Biological networks/Bibliography: Difference between revisions
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==Books== | |||
* Képès F. (editor) (2007) ''Biological networks.'' Volume 3 of Complex Systems and Interdisciplinary Science. World Scientific. ISBN 9789812706959. | [http://books.google.com/books?id=5pxnNbVs9MMC&dq=biological+networks&source=gbs_navlinks_s Google Books preview.] | |||
**<font face="Gill Sans MT">From Preface: In network models, the relevant components in a system are identified as nodes. The interactions between these components are represented as links between nodes. Following this abstraction step, it becomes possible to study the topological properties of the network thus obtained. The generality and uniformity of the network representation make it possible to compare systems of very different types. At present, pure and combined network-based approaches still present fascinating challenges with respect to topological properties, and to temporal and spatial development.</font> | |||
* Ross J, Schreiber I, Vlad MO; with contributions from Arkin A, Oefner PJ, Zamboni N. (2006) [http://tinyurl.com/yeme67m ''Determination of Complex Reaction Mechanisms: Analysis of Chemical, Biological, and Genetic Networks.''] Oxford University Press: New York. ISBN 978-0-19-517868-5. | [http://books.google.com/books?id=9oxZCW876A0C&dq=schreiber+reaction&source=gbs_navlinks_s Google books preview.] | [http://www.oup.com/us/catalog/general/subject/Chemistry/PhysicalChemistry/ChemicalKinetics/?view=usa&ci=9780195178685 Description of book, table of contents, author bio - OUP webpage.] | |||
**<font face="Gill Sans MT">Excerpt: We have seen that computations can be achieved by chemical and biochemical reaction mechanisms, and have located computational functions in biological reaction systems. This identification helps in understanding functions and control in such systems. It also helps in suggesting new approaches to the determination of causal connectivities of reacting species, of reaction pathways, and reaction mechanisms, by exploring analogs of investigations in electronics, system analysis [citations given], multivariate statistics [citations given], and other related disciplines. (From Chapter 4: Computations by Means of Macroscopic Chemical Kinetics.) | |||
**[http://www.oup.com/us/catalog/general/subject/Chemistry/PhysicalChemistry/ChemicalKinetics/?view=usa&ci=9780195178685 ...several systematic approaches for obtaining information on the causal connectivity of chemical species, on correlations of chemical species, on the reaction pathway, and on the reaction mechanism.]</font> | |||
* Barabasi A-L. (2002) ''Linked: The New Science of Networks''. Perseus Publishing: Cambridge, MA. ISBN 0-7382-0667-9. | [http://books.google.com/books?id=QTHsGNY4wcwC&dq=Linked&source=gbs_navlinks_s Google Books preview.] | |||
* Newman MEJ. (2010) [http://www.oup.com/us/catalog/general/subject/Physics/?view=usa&ci=9780199206650 ''Networks: an introduction'']. Oxford: Oxford University Press. ISBN 9780199206650. | [http://books.google.com/books?id=q7HVtpYVfC0C&dq=newman+networks&source=gbs_navlinks_s Google Books preview]. | |||
* Newman MEJ, Barabâasi AL, Watts DJ. (2006) ''The structure and dynamics of networks''. Princeton, N.J: Princeton University Press. | |||
* Watts DJ. (1999) ''Small worlds: the dynamics of networks between order and randomness''. Princeton, N.J: Princeton University Press, ISBN 0691005419 | |||
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<!--[http://books.google.com/books?id=vTVLh5xzJWIC&dq=linguistics+biology&source=gbs_navlinks_s Matthias Dehmer, Frank Emmert-Streib. Analysis of complex networks: from biology to linguistics].--> | |||
==Book Chapters== | |||
==Journal articles== | |||
* Weitz JS, Benfey PN, Wingreen NS. (2007) [http://dx.doi.org/10.1371/journal.pbio.0050011 Evolution, Interactions, and Biological Networks.] PLoS Biol 5(1): e11. | |||
**'''Excerpt:''' As [Theodosius] Dobzhansky famously noted, nothing in biology makes sense except in the light of evolution...This is particularly true of biological networks, and we believe that the lens of evolution provides an exciting opportunity to link disciplines in ways that address fundamental challenges in biology. | |||
* Nitschke JR. (2009) [http://dx.doi.org/10.1038/462736a Systems chemistry: Molecular networks come of age.] ''Nature'' 462:736-738. | |||
**'''Excerpt:''' There are two main questions [systems chemists are asking]. The first is how the complex networks of molecules found on the prebiotic Earth might have crossed the threshold of life...The second question is how collections of molecules self-assemble into complex structures, and how secondary interactions between molecules and competition for molecular building blocks lead to complex behaviour within self-assembling systems. | |||
* Bray D. (2003) [http://dx.doi.org/10.1126/science.1089118 Molecular Networks: The Top-Down View.] ''Science'' 301:1864-1865. | * Bray D. (2003) [http://dx.doi.org/10.1126/science.1089118 Molecular Networks: The Top-Down View.] ''Science'' 301:1864-1865. | ||
**'''Excerpt:''' Everything in a living cell is, of course, connected to everything else, and interactions between macromolecules through multiple noncovalent bonds are the very fabric of life. It is therefore an attractive notion that, by taking a top-down view of protein-protein interactions, enzymatic pathways, signaling pathways, and gene regulatory pathways, we will gain a better perspective of how they work. | **'''Excerpt:''' Everything in a living cell is, of course, connected to everything else, and interactions between macromolecules through multiple noncovalent bonds are the very fabric of life. It is therefore an attractive notion that, by taking a top-down view of protein-protein interactions, enzymatic pathways, signaling pathways, and gene regulatory pathways, we will gain a better perspective of how they work. | ||
* Alon U. (2003) [http://dx.doi.org/10.1126/science.1089072 Biological Networks: The Tinkerer as an Engineer.] Science'' 301:1866-1867. | * Alon U. (2003) [http://dx.doi.org/10.1126/science.1089072 Biological Networks: The Tinkerer as an Engineer.] Science'' 301:1866-1867. | ||
** '''Excerpt:''' This viewpoint [article] comments on recent advances in understanding the design principles of biological networks. It highlights the surprising discovery of "good-engineering" principles in biochemical circuitry that evolved by random tinkering. | **'''Excerpt:''' This viewpoint [article] comments on recent advances in understanding the design principles of biological networks. It highlights the surprising discovery of "good-engineering" principles in biochemical circuitry that evolved by random tinkering. | ||
* | * Barabási A-L, Albert R. (1999) [http://dx.doi.org/10.1126/science.286.5439.509 Emergence of Scaling in Random Networks.] ''Science'' 286:509-511. | ||
** '''Excerpt:''' | **'''Excerpt:''' Here we report on the existence of a high degree of self-organization characterizing the large-scale properties of complex networks. Exploring several large databases describing the topology of large networks that span fields as diverse as the WWW or citation patterns in science, we show that, independent of the system and the identity of its constituents, the probability P(k) that a vertex in the network interacts with k other vertices decays as a power law, following P(k) ~k-gamma<sup>- </sup>. This result indicates that large networks self-organize into a scale-free state, a feature unpredicted by all existing random network models. |
Latest revision as of 17:05, 4 December 2011
- Please sort and annotate in a user-friendly manner. For formatting, consider using automated reference wikification.
Books
- Képès F. (editor) (2007) Biological networks. Volume 3 of Complex Systems and Interdisciplinary Science. World Scientific. ISBN 9789812706959. | Google Books preview.
- From Preface: In network models, the relevant components in a system are identified as nodes. The interactions between these components are represented as links between nodes. Following this abstraction step, it becomes possible to study the topological properties of the network thus obtained. The generality and uniformity of the network representation make it possible to compare systems of very different types. At present, pure and combined network-based approaches still present fascinating challenges with respect to topological properties, and to temporal and spatial development.
- Ross J, Schreiber I, Vlad MO; with contributions from Arkin A, Oefner PJ, Zamboni N. (2006) Determination of Complex Reaction Mechanisms: Analysis of Chemical, Biological, and Genetic Networks. Oxford University Press: New York. ISBN 978-0-19-517868-5. | Google books preview. | Description of book, table of contents, author bio - OUP webpage.
- Excerpt: We have seen that computations can be achieved by chemical and biochemical reaction mechanisms, and have located computational functions in biological reaction systems. This identification helps in understanding functions and control in such systems. It also helps in suggesting new approaches to the determination of causal connectivities of reacting species, of reaction pathways, and reaction mechanisms, by exploring analogs of investigations in electronics, system analysis [citations given], multivariate statistics [citations given], and other related disciplines. (From Chapter 4: Computations by Means of Macroscopic Chemical Kinetics.)
- ...several systematic approaches for obtaining information on the causal connectivity of chemical species, on correlations of chemical species, on the reaction pathway, and on the reaction mechanism.
- Barabasi A-L. (2002) Linked: The New Science of Networks. Perseus Publishing: Cambridge, MA. ISBN 0-7382-0667-9. | Google Books preview.
- Newman MEJ. (2010) Networks: an introduction. Oxford: Oxford University Press. ISBN 9780199206650. | Google Books preview.
- Newman MEJ, Barabâasi AL, Watts DJ. (2006) The structure and dynamics of networks. Princeton, N.J: Princeton University Press.
- Watts DJ. (1999) Small worlds: the dynamics of networks between order and randomness. Princeton, N.J: Princeton University Press, ISBN 0691005419
Book Chapters
Journal articles
- Weitz JS, Benfey PN, Wingreen NS. (2007) Evolution, Interactions, and Biological Networks. PLoS Biol 5(1): e11.
- Excerpt: As [Theodosius] Dobzhansky famously noted, nothing in biology makes sense except in the light of evolution...This is particularly true of biological networks, and we believe that the lens of evolution provides an exciting opportunity to link disciplines in ways that address fundamental challenges in biology.
- Nitschke JR. (2009) Systems chemistry: Molecular networks come of age. Nature 462:736-738.
- Excerpt: There are two main questions [systems chemists are asking]. The first is how the complex networks of molecules found on the prebiotic Earth might have crossed the threshold of life...The second question is how collections of molecules self-assemble into complex structures, and how secondary interactions between molecules and competition for molecular building blocks lead to complex behaviour within self-assembling systems.
- Bray D. (2003) Molecular Networks: The Top-Down View. Science 301:1864-1865.
- Excerpt: Everything in a living cell is, of course, connected to everything else, and interactions between macromolecules through multiple noncovalent bonds are the very fabric of life. It is therefore an attractive notion that, by taking a top-down view of protein-protein interactions, enzymatic pathways, signaling pathways, and gene regulatory pathways, we will gain a better perspective of how they work.
- Alon U. (2003) Biological Networks: The Tinkerer as an Engineer. Science 301:1866-1867.
- Excerpt: This viewpoint [article] comments on recent advances in understanding the design principles of biological networks. It highlights the surprising discovery of "good-engineering" principles in biochemical circuitry that evolved by random tinkering.
- Barabási A-L, Albert R. (1999) Emergence of Scaling in Random Networks. Science 286:509-511.
- Excerpt: Here we report on the existence of a high degree of self-organization characterizing the large-scale properties of complex networks. Exploring several large databases describing the topology of large networks that span fields as diverse as the WWW or citation patterns in science, we show that, independent of the system and the identity of its constituents, the probability P(k) that a vertex in the network interacts with k other vertices decays as a power law, following P(k) ~k-gamma- . This result indicates that large networks self-organize into a scale-free state, a feature unpredicted by all existing random network models.