Yazar "Greenlon, Alex" seçeneğine göre listele

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    Ecology and genomics of an important crop wild relative as a prelude to agricultural innovation
    (Nature Publishing Group, 2018) Von Wettberg, Eric J.B.; Chang, Peter L.; Başdemir, Fatma; Carrasquila-Garcia, Noelia; Korbu, Lijalem Balcha; Moenga, Susan M.; Bedada, Gashaw; Greenlon, Alex; Moriuchi, Ken S.; Singh, Vasantika; Cordeiro, Matilde A.; Noujdina, Nina V.; Dinegde, Kassaye Negash; Shah Sani, Syed Gul Abbas; Getahun, Tsegaye; Vance, Lisa; Bergmann, Emily; Lindsay, Donna; Mamo, Bullo Erena; Warschefsky, Emily J.; Dacosta-Calheiros, Emmanuel; Marques, Edward; Yılmaz, Mustafa Abdullah; Çakmak, Ahmet; Rose, Janna; Migneault, Andrew; Krieg, Christopher P.; Saylak, Sevgi; Temel, Hamdi; Friesen, Maren L.; Siler, Eleanor; Akhmetov, Zhaslan; Özçelik, Hüseyin; Kholova, Jana; Can, Canan; Gaur, Pooran; Yıldırım, Mehmet; Sharma, Hari; Vadez, Vincent; Tesfaye, Kassahun; Woldemedhin, Asnake Fikre; Tar'An, Bunyamin; Aydoğan, Abdulkadir; Bükün, Bekir; Penmetsa, R. Varma; Berger, Jens; Kahraman, Abdullah; Nuzhdin, Sergey V.; Cook, Douglas R.
    Domesticated species are impacted in unintended ways during domestication and breeding. Changes in the nature and intensity of selection impart genetic drift, reduce diversity, and increase the frequency of deleterious alleles. Such outcomes constrain our ability to expand the cultivation of crops into environments that differ from those under which domestication occurred. We address this need in chickpea, an important pulse legume, by harnessing the diversity of wild crop relatives. We document an extreme domestication-related genetic bottleneck and decipher the genetic history of wild populations. We provide evidence of ancestral adaptations for seed coat color crypsis, estimate the impact of environment on genetic structure and trait values, and demonstrate variation between wild and cultivated accessions for agronomic properties. A resource of genotyped, association mapping progeny functionally links the wild and cultivated gene pools and is an essential resource chickpea for improvement, while our methods inform collection of other wild crop progenitor species.
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    Global-level population genomics reveals differential effects of geography and phylogeny on horizontal gene transfer in soil bacteria
    (National Academy of Sciences, 2019) Greenlon, Alex; Chang, Peter L.; Damtew, Zehara Mohammed; Muleta, Atsede; Garcia, Noelia Carrasquilla; Kim, Donghyun; Nguyen, Hien P.; Suryawanshi, Vasantika; Krieg, Christopher P.; Yadav, Sudheer Kumar; Patel, Jai Singh; Mukherjee, Arpan; Udupa, Sripada Mahabala; Benjelloun, Imane; Alami, Imane Thami; Yasin, Mohammad; Patil, Bhuvaneshwara; Singh, Sarvjeet P.; Sarma, Birinchi Kumar; Bishop Von Wettberg, Eric J.; Kahraman, Abdullah; Bükün, Bekir; Assefa, Fassil; Tesfaye, Kassahun; Fikre, Asnake; Cook, Douglas R.
    Although microorganisms are known to dominate Earth’s biospheres and drive biogeochemical cycling, little is known about the geographic distributions of microbial populations or the environmental factors that pattern those distributions. We used a global-level hierarchical sampling scheme to comprehensively characterize the evolutionary relationships and distributional limitations of the nitrogen-fixing bacterial symbionts of the crop chickpea, generating 1,027 draft whole-genome sequences at the level of bacterial populations, including 14 high-quality PacBio genomes from a phylogenetically representative subset. We find that diverse Mesorhizobium taxa perform symbiosis with chickpea and have largely overlapping global distributions. However, sampled locations cluster based on the phylogenetic diversity of Mesorhizobium populations, and diversity clusters correspond to edaphic and environmental factors, primarily soil type and latitude. Despite long-standing evolutionary divergence and geographic isolation, the diverse taxa observed to nodulate chickpea share a set of integrative conjugative elements (ICEs) that encode the major functions of the symbiosis. This symbiosis ICE takes 2 forms in the bacterial chromosome—tripartite and monopartite—with tripartite ICEs confined to a broadly distributed superspecies clade. The pairwise evolutionary relatedness of these elements is controlled as much by geographic distance as by the evolutionary relatedness of the background genome. In contrast, diversity in the broader gene content of Mesorhizobium genomes follows a tight linear relationship with core genome phylogenetic distance, with little detectable effect of geography. These results illustrate how geography and demography can operate differentially on the evolution of bacterial genomes and offer useful insights for the development of improved technologies for sustainable agriculture.