region showed elevated structural variation relative to the centromere-proximal region. Examination of nucleotide sequences from this 1.4-kb region revealed diverse DNA rearrangements, including an inversion, several deletions, and an insertion of a retrotransposon LTR. The structures at the deletion and inversion breakpoints are characteristic of simple deletion-associated nonhomologous end-joining (NHEJ) events. There was strong linkage disequilibrium between the distal subtelomeric region and the proximal telomere, which contains degenerate and variant telomeric repeats. Variation in the proximal telomere was characterized by the expansion and deletion of blocks of repeats. Our sample of accessions documented two independent chromosome-healing events associated with terminal deletions of the subtelomeric region as well as the capture of a scrambled mitochondrial DNA segment in the proximal telomeric array. This natural variation study highlights the variety of genomic events that drive the fluidity of chromosome termini.     

Natural variants of AtHKT1 enhance Na+ accumulation in two wild populations of Arabidopsis

Plants are sessile and therefore have developed mechanisms to adapt to their environment, including the soil mineral nutrient composition. Ionomics is a developing functional genomic strategy designed to rapidly identify the genes and gene networks involved in regulating how plants acquire and accumulate these mineral nutrients from the soil. Here, we report on the coupling of high-throughput elemental profiling of shoot tissue from various Arabidopsis accessions with DNA microarray-based bulk segregant analysis and reverse genetics, for the rapid identification of genes from wild populations of Arabidopsis that are involved in regulating how plants acquire and accumulate Na(+) from the soil. Elemental profiling of shoot tissue from 12 different Arabidopsis accessions revealed that two coastal populations of Arabidopsis collected from Tossa del Mar, Spain, and Tsu, Japan (Ts-1 and Tsu-1, respectively), accumulate higher shoot levels of Na(+) than do Col-0 and other accessions. We identify AtHKT1, known to encode a Na(+) transporter, as being the causal locus driving elevated shoot Na(+) in both Ts-1 and Tsu-1. Furthermore, we establish that a deletion in a tandem repeat sequence approximately 5 kb upstream of AtHKT1 is responsible for the reduced root expression of AtHKT1 observed in these accessions. Reciprocal grafting experiments establish that this loss of AtHKT1 expression in roots is responsible for elevated shoot Na(+). Interestingly, and in contrast to the hkt1-1 null mutant, under NaCl stress conditions, this novel AtHKT1 allele not only does not confer NaCl sensitivity but also cosegregates with elevated NaCl tolerance. We also present all our elemental profiling data in a new open access ionomics database, the Purdue Ionomics Information Management System (PiiMS; http://www.purdue.edu/dp/ionomics). Using DNA microarray-based genotyping has allowed us to rapidly identify AtHKT1 as the casual locus driving the natural variation in shoot Na(+) accumulation we observed in Ts-1 and Tsu-1. Such an approach overcomes the limitations imposed by a lack of established genetic markers in most Arabidopsis accessions and opens up a vast and tractable source of natural variation for the identification of gene function not only in ionomics but also in many other biological processes.     

2b-RAD: a simple and flexible method for genome-wide genotyping

We describe 2b-RAD, a streamlined restriction site-associated DNA (RAD) genotyping method based on sequencing the uniform fragments produced by type IIB restriction endonucleases. Well-studied accessions of Arabidopsis thaliana were genotyped to validate the method's accuracy and to demonstrate fine-tuning of marker density as needed. The simplicity of the 2b-RAD protocol makes it particularly suitable for high-throughput genotyping as required for linkage mapping and profiling genetic variation in natural populations.     

Genome elimination during microsporogenesis in two pentaploid accessions of Brachiaria decumbens (Poaceae)

Polyploidy is a prominent and significant force in plant evolution, taking place since ancient times and continuing until today. Recent cytogenetic studies in the genus Brachiaria using germplasm collected from wild African savannas in the 1980s revealed that most species and accessions within species are polyploid. Diploid, tetraploid, and pentaploid accessions have been found. We found asynchronous meiosis during microsporogenesis, followed by genome elimination, in two pentaploid (2n = 5x = 45) accessions (D53 and D71) of a hardy, invasive pasture grass, introduced from Africa to Brazil, Brachiaria decumbens. In these accessions, chromosomes paired as 18 bivalents and nine univalents during diakinesis, suggesting that these accessions resulted from a recent event of natural hybridization. The lack of chromosome associations in the genomes suggests that these accessions resulted from hybridization between two genotypes that are not closely related, with low genome affinity and with different meiotic rhythms. This supposition is reinforced by the meiotic behavior of the nine univalents, which were always laggard in relation to the other chromosomes and eliminated as micronuclei in microspores. The behavior of these accessions, which have an odd level of ploidy and confirmed genome elimination, supports the general assumption that a polyploid accession can undergo a new event of polyploidization by natural hybridization (neopolyploidyzation). This evidence for natural hybridization in Brachiaria shows that this is a wild genus in an ongoing evolutionary process.     

Interrelationship of cultivated rices Oryza sativa and O. glaberrima with wild O. perennis complex

Summary Phylogenetic relationship of the cultivated rices Oryza sativa and O. glaberrima with the O. perennis complex, distributed on the three continents of Asia, Africa and America, and O. australiensis has been studied using Fraction 1 protein and two repeated DNA sequences as markers. Fraction 1 protein isolated from the leaf tissue of accessions of different species was subjected to isoelectric focusing. All the species studied have similar nuclear-encoded small subunit polypeptides and chloroplast-encoded large subunit polypeptides, except two of the O. perennis accessions from South America and O. australiensis, which have a different pattern for the chloroplast subunit. Two DNA sequences were isolated from Eco R1 restriction endonuclease digests of total DNA from O. sativa. One of the sequences has been characterized as highly repeated satellite DNA, and the other one as a moderately repeated DNA sequence. These sequences were used as probes in DNA/DNA hybridization with restriction endonuclease digested DNA from some accessions of the different species. Those accessions that are divergent for large subunit polypeptides of Fraction 1 protein (O. australiensis and two of the four South American O. perennis accessions) also lack the satellite DNA and have a different hybridization pattern with the moderately repeated sequence. All other accessions, irrespective of their geographical origin, are similar. We propose that various accessions of O. perennis from Africa and Asia are closely related to O. sativa and O. glaberrima, and that the dispersal of cultivated and O. perennis rices to different continents may be quite recent. The American O. perennis is a heterogeneous group. Some of the accessions ascribed to this group are closely related to the Asian and African O. perennis, while others have diverged.     

Genetic investigation of the origination of allopolyploid with virtually synthesized lines: application to the C subgenome of Brassica napus

Although there are a number of different allopolyploids in the plant kingdom, the exact ancestral parents of some allopolyploids have not been well characterized. We propose a strategy in which virtual allopolyploid lines derived from different types of parental species are used to investigate the progenitors of an allopolyploid. The genotypes of the parental lines and the natural allopolyploid were established using a set of DNA molecular markers. The genotypes of the virtual lines were then derived from those of the parental lines, and compared extensively with that of the natural allopolyploid. We applied this strategy to investigate the progenitors of the C subgenome of Brassica napus (rapeseed, AACC). A total of 39 accessions from 10 wild and 7 cultivated types of the B. oleracea cytodeme (CC), and 4 accessions of B. rapa (AA) were used to construct 156 virtual rapeseed lines. Genetic structure was compared among natural rapeseed, virtual rapeseed lines, and their parental lines by principal component analysis and analysis of ancestry. Our data showed that the C subgenome of natural rapeseed was related closely to the genome of cultivated B. oleracea and its related wild types, such as B. incana, B. bourgeaui, B. montana, B. oleracea ssp. oleracea and B. cretica. This finding indicated that these types or their progeny might be ancestral donors of the C subgenome of rapeseed. The successful application of the strategy of virtual allopolyploidy in rapeseed demonstrates that it can possibly be used to identify the progenitors of an allopolyploid species.     

Genetic and geographic polymorphism of cultivated tobaccos (Nicotiana tabacum) in Turkey

Nicotiana tabacum (2n = 48) is a natural amphidiploid and shows a distribution over a geographical area in eastern Anatolia. Random amplified polymorphic DNA (RAPD) technique was used to evaluate both genetic diversity among 21 primitive tobacco accessions comparing flue cure virginia genotype (FCV) and their geographical polymorphism as a source of genetic variations for breeding programs. Only 13 of all the 60 random primers used in RAPD showed polymorphism acceptable for characterization of these accessions. Totally 118 RAPD fragments were generated from 13 decamer primer and 64 of them were found polymorphic (54.2%). Mus and FCV showed the smallest genetic distance among accessions cultivated in the eastern Anatolia. These results shows that the RAPD assay is a powerful approach for identifying genetic and geographic polymorphism. This article was submitted by the authors in English.     

Multiple origins and nrDNA internal transcribed spacer homeologue evolution in the Glycine tomentella (Leguminosae) allopolyploid complex

Despite the importance of polyploidy in the evolution of plants, patterns of molecular evolution and genomic interactions following polyploidy are not well understood. Nuclear ribosomal DNA is particularly complex with respect to these genomic interactions. The composition of nrDNA tandem arrays is influenced by intra- and interlocus concerted evolution and their expression is characterized by patterns such as nucleolar dominance. To understand these complex interactions it is important to study them in diverse natural polyploid systems. In this study we use direct sequencing to isolate and characterize nrDNA internal transcribed spacer (ITS) homeologues from multiple accessions of six different races in the Glycine tomentella allopolyploid complex. The results indicate that in most allopolyploid accessions both homeologous nrDNA repeats are present, but that there are significant biases in copy number toward one homeologue, possibly resulting from interlocus concerted evolution. The predominant homeologue often differs between races and between accessions within a race. A phylogenetic analysis of ITS sequences provides evidence for multiple origins in several of the polyploid races. This evidence for diverse patterns of nrDNA molecular evolution and multiple origins of polyploid races will provide a useful system for future studies of natural variation in patterns of nrDNA expression.     

西藏白菜型油菜遗传多样性的RAPD分析

通过利用22个10bp随机引物对来自西藏高原地区107份白菜型油菜种质资源材料的PAPD分析,探讨了西藏白菜型油菜品种之间的遗传分化关系,结果表明：（1）供试的107份材料共产生236条谱带,其中210条谱带有多态性,占88．98％,说明白菜型油菜在西藏高原地区具有较丰富的遗传多样性;（2）根据引物扩增出的DNA指纹图谱,运用UPGMA分析法,在遗传距离为0．078处,可将供试的107份白菜型油菜划分为11个类群,发现来自于同一地区或气候相似区的品种往往聚在一起,表明西藏高原白菜型油菜品种的相似性与其原产地的地理,气候背景密切相关,并在此基础上,结合西藏高原农业发展历史,气候背景以及地形地貌特点和植物地理学,植物区系学,植物进化论等方面的综合分析,提出西藏高原是世界白菜型油菜起源地的观点。     

Genetic and geographic polymorphism of cultivated tobaccos (Nicotiana tabacum) in Turkey

Nicotiana tabacum (2n = 48) is a natural amphidiploid and shows a distribution over a geographical area in eastern anatolia. Random amplified polymorphic DNA (RAPD) technique was used to evaluate both genetic diversity among 21 primitive tobacco accessions comparing flue cure virginia genotype (FCV) and their geographical polymorphism as a source of genetic variations for breeding programs. Only 13 of all the 60 random primers used in RAPD showed polymorphism acceptable for characterization of these accessions. Totally 118 RAPD fragments were generated from thirteen decamer primer and sixtyfour of them were found polymorphic (54.2%). Mus and FCV showed the smallest genetic distance among accessions cultivated in the eastern anatolia. These results shows that the RAPD assay is a powerful approach for identifying genetic and geographic polymorphism.     

Genetic isolation by distance in Arabidopsis thaliana: biogeography and postglacial colonization of Europe

Arabidopsis thaliana provides a useful model system for functional, evolutionary and ecological studies in plant biology. We have analysed natural genetic variation in A. thaliana in order to infer its biogeographical and historical distribution across Eurasia. We analysed 79 amplified fragment length polymorphism (AFLP) markers in 142 accessions from the species' native range, and found highly significant genetic isolation by distance among A. thaliana accessions from Eurasia and southern Europe. These spatial patterns of genetic variation suggest that A. thaliana colonized central and northern Europe from Asia and from Mediterranean Pleistocene refugia, a trend which has been identified in other species. Statistically significant levels of multilocus linkage disequilibrium suggest intermediate levels of disequilibrium among subsets of loci, and analysis of genetic relationships among accessions reveal a star or bush-like dendrogram with low bootstrap support. Taken together, it appears that there has been sufficient historical recombination in the A. thaliana genome such that accessions do not conform to a tree-like, bifurcating pattern of evolution - there is no 'ecotype phylogeny.' Nonetheless, significant isolation by distance provides a framework upon which studies of natural variation in A. thaliana may be designed and interpreted.     

Chloroplast DNA indicates a single origin of the allotetraploid Arabidopsis suecica

DNA sequencing was performed on up to 12 chloroplast DNA regions [giving a total of 4288 base pairs (bp) in length] from the allopolyploid Arabidopsis suecica (48 accessions) and its two parental species, A. thaliana (25 accessions) and A. arenosa (seven accessions). Arabidopsis suecica was identical to A. thaliana at all 93 sites where A. thaliana and A. arenosa differed, thus showing that A. thaliana is the maternal parent of A. suecica. Under the assumption that A. thaliana and A. arenosa separated 5 million years ago, we estimated a substitution rate of 2.9 x 10(-9) per site per year in noncoding single copy sequence. Within A. thaliana we found 12 substitution (single bp) and eight insertion/deletion (indel) polymorphisms, separating the 25 accessions into 15 haplotypes. Eight of the A. thaliana accessions from central Sweden formed one cluster, which was separated from a cluster consisting of central European and extreme southern Swedish accessions. This latter cluster also included the A. suecica accessions, which were all identical except for one 5 bp indel. We interpret this low level of variation as a strong indication that A. suecica effectively has a single origin, which we dated at 20 000 years ago or more.     

The disease resistance gene Dm3 is infrequent in natural populations of Lactuca serriola due to deletions and frequent gene conversions at the RGC2 locus

Resistance genes can exhibit heterogeneous patterns of variation. However, there are few data on their frequency and variation in natural populations. We analysed the frequency and variation of the resistance gene Dm3, which confers resistance to Bremia lactucae (downy mildew) in 1033 accessions of Lactuca serriola (prickly lettuce) from 49 natural populations. Inoculations with an isolate of Bremia lactucae carrying avirulence gene Avr3 indicated that the frequency of Dm3 in natural populations of L. serriola was very low. Molecular analysis demonstrated that Dm3 was present in only one of the 1033 wild accessions analysed. The sequence of the 5' region of Dm3 was either highly conserved among accessions, or absent. In contrast, frequent chimeras were detected in the 3' leucine-rich repeat-encoding region. Therefore low frequency of the Dm3 specificity in natural populations was due to either the recent evolution of Dm3 specificity, or deletions of the whole gene as well as variation in 3' region caused by frequent gene conversions. This is the most extensive analysis of the prevalence of a known disease resistance gene to date, and indicates that the total number of resistance genes in a species may be very high. This has implications for the scales of germplasm conservation and exploitation of sources of resistance.     

DNA fingerprinting and new tools for fine-scale discrimination of Arabidopsis thaliana accessions

One of the main strengths of Arabidopsis thaliana as a model species is the impressive number of public resources available to the scientific community. Exploring species genetic diversity--and therefore adaptation--relies on collections of individuals from natural populations taken from diverse environments. Nevertheless, due to a few mislabeling events or genotype mixtures, some variants available in stock centers have been misidentified, causing inconsistencies and limiting the potential of genetic analyses. To improve the identification of natural accessions, we genotyped 1311 seed stocks from our Versailles Arabidopsis Stock Center and from other collections to determine their molecular profiles at 341 single nucleotide polymorphism markers. These profiles were used to compare genotypes at both the intra- and inter-accession levels. We confirmed previously described inconsistencies and revealed new ones, and suggest likely identities for accessions whose lineage had been lost. We also developed two new tools: a minimal fingerprint computation to quickly verify the identity of an accession, and an optimized marker set to assist in the identification of unknown or mixed accessions. These tools are available on a dedicated web interface called ANATool (https://www.versailles.inra.fr/ijpb/crb/anatool) that provides a simple and efficient means to verify or determine the identity of A. thaliana accessions in any laboratory, without the need for any specific or expensive technology.     

1,135 ionomes reveal the global pattern of leaf and seed mineral nutrient and trace element diversity in Arabidopsis thaliana

Soil is a heterogeneous reservoir of essential elements needed for plant growth and development. Plants have evolved mechanisms to balance their nutritional needs based on availability of nutrients. This has led to genetically based variation in the elemental composition, the ‘ionome’, of plants, both within and between species. We explore this natural variation using a panel of wild-collected, geographically widespread Arabidopsis thaliana accessions from the 1001 Genomes Project including over 1,135 accessions, and the 19 parental accessions of the Multi-parent Advanced Generation Inter-Cross (MAGIC) panel, all with full-genome sequences available. We present an experimental design pipeline for high-throughput ionomic screenings and analyses with improved normalisation procedures to account for errors and variability in conditions often encountered in large-scale, high-throughput data collection. We report quantification of the complete leaf and seed ionome of the entire collection using this pipeline and a digital tool, Ion Explorer , to interact with the dataset. We describe the pattern of natural ionomic variation across the A. thaliana species and identify several accessions with extreme ionomic profiles. It forms a valuable resource for exploratory genetic mapping studies to identify genes underlying natural variation in leaf and seed ionome and genetic adaptation of plants to soil conditions.     

Validation of molecular markers linked to apospory in tetraploid races of bahiagrass, Paspalum notatum Flüggé

Tetraploid (2n = 4x = 40) races of Paspalum notatum Flüggé are important natural forage grasses for the tropical and subtropical areas of the Americas. Almost all natural accessions reproduce by obligate aposporous apomixis. Previous work on the species allowed the identification of several molecular markers completely linked to apospory, one component of apomictic reproduction. Moreover, after a fingerprinting characterization of a germplasm collection, 11 amplified fragment length polymorphism (AFLP) markers exclusive to apomictic accessions were detected. The objectives of this work were (1) to validate the presence of molecular markers linked to apospory in tetraploid races of different geographic origins, (2) to determine if markers specific to apomictic accessions were associated with the mode of reproduction, and (3) to develop single-locus markers of apospory that can be used for marker-assisted selection. Thirteen natural apomictic accessions were analyzed. Moreover, the parental plants Q4188 (non-aposporous) and Q4117 (aposporous) and 44 F1 progenies (36 non-aposporous, 8 aposporous) derived from them were used as a validation population. Nine markers [two random amplification of polymorphic DNA (RAPD) and seven AFLP] 100% linked to apospory in Q4117 were tested. Amplification reactions with the corresponding primers showed that all markers were present in the 13 aposporous (apomictic) accessions, but were absent in the non-aposporous controls. On the other hand, linkage analysis of the 11 AFLP markers specific to the apomictic accessions showed that all of them were linked in coupling to apospory (r = 0.00, LOD 13.245). Based on one AFLP (E36M37c), two sequence characterized amplification region (SCAR) markers (SPNA1 and SPNA2) co-segregating with the trait and present in the 13 apomictic accessions were developed. The presence of markers associated with apospory was conserved among tetraploid accessions of different geographic origins. Moreover, the single-locus markers SPNA1 and SPNA2 could be used for routine marker-assisted selection in hybrid populations segregating for apospory and to facilitate the isolation of apospory-related genes.