| 000 -LEADER |
|---|
| fixed length control field |
07432nam a22003497a 4500 |
| 003 - CONTROL NUMBER IDENTIFIER |
|---|
| control field |
APU |
| 005 - DATE AND TIME OF LATEST TRANSACTION |
|---|
| control field |
20221031160241.0 |
| 008 - FIXED-LENGTH DATA ELEMENTS--GENERAL INFORMATION |
|---|
| fixed length control field |
210804s2017 nyua fob 000 0deng d |
| 010 ## - LIBRARY OF CONGRESS CONTROL NUMBER |
|---|
| LC control number |
2018302854 |
| 020 ## - INTERNATIONAL STANDARD BOOK NUMBER |
|---|
| International Standard Book Number |
9781970001549 (epub) |
| 020 ## - INTERNATIONAL STANDARD BOOK NUMBER |
|---|
| International Standard Book Number |
9781970001532 (pdf) |
| 035 ## - SYSTEM CONTROL NUMBER |
|---|
| System control number |
(OCoLC)ocn990288882 |
| 040 ## - CATALOGING SOURCE |
|---|
| Original cataloging agency |
BTCTA |
| Language of cataloging |
eng |
| Transcribing agency |
APU |
| Modifying agency |
SF |
| 042 ## - AUTHENTICATION CODE |
|---|
| Authentication code |
lccopycat |
| 050 00 - LIBRARY OF CONGRESS CALL NUMBER |
|---|
| Classification number |
QP551.5 |
| Item number |
.S75 2017eb |
| 082 00 - DEWEY DECIMAL CLASSIFICATION NUMBER |
|---|
| Classification number |
572/.64 |
| Edition number |
23 |
| 100 1# - MAIN ENTRY--PERSONAL NAME |
|---|
| Personal name |
Srihari, Sriganesh, |
| 9 (RLIN) |
47425 |
| 245 10 - TITLE STATEMENT |
|---|
| Title |
Computational prediction of protein complexes from protein interaction networks |
| Medium |
[electronic resource] / |
| Statement of responsibility, etc |
Sriganesh Srihari , Chern Han Yong , Limsoon Wong. |
| 260 ## - PUBLICATION, DISTRIBUTION, ETC. (IMPRINT) |
|---|
| Place of publication, distribution, etc |
[New York] : |
| Name of publisher, distributor, etc |
Association for Computing Machinery ; |
| 260 ## - PUBLICATION, DISTRIBUTION, ETC. (IMPRINT) |
|---|
| Place of publication, distribution, etc |
[San Rafael] : |
| Name of publisher, distributor, etc |
Morgan & Claypool Publishers, |
| Date of publication, distribution, etc |
c2017. |
| 300 ## - PHYSICAL DESCRIPTION |
|---|
| Extent |
1 online resource (xiv, 775 pages) ; |
| Other physical details |
illustrations. |
| 490 1# - SERIES STATEMENT |
|---|
| Series statement |
ACM books series, |
| International Standard Serial Number |
2374-6769 ; |
| Volume number/sequential designation |
#16 |
| 504 ## - BIBLIOGRAPHY, ETC. NOTE |
|---|
| Bibliography, etc |
Includes bibliographical references (pages 233-278). |
| 505 ## - FORMATTED CONTENTS NOTE |
|---|
| Formatted contents note |
1. Introduction to protein complex prediction -- 1.1 From protein interactions to protein complexes -- 1.2 Databases for protein complexes -- 1.3 Organization of the rest of the book -- 2. Constructing reliable protein-protein interaction (PPI) networks -- 2.1 High-throughput experimental systems to infer PPIs -- 2.2 Data sources for PPIs -- 2.3 Topological properties of PPI networks -- 2.4 Theoretical models for PPI networks -- 2.5 Visualizing PPI networks -- 2.6 Building high-confidence PPI networks -- 2.7 Enhancing PPI networks by integrating functional interactions -- 3. Computational methods for protein complex prediction from PPI networks -- 3.1 Basic definitions and terminologies -- 3.2 Taxonomy of methods for protein complex prediction -- 3.3 Methods based solely on PPI network clustering -- 3.4 Methods incorporating core-attachment structure -- 3.5 Methods incorporating functional information -- 4. Evaluating protein complex prediction methods -- 4.1 Evaluation criteria and methodology -- 4.2 Evaluation on unweighted yeast PPI networks -- 4.3 Evaluation on weighted yeast PPI networks -- 4.4 Evaluation on human PPI networks -- 4.5 Case study: prediction of the human mechanistic target of Rapamycin complex -- 4.6 Take-home lessons from evaluating prediction methods -- 5. Open challenges in protein complex prediction -- 5.1 Three main challenges in protein complex prediction -- 5.2 Identifying sparse protein complexes -- 5.3 Identifying overlapping protein complexes -- 5.4 Identifying small protein complexes -- 5.5 Identifying protein sub-complexes -- 5.6 An integrated system for identifying challenging protein complexes -- 5.7 Recent methods for protein complex prediction -- 5.8 Identifying membrane-protein complexes -- 6. Identifying dynamic protein complexes -- 6.1 Dynamism of protein interactions and protein complexes -- 6.2 Identifying temporal protein complexes -- 6.3 Intrinsic disorder in proteins -- 6.4 Intrinsic disorder in protein interactions and protein complexes -- 6.5 Identifying fuzzy protein complexes -- 7. Identifying evolutionarily conserved protein complexes -- 7.1 Inferring evolutionarily conserved PPIs (interologs) -- 7.2 Identifying conserved complexes from interolog networks, I -- 7.3 Identifying conserved complexes from interolog networks, II -- 8. Protein complex prediction in the era of systems biology -- 8.1 Constructing the network of protein complexes -- 8.2 Identifying protein complexes across phenotypes -- 8.3 Identifying protein complexes in diseases -- 8.4 Enhancing quantitative proteomics using PPI networks and protein complexes -- 8.5 Systems biology tools and databases to analyze biomolecular networks -- 9. Conclusion -- References -- Authors' biographies. |
| 520 ## - SUMMARY, ETC. |
|---|
| Summary, etc |
Complexes of physically interacting proteins constitute fundamental functional units that drive almost all biological processes within cells. A faithful reconstruction of the entire set of protein complexes (the “complexosome”) is therefore important not only to understand the composition of complexes but also the higher level functional organization within cells. Advances over the last several years, particularly through the use of high-throughput proteomics techniques, have made it possible to map substantial fractions of protein interactions (the “interactomes”) from model organisms including Arabidopsis thaliana (a flowering plant), Caenorhabditis elegans (a nematode), Drosophila melanogaster (fruit fly), and Saccharomyces cerevisiae (budding yeast). These interaction datasets have enabled systematic inquiry into the identification and study of protein complexes from organisms. Computational methods have played a significant role in this context, by contributing accurate, efficient, and exhaustive ways to analyze the enormous amounts of data. These methods have helped to compensate for some of the limitations in experimental datasets including the presence of biological and technical noise and the relative paucity of credible interactions. In this book, we systematically walk through computational methods devised to date (approximately between 2000 and 2016) for identifying protein complexes from the network of protein interactions (the protein-protein interaction (PPI) network). We present a detailed taxonomy of these methods, and comprehensively evaluate them for protein complex identification across a variety of scenarios including the absence of many true interactions and the presence of false-positive interactions (noise) in PPI networks. Based on this evaluation, we highlight challenges faced by the methods, for instance in identifying sparse, sub-, or small complexes and in discerning overlapping complexes, and reveal how a combination of strategies is necessary to accurately reconstruct the entire complexosome. The experience gained from studying model organisms has immensely helped in mapping of interactions and identifying protein complexes from higher-order organisms including Homo sapiens (human) and other mammals. In particular, with the increasing use of “phenomics” techniques spanning genomics, transcriptomics, and proteomics to map human cells across multiple layers of functional organization, the need to understand the basis of rewiring of the interactome (e.g., as a result of changes to the genome), and the resulting recomposition of protein complexes, is gaining immense importance. Toward this end, recent computational methods have integrated panomics datasets to assess interactome rewiring and to track complexes across conditions (e.g., between normal development and disease). These efforts have revealed valuable insights into dysregulated cellular processes, and highlighted molecular targets for therapeutic intervention in diseases including cancer. By discussing these approaches in depth, we emphasize how tackling a fundamental problem such as protein complex prediction (PCP) can have far-reaching applications in understanding the biology underpinning physiological and environmental transformations affecting cells.<br/> |
| 650 #0 - SUBJECT ADDED ENTRY--TOPICAL TERM |
|---|
| Topical term or geographic name as entry element |
Protein-protein interactions |
| General subdivision |
Computer simulation. |
| 9 (RLIN) |
47426 |
| 700 1# - ADDED ENTRY--PERSONAL NAME |
|---|
| Personal name |
Yong, Chern Han, |
| 9 (RLIN) |
47427 |
| 700 1# - ADDED ENTRY--PERSONAL NAME |
|---|
| Personal name |
Wong, Limsoon, |
| Dates associated with a name |
1965- |
| 9 (RLIN) |
47428 |
| 830 #0 - SERIES ADDED ENTRY--UNIFORM TITLE |
|---|
| Uniform title |
ACM books ; |
| Volume number/sequential designation |
#16. |
| 9 (RLIN) |
47379 |
| 856 ## - ELECTRONIC LOCATION AND ACCESS |
|---|
| Materials specified |
ACM Digital Library. |
| Uniform Resource Identifier |
https://dl-acm-org.ezproxy.apiit.edu.my/doi/book/10.1145/3064650 |
| Public note |
Available in ACM Digital Library. |
| 942 ## - ADDED ENTRY ELEMENTS (KOHA) |
|---|
| Source of classification or shelving scheme |
|
| Koha item type |
E-Book |
