Institution
University of Georgia
Education•Athens, Georgia, United States•
About: University of Georgia is a education organization based out in Athens, Georgia, United States. It is known for research contribution in the topics: Population & Gene. The organization has 41934 authors who have published 93622 publications receiving 3713212 citations. The organization is also known as: UGA & Franklin College.
Topics: Population, Gene, Poison control, Context (language use), Genome
Papers published on a yearly basis
Papers
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Civil Aviation Authority of Singapore1, Rothamsted Research2, Beijing Institute of Genomics3, University of Copenhagen4, Rural Development Administration5, John Innes Centre6, University of Georgia7, North China University of Science and Technology8, University of California, Berkeley9, University of Missouri10, Australian Research Council11, University of Queensland12, National Research Council13, Bielefeld University14, Australian Centre for Plant Functional Genomics15, University of Rennes16, Wageningen University and Research Centre17, Agriculture and Agri-Food Canada18, Huazhong Agricultural University19, French Alternative Energies and Atomic Energy Commission20, Chungnam National University21, Norwich Research Park22
TL;DR: The annotation and analysis of the draft genome sequence of Brassica rapa accession Chiifu-401-42, a Chinese cabbage, and used Arabidopsis thaliana as an outgroup for investigating the consequences of genome triplication, such as structural and functional evolution.
Abstract: We report the annotation and analysis of the draft genome sequence of Brassica rapa accession Chiifu-401-42, a Chinese cabbage. We modeled 41,174 protein coding genes in the B. rapa genome, which has undergone genome triplication. We used Arabidopsis thaliana as an outgroup for investigating the consequences of genome triplication, such as structural and functional evolution. The extent of gene loss (fractionation) among triplicated genome segments varies, with one of the three copies consistently retaining a disproportionately large fraction of the genes expected to have been present in its ancestor. Variation in the number of members of gene families present in the genome may contribute to the remarkable morphological plasticity of Brassica species. The B. rapa genome sequence provides an important resource for studying the evolution of polyploid genomes and underpins the genetic improvement of Brassica oil and vegetable crops.
1,811 citations
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TL;DR: New developments in understanding pectin structure, function, and biosynthesis indicate that these polysaccharides have roles in both primary and secondary cell walls.
1,810 citations
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TL;DR: The view of critical questions regarding pectin structure, biosynthesis, and function that need to be addressed in the coming decade are presented and new methods that may be useful to study localized pectins in the plant cell wall are described.
1,795 citations
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TL;DR: The Self-Evaluation Maintenance (SEM) model as discussed by the authors is composed of two dynamic processes, the reflection process and the comparison process, which have as component variables the closeness of another and the quality of that other's performance, which interact in affecting self-evaluation but do so in quite opposite ways in each of the processes.
Abstract: Publisher Summary This chapter discusses social behavior through self-evaluation maintenance (SEM) model. It describes several studies to provide a feel for the kind of research that has been completed in an attempt to explore the predictions of the model. The SEM model is composed of two dynamic processes. Both the reflection process and the comparison process have as component variables the closeness of another and the quality of that other's performance. These two variables interact in affecting self-evaluation but do so in quite opposite ways in each of the processes Model establishes the comprehensiveness of the research and the interactive quality of its predictions. Next, the SEM model is fit into the perspective of related work, including self-theories, social comparison theory, and Cialdini's BIRGing research. The chapter reviews the epistemological status of the model. It discusses some of the implications of the research for a variety of areas in psychology.
1,787 citations
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Cornell University1, University of Maryland, College Park2, North Carolina State University3, University of Maryland Biotechnology Institute4, Harvard University5, University of Southern Mississippi6, Old Dominion University7, University of South Florida St. Petersburg8, Erasmus University Rotterdam9, University of Georgia10, University of South Carolina Aiken11
TL;DR: A dramatic global increase in the severity of coral bleaching in 1997-98 is coincident with high El Niño temperatures, which climate-mediated, physiological stresses may compromise host resistance and increase frequency of opportunistic diseases.
Abstract: Mass mortalities due to disease outbreaks have recently affected major taxa in the oceans. For closely monitored groups like corals and marine mammals, reports of the frequency of epidemics and the number of new diseases have increased recently. A dramatic global increase in the severity of coral bleaching in 1997—98 is coincident with high El Nino temperatures. Such climate-mediated, physiological stresses may compromise host resistance and increase frequency of opportunistic diseases. Where documented, new diseases typically have emerged through host or range shifts of known pathogens. Both climate and human activities may have also accelerated global transport of species, bringing together pathogens and previously unexposed host populations. T he oceans harbor enormous biodiver- sity by terrestrial terms (1), much of which is still poorly described taxo- nomically. Even less well known are the dy- namics of intermittent, ephemeral, threshold phenomena such as disease outbreaks. De- spite decades of intense study of the biolog- ical agents structuring natural communities, the ecological and evolutionary impact of diseases in the ocean remains unknown, even when these diseases affect economically and ecologically important species. The paucity of baseline and epidemiological information on normal disease levels in the ocean chal- lenges our ability to assess the novelty of a recent spate of disease outbreaks and to de- termine the relative importance of increased pathogen transmission versus decreased host resistance in facilitating the outbreaks. Our objectives here are to review the prevalence of diseases of marine taxa to evaluate wheth- er it can be concluded that there has been a recent increase. We also assess the contribut- ing roles of human activity and global cli- mate, and evaluate the role of the oceans as incubators and conveyors of human disease agents. Is There an Increase in Diseases in the Ocean?
1,778 citations
Authors
Showing all 42268 results
Name | H-index | Papers | Citations |
---|---|---|---|
Rob Knight | 201 | 1061 | 253207 |
Feng Zhang | 172 | 1278 | 181865 |
Zhenan Bao | 169 | 865 | 106571 |
Carl W. Cotman | 165 | 809 | 105323 |
Yoshio Bando | 147 | 1234 | 80883 |
Mark Raymond Adams | 147 | 1187 | 135038 |
Han Zhang | 130 | 970 | 58863 |
Dmitri Golberg | 129 | 1024 | 61788 |
Godfrey D. Pearlson | 128 | 740 | 58845 |
Douglas E. Soltis | 127 | 612 | 67161 |
Richard A. Dixon | 126 | 603 | 71424 |
Ajit Varki | 124 | 542 | 58772 |
Keith A. Johnson | 120 | 798 | 51034 |
Gustavo E. Scuseria | 120 | 658 | 95195 |
Julian I. Schroeder | 120 | 315 | 50323 |