The impact of structural genomics: the first quindecennial
作者: Marek Grabowski , Ewa Niedzialkowska , Matthew D. Zimmerman , Wladek Minor
DOI: 10.1007/S10969-016-9201-5
关键词: Scientific experiment 、 Structural genomics 、 Data collection 、 Data science 、 Genomics 、 Biology 、 Nanotechnology 、 Scientific literature 、 Workflow
摘要: The period 2000-2015 brought the advent of high-throughput approaches to protein structure determination. With overall funding on order $2 billion (in 2010 dollars), structural genomics (SG) consortia established worldwide have developed pipelines for target selection, production, sample preparation, crystallization, and determination by X-ray crystallography NMR. These efforts resulted in over 13,500 structures, mostly from unique families, increased coverage expanding universe. SG programs contributed 4400 publications scientific literature. NIH-funded Protein Structure Initiatives alone produced 2000 publications, which date attracted more than 93,000 citations. Software database developments that were necessary handle workflows led structures better quality improved integrity associated data. Organized accessible data a positive impact reproducibility experiments. Most experimental generated centers are freely available community has been utilized scientists various fields research. projects created, improved, streamlined, validated many protocols production collection, functional analysis, significantly benefiting biological biomedical
springer.com
sci-hub.se 参考文章(91)
Tracey L. Musa, Thomas R. Ioerger, James C. Sacchettini, The tuberculosis structural genomics consortium: a structural genomics approach to drug discovery. Advances in Protein Chemistry. ,vol. 77, pp. 41- 76 ,(2009) , 10.1016/S1876-1623(09)77003-8
Leonard P. Freedman, Iain M. Cockburn, Timothy S. Simcoe, The Economics of Reproducibility in Preclinical Research PLOS Biology. ,vol. 13, pp. 1- 9 ,(2015) , 10.1371/JOURNAL.PBIO.1002165
Kamil Khafizov, Maxim V. Ivanov, Olga V. Glazova, Sergei P. Kovalenko, Computational approaches to study the effects of small genomic variations Journal of Molecular Modeling. ,vol. 21, pp. 251- 251 ,(2015) , 10.1007/S00894-015-2794-Y
William H. Eschenfeldt, Stols Lucy, Cynthia Sanville Millard, Andrzej Joachimiak, I. Donnelly Mark, A Family of LIC Vectors for High-Throughput Cloning and Purification of Proteins Methods of Molecular Biology. ,vol. 498, pp. 105- 115 ,(2009) , 10.1007/978-1-59745-196-3_7
Zsolt Zolnai, Peter T. Lee, Jing Li, Michael R. Chapman, Craig S. Newman, George N. Phillips Jr., Ivan Rayment, Eldon L. Ulrich, Brian F. Volkman, John L. Markley, Project management system for structural and functional proteomics: Sesame. Journal of Structural and Functional Genomics. ,vol. 4, pp. 11- 23 ,(2003) , 10.1023/A:1024684404761
Dennis Vitkup, Eugene Melamud, John Moult, Chris Sander, Completeness in structural genomics. Nature Structural & Molecular Biology. ,vol. 8, pp. 559- 566 ,(2001) , 10.1038/88640
Peter J Brown, Susanne Müller, Open access chemical probes for epigenetic targets. Future Medicinal Chemistry. ,vol. 7, pp. 1901- 1917 ,(2015) , 10.4155/FMC.15.127
, , , , , , , , , , , , , , Protein production and purification. Nature Methods. ,vol. 5, pp. 135- 146 ,(2008) , 10.1038/NMETH.F.202
Steven C Almo, Scott J Garforth, Brandan S Hillerich, James D Love, Ronald D Seidel, Stephen K Burley, Protein production from the structural genomics perspective: achievements and future needs Current Opinion in Structural Biology. ,vol. 23, pp. 335- 344 ,(2013) , 10.1016/J.SBI.2013.02.014
David Lee, Alastair Grant, Russell L. Marsden, Christine Orengo, Identification and distribution of protein families in 120 completed genomes using Gene3D Proteins: Structure, Function, and Bioinformatics. ,vol. 59, pp. 603- 615 ,(2005) , 10.1002/PROT.20409