Life/Bibliography: Difference between revisions
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==Articles== | ==Articles== | ||
*{{:CZ:Ref:DOI:10.1152/physrev.00047.2006}} | *{{:CZ:Ref:DOI:10.1152/physrev.00047.2006}} | ||
::*'''<u>Abstract:</u>''' Maximum life span differences among animal species exceed life span variation achieved by experimental manipulation by orders of magnitude. The differences in the characteristic maximum life span of species was initially proposed to be due to variation in mass-specific rate of metabolism. This is called the rate-of-living theory of aging and lies at the base of the oxidative-stress theory of aging, currently the most generally accepted explanation of aging. However, the rate-of-living theory of aging while helpful is not completely adequate in explaining the maximum life span. Recently, it has been discovered that the fatty acid composition of cell membranes varies systematically between species, and this underlies the variation in their metabolic rate. When combined with the fact that 1) the products of lipid peroxidation are powerful reactive molecular species, and 2) that fatty acids differ dramatically in their susceptibility to peroxidation, membrane fatty acid composition provides a mechanistic explanation of the variation in maximum life span among animal species. When the connection between metabolic rate and life span was first proposed a century ago, it was not known that membrane composition varies between species. Many of the exceptions to the rate-of-living theory appear explicable when the particular membrane fatty acid composition is considered for each case. Here we review the links between metabolic rate and maximum life span of mammals and birds as well as the linking role of membrane fatty acid composition in determining the maximum life span. The more limited information for ectothermic animals and treatments that extend life span (e.g., caloric restriction) are also reviewed. | |||
*{{:CZ:Ref:DOI:10.1016/j.shpsc.2006.09.009}} | *{{:CZ:Ref:DOI:10.1016/j.shpsc.2006.09.009}} | ||
*Epstein IR, Pojman JA, Steinbock O (2006) [http://dx.doi.org/10.1063/1.2354477 Introduction: Self-organization in nonequilibrium chemical systems.] ''Chaos'' 16:037101 PMID 17014235 | *Epstein IR, Pojman JA, Steinbock O (2006) [http://dx.doi.org/10.1063/1.2354477 Introduction: Self-organization in nonequilibrium chemical systems.] ''Chaos'' 16:037101 PMID 17014235 | ||
::*'''<u>Abstract:</u>''' The field of self-organization in nonequilibrium chemical systems comprises the study of dynamical phenomena in chemically reacting systems far from equilibrium. Systematic exploration of this area began with investigations of the temporal behavior of the Belousov-Zhabotinsky oscillating reaction, discovered accidentally in the former Soviet Union in the 1950s. The field soon advanced into chemical waves in excitable media and propagating fronts. With the systematic design of oscillating reactions in the 1980s and the discovery of Turing patterns in the 1990s, the scope of these studies expanded dramatically. The articles in this Focus Issue provide an overview of the development and current state of the field. | ::*'''<u>Abstract:</u>''' The field of self-organization in nonequilibrium chemical systems comprises the study of dynamical phenomena in chemically reacting systems far from equilibrium. Systematic exploration of this area began with investigations of the temporal behavior of the Belousov-Zhabotinsky oscillating reaction, discovered accidentally in the former Soviet Union in the 1950s. The field soon advanced into chemical waves in excitable media and propagating fronts. With the systematic design of oscillating reactions in the 1980s and the discovery of Turing patterns in the 1990s, the scope of these studies expanded dramatically. The articles in this Focus Issue provide an overview of the development and current state of the field. | ||
*Hazen R (2006) [http:// | *Hazen R (2006) [http://www.newscientist.com/article/mg19225780.071 The Big Questions: What is Life?] ''New Scientist'' Issue 2578, pages 46-51. | ||
::*'''<u>Excerpt:</u>''' Scientists care about definitions, so they convene conferences to discuss the matter. A recent meeting called "What is life?" attracted a hundred scientists, who mingled with assorted philosophers and theologians to debate the issue. Opinions differed dramatically, but the most contentious debates occurred within the scientific ranks. One very senior expert on lipid molecules argued that life began with the first semi-permeable lipid membrane. An equally august authority on metabolism countered that life began with the first self-sustaining metabolic cycle. On the contrary, claimed several molecular biologists, the first living entity must have been an RNA-like genetic system that carried and duplicated biological information. One mineralogist even proposed the decidedly minority view that life began not as an organic entity, but as a self-replicating mineral. | |||
*Marenduzzo D ''et al.'' (2006) Entropy-driven genome organization. Biophys J 90:3712-21 PMID 16500976 | *Marenduzzo D ''et al.'' (2006) Entropy-driven genome organization. Biophys J 90:3712-21 PMID 16500976 | ||
*Morowitz H, Smith E (2006) [http://www.santafe.edu/research/publications/workingpapers/06-08-029.pdf Energy flow and the organization of life] | *Morowitz H, Smith E (2006) [http://www.santafe.edu/research/publications/workingpapers/06-08-029.pdf Energy flow and the organization of life] |
Revision as of 19:11, 29 December 2008
- Please sort and annotate in a user-friendly manner. For formatting, consider using automated reference wikification.
Books
- Schrödinger E (1944-2000) What is Life? Cambridge University Press (Canto). ISBN 0-521-42708-8 Chapter 6: Order, Disorder and Entropy (Prediction of hereditary molecule like a coded periodic crystal — Watson claims inspiration — Stresses open thermodynamic systems key to life.)
- Kaneko K (2006) Life: An Introduction to Complex Systems Biology. Springer, Berlin ISBN 3-540-32666-9
- Dill KA, Bromberg S, Stigter D (2003) Molecular Driving Forces: Statistical Thermodynamics in Chemistry and Biology. Garland Science, New York. ISBN 0-8153-2051-5
- Strogatz SH (2003) Sync: The Emerging Science of Spontaneous Order. Theia, New York ISBN 0-7868-6844-9
- Buchanan M (2002) Nexus: Small Worlds and the Groundbreaking Science of Networks. W.W. Norton, New York ISBN 0-393-04153-0
- Hoagland M, Dodson B, Hauck J (2001) Exploring the Way Life Works: The Science of Biology. Jones and Bartlett Publishers, Inc, Mississauga, Ontario ISBN 0-7637-1688-X (For young people. An illustrated text.)
- Solé R, Goodwin B (2000) Signs of Life: How Complexity Pervades Biology. Basic Books, Perseus Books Group, New York ISBN 0-465-01928-5
- Loewenstein WR (2000) The Touchstone of life: Molecular Information, Cell Communication, and the Foundations of Life. Oxford University Press ISBN 0-19-514057-5 Book Review and Chapter One
- Hoagland M, Dodson B (1998) The Way Life Works: The Science Lovers Illustrated Guide to How Life Grows, Develops, Reproduces, and Gets Along. Three Rivers Press, New York ISBN 0-8129-2888-1 (For young people. An illustrated text.)
- Margulis L, Sagan D (1995) What is Life? Simon & Schuster ISBN 0-684-81087-5
- Rosen R. (1991) Life Itself: A Comprehensive Inquiry Into The Nature, Origin, And Fabrication Of Life. Columbia University Press, New York. ISBN 0-231-07565-0
- Kauffman SA. (1993) The Origins of Order: Self-Organization and Selection in Evolution. Oxford University Press, New York. ISBN 0195058119
- Kauffman S. (1995) At Home in the Universe: The Search for Laws of Self-Organization and Complexity. Oxford University Press, New York. ISBN 0195095995
- Mayr E. (1997) Evolution and the Diversity of Life: Selected Essays. The Belknap Press of Harvard University Press, Cambridge, Massachusetts.
- Holland JH. (1998) Emergence: From Chaos to Order. Perseus Books, Cambridge. ISBN 0-7382-0142-1
- Haynie DT. (2001) Biological Thermodynamics. Cambridge University Press, Cambridge. ISBN 13-978-0-521-79549-4; 10-0-521-79165-0
- Harold FM. (2001) The Way of the Cell: Molecules, Organisms, and the Order of Life. Oxford University Press, Oxford. ISBN 0195135121
- Kirschner MW, Gerhart JC, Norton J. (2005) The Plausibility of Life: Resolving Darwin's Dilemma. Yale University Press, New Haven. ISBN 13-978-0-300-11977-0; 10-0-300-11977-1
- Reid RGB. (2007) Biological Emergences: Evolution by Natural Experiment. A Bradford Book, Cambridge . ISBN 10: 0-262-18257-2
- De Duve C (2004) Life Evolving: Molecules, Mind, and Meaning. Oxford University Press. New York ISBN 0195156056
Articles
- Hulbert, A. J.; Reinald Pamplona & Rochelle Buffenstein et al. (2007), "Life and Death: Metabolic Rate, Membrane Composition, and Life Span of Animals", Physiological Reviews 87 (4): 1175-1213, DOI:10.1152/physrev.00047.2006 [e]
- Abstract: Maximum life span differences among animal species exceed life span variation achieved by experimental manipulation by orders of magnitude. The differences in the characteristic maximum life span of species was initially proposed to be due to variation in mass-specific rate of metabolism. This is called the rate-of-living theory of aging and lies at the base of the oxidative-stress theory of aging, currently the most generally accepted explanation of aging. However, the rate-of-living theory of aging while helpful is not completely adequate in explaining the maximum life span. Recently, it has been discovered that the fatty acid composition of cell membranes varies systematically between species, and this underlies the variation in their metabolic rate. When combined with the fact that 1) the products of lipid peroxidation are powerful reactive molecular species, and 2) that fatty acids differ dramatically in their susceptibility to peroxidation, membrane fatty acid composition provides a mechanistic explanation of the variation in maximum life span among animal species. When the connection between metabolic rate and life span was first proposed a century ago, it was not known that membrane composition varies between species. Many of the exceptions to the rate-of-living theory appear explicable when the particular membrane fatty acid composition is considered for each case. Here we review the links between metabolic rate and maximum life span of mammals and birds as well as the linking role of membrane fatty acid composition in determining the maximum life span. The more limited information for ectothermic animals and treatments that extend life span (e.g., caloric restriction) are also reviewed.
- Walsh, D. (2006), "Organisms as natural purposes: the contemporary evolutionary perspective", Studies in History and Philosophy of Science Part C: Studies in History and Philosophy of Biological and Biomedical Sciences 37: 771-791, DOI:10.1016/j.shpsc.2006.09.009 [e]
- Epstein IR, Pojman JA, Steinbock O (2006) Introduction: Self-organization in nonequilibrium chemical systems. Chaos 16:037101 PMID 17014235
- Abstract: The field of self-organization in nonequilibrium chemical systems comprises the study of dynamical phenomena in chemically reacting systems far from equilibrium. Systematic exploration of this area began with investigations of the temporal behavior of the Belousov-Zhabotinsky oscillating reaction, discovered accidentally in the former Soviet Union in the 1950s. The field soon advanced into chemical waves in excitable media and propagating fronts. With the systematic design of oscillating reactions in the 1980s and the discovery of Turing patterns in the 1990s, the scope of these studies expanded dramatically. The articles in this Focus Issue provide an overview of the development and current state of the field.
- Hazen R (2006) The Big Questions: What is Life? New Scientist Issue 2578, pages 46-51.
- Excerpt: Scientists care about definitions, so they convene conferences to discuss the matter. A recent meeting called "What is life?" attracted a hundred scientists, who mingled with assorted philosophers and theologians to debate the issue. Opinions differed dramatically, but the most contentious debates occurred within the scientific ranks. One very senior expert on lipid molecules argued that life began with the first semi-permeable lipid membrane. An equally august authority on metabolism countered that life began with the first self-sustaining metabolic cycle. On the contrary, claimed several molecular biologists, the first living entity must have been an RNA-like genetic system that carried and duplicated biological information. One mineralogist even proposed the decidedly minority view that life began not as an organic entity, but as a self-replicating mineral.
- Marenduzzo D et al. (2006) Entropy-driven genome organization. Biophys J 90:3712-21 PMID 16500976
- Morowitz H, Smith E (2006) Energy flow and the organization of life
- Scheffer M, van Nes EH (2006) Self-organized similarity, the evolutionary emergence of groups of similar species. Proc Natl Acad Sci USA 103:6230-5 PMID 16585519
- Walsh DM (2006) Organisms as natural purposes: The contemporary evolutionary perspective. Studies in History and Philosophy of Science. Part C: Studies in History and Philosophy of Biological and Biomedical Sciences 37:771-91
- Park K et al. (2005) Self-organized scale-free networks. Phys Rev E Stat Nonlin Soft Matter Phys 72:026131 PMID 16196668
- Troisi A et al.(2005) An agent-based approach for modeling molecular self-organization. Proc Natl Acad Sci USA 102:255-60 PMID 15625108
- Koshland DE, Jr. (2002) Special essay. The seven pillars of life. Science 295:2215-2216 PMID 11910092
- The Seven Pillars: Program (DNA), Improvisation (evolution), Compartmentalization (boundary with environment), Energy (the flow of energy through the system), Regeneration (re-synthesis of parts), Adaptability (‘behavioral’ responsiveness), Seclusion (metabolic pathways do not have their privacy invaded).
- Pace NR (2001) Special Feature: The universal nature of biochemistry. Proc Natl Acad Sci USA 98:805-8
- Dronamraju KR (1999) Erwin Schrodinger and the origins of molecular biology. Genetics 153:1071-6 PMID 10545442
Interviews and Commentaries
- Kauffman S. The Adjacent Possible: A Talk with Stuart Kauffman