The origin and evolution of a recent agricultural weed: population genetic diversity of weedy populations of sunflower (Helianthus annuus L.) in Spain and France

The recurrent evolution of crop-related weeds during agricultural history raises serious economic problems and challenging scientific questions. Weedy forms of sunflower, a species native from America, have been reported in European sunflower fields for a few decades. In order to understand their origin, we analysed the genetic diversity of a sample of weedy populations from France and Spain, and of conventional and ornamental varieties. A crop-specific maternally inherited marker was present in all weeds. At 16 microsatellite loci, the weedy populations shared most of their diversity with the conventional varieties. But they showed a large number of additional alleles absent from the cultivated pool. European weedy populations thus most probably originated from the unintentional pollination of maternal lines in seed production fields by wild plants growing nearby, resulting in the introduction of crop-wild hybrids into the farmers’ fields. The wide diversity and the low population structure detected were indicative of a multiplicity of introductions events rather than of field-to-field propagation. Further studies are required to understand the local evolutionary dynamics of a weedy population, and especially the respective roles of crop-to-weed gene flow and selection in the fate of an initial source of crop-wild hybrids

A small XY chromosomal region explains sex determination in wild dioecious V. vinifera and the reversal to hermaphroditism in domesticated grapevines

Publis014-agap-029Background In Vitis vinifera L., domestication induced a dramatic change in flower morphology: the wild sylvestris subspecies is dioecious while hermaphroditism is largely predominant in the domesticated subsp. V. v. vinifera. The characterisation of polymorphisms in genes underlying the sex-determining chromosomal region may help clarify the history of domestication in grapevine and the evolution of sex chromosomes in plants. In the genus Vitis, sex determination is putatively controlled by one major locus with three alleles, male M, hermaphrodite H and female F, with an allelic dominance M > H > F. Previous genetic studies located the sex locus on chromosome 2. We used DNA polymorphisms of geographically diverse V. vinifera genotypes to confirm the position of this locus, to characterise the genetic diversity and traces of selection in candidate genes, and to explore the origin of hermaphroditism. Results In V. v. sylvestris, a sex-determining region of 154.8 kb, also present in other Vitis species, spans less than 1% of chromosome 2. It displays haplotype diversity, linkage disequilibrium and differentiation that typically correspond to a small XY sex-determining region with XY males and XX females. In male alleles, traces of purifying selection were found for a trehalose phosphatase, an exostosin and a WRKY transcription factor, with strikingly low polymorphism levels between distant geographic regions. Both diversity and network analysis revealed that H alleles are more closely related to M than to F alleles. Conclusions Hermaphrodite alleles appear to derive from male alleles of wild grapevines, with successive recombination events allowing import of diversity from the X into the Y chromosomal region and slowing down the expansion of the region into a full heteromorphic chromosome. Our data are consistent with multiple domestication events and show traces of introgression from other Asian Vitis species into the cultivated grapevine gene pool. La vigne domestiquée, Vitis vinifera ssp. vinifera, cultivée pour la production de fruit et de vin à travers le monde, dérive de la vigne sauvage, Vitis vinifera ssp. sylvestris, sous-espèce endémique de l'Eurasie. Au cours de la domestication, le système de reproduction a évolué de la diécie à l'hermaphrodisme. Nous montrons que la région du sexe est sous le contrôle d'une région chromosomique qui couvre au maximum 154kpbp, moins de 1% du chromosome 2. La caractérisation de ce locus en terme de diversité haplotypique, de signature de sélection et de déséquilibre de liaison a permis de révéler un système de détermination sexuelle de type XY. La petite taille de cette région chromosomique semble indiquer un stade très précoce dans l'évolution de chromosomes sexuels, malgré que la diécie soit le trait ancestral chez toutes les espèces de Vitis, ayant divergé du sous-genre Muscadinia il y a plusieurs millions d'années. L'analyse des distances génétiques entre haplotypes dans le locus du sexe a révélé que l'hermaphrodisme observé chez la vigne domestiquée résulte de la mutation de l'allèle mâle présent chez la vigne sauvage. Le réseau d'haplotypes a montré qu'en plus de la contribution de V. sylvestris, une autre espèce de Vitis asiatique a pu contribuer à la constitution du génome actuel de la vigne cultivée moderne. Ces travaux résultent d'une collaboration entre l'équipe DAAV d'AGAP et l'UMR CBAE (Montpellier)

Flowering phenology and hybridization rates between cultivated varieties and weedy populations of sunflower in France

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How to escape from crop-to-weed gene flow: phenological variation and isolation-by-time within weedy sunflower populations.

AGAP : équipe Génomique évolutive et gestion des populations (GE²pop)The evolution of crop-related weeds may be constrained by recurrent gene flow from the crop. However, flowering time variation within weedy populations may open the way for weed adaptation by allowing some weeds to escape from this constraint. We investigated this link between phenology, gene flow and adaptation in weedy sunflower populations that have recently emerged in Europe from crop-wild hybridization. We studied jointly flowering phenology and genetic diversity for 15 microsatellite loci in six cultivated sunflower (Helianthus annuus) fields infested by weedy sunflower populations. The flowering overlap of cultivated and weedy sunflowers varied between and within populations: some weedy individuals were found to be completely isolated from the crop, the frequency of these plants being higher in populations from highly infested fields. Within weedy populations, we detected a pattern of isolation-by-time: the genetic divergence between individuals was positively correlated with their divergence in flowering period. In addition, earlier weeds, which flowered synchronously with the crop, were genetically more similar than late-flowering weeds to the cultivated varieties. Overall, our results suggest that crop-to-weed gene flow occurred, but was limited by divergent phenologies. We discuss the roles of weed adaptation and population history in the generation of this partial reproductive isolation

Phenotypic_data

The excel file has both the data (one worksheet for the weedy population, one worksheet for phenological data of cultivated fields), and a worksheet explaining each of the columns/fields

Genetic_data

Genotypic data for 13 microsatellites for the cultivated variety, a sample of the weedy population and its offspring; missing data coded as N

Data from: How to escape from crop-to-weed gene flow: phenological variation and isolation-by-time within weedy sunflower populations

The evolution of crop-related weeds may be constrained by recurrent gene flow from the crop. However, flowering time variation within weedy populations may open the way for weed adaptation by allowing some weeds to escape from this constraint. We investigated this link between phenology, gene flow and adaptation in weedy sunflower populations recently emerged in Europe from crop-wild hybridization. We studied jointly flowering phenology and genetic diversity for 15 microsatellite loci in six cultivated sunflower fields infested by weedy sunflower populations. The flowering overlap of cultivated and weedy sunflowers varied between and within populations: some weedy individuals were found completely isolated from the crop, the frequency of these plants being higher in populations from highly infested fields. Within weedy populations, we detected a pattern of isolation-by-time: the genetic divergence between individuals was positively correlated with their divergence in flowering period. Additionally, earlier weeds, which flowered synchronously with the crop, were genetically more similar to the cultivated varieties than late-flowering weeds. Overall our results suggest that crop-to-weed gene flow did occur but was limited by divergent phenologies. We discuss the roles of weed adaptation and population history in generating this partial reproductive isolation

Preferential helping to relatives: A potential mechanism responsible for lower yield of crop variety mixtures?

International audienceVariety mixtures, the cultivation of different genotypes within a field, have been proposed as a way to increase within‐crop diversity, allowing the development of more sustainable agricultural systems with reduced environmental costs. Although mixtures have often been shown to over‐yield the average of component varieties in pure stands, decreased yields in mixtures have also been documented. Kin selection may explain such pattern, whenever plants direct helping behaviors preferentially toward relatives and thus experience stronger competition when grown with less related neighbors, lowering seed production of mixtures. Using varieties of durum wheat originating from traditional Moroccan agrosystems, we designed a greenhouse experiment to address whether plants reduced competition for light by limiting stem elongation when growing with kin, and whether such phenotypic response resulted in higher yield of kin groups. Seeds were sown in groups of siblings and non‐kin, each group containing a focal plant surrounded by four neighbors. At the group level, mean plant height and yield did not depend upon relatedness among competing plants. At the individual level, plant height was not affected by genetic relatedness to neighbors, after accounting for direct genetic effects that might induce among‐genotype differences in the ability to capture resources that do not depend on relatedness. Moreover, in contrast to our predictions, shorter plants had lower inclusive fitness. Phenotypic plasticity in height was very limited in response to neighbor genotypes. This suggests that human selection in crops may have attenuated shade‐avoidance responses to competition for light. Future research on preferential helping to relatives in crops might thus target social traits that drive competition for other resources than light. Overall, our study illustrates the relevance of tackling agricultural issues from an evolutionary standpoint, and calls for extending such approaches to a larger set of crop species

Genotype mixtures as a tool to develop sustainable agriculture? Elucidating the mechanisms that drive genotypic interactions in crops

National audienc

Kin recognition in crops as a possible mechanism for explaining lower yield of variety mixtures

National audienc