Theoretical enzyme design using the Kepler scientific workflows on the Grid | Zendy

Jianwu Wang | Zendy; Prakashan Korambath | Zendy; Seonah Kim | Zendy; S.A. Johnson | Zendy; Kejian Jin | Zendy; Daniel Crawl | Zendy; İlkay Altıntaş | Zendy; Shava Smallen | Zendy; Bill Labate | Zendy; K. N. Houk | Zendy

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Theoretical enzyme design using the Kepler scientific workflows on the Grid

Author(s) -

Jianwu Wang,

Prakashan Korambath,

Seonah Kim,

S.A. Johnson,

Kejian Jin,

Daniel Crawl,

İlkay Altıntaş,

Shava Smallen,

Bill Labate,

K. N. Houk

Publication year - 2010

Publication title -

procedia computer science

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 0.334

H-Index - 76

ISSN - 1877-0509

DOI - 10.1016/j.procs.2010.04.131

Subject(s) - computer science , workflow , workflow management system , workflow technology , grid , reuse , grid computing , workflow engine , distributed computing , process (computing) , software engineering , database , operating system , ecology , geometry , mathematics , biology

One of the greatest challenges in computational chemistry is the design of enzymes to catalyze non-natural chemical reactions. We focus on harnessing the distributed parallel computational power of the Grid to automate the inside-out process of enzyme design using scientific workflow systems. This paper presents a scientific workflow based approach to facilitate the inside-out enzyme design process in the Grid execution environment by providing features such as resource consolidation, task parallelism, provenance tracking, fault tolerance and workflow reuse, which results in an automated, pipelined, efficient, extensible, stable, and easy-to-use computational process for enzyme design

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