The coming Kuhnian revolution in biology

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3. The anomalies arising from Human Genome Project data banks are described by Miklos and Rubin (The role of the Genome Project in determining gene function: Insights from model organisms. Cell 86: 521–529, 1996) Also presented is a scheme for reducing complex function to small clusters of functionally related genes. The hope is that major physiological functions in different species will all exhibit identical or nearly identical patterns of gene utilization. If correct, such reduction may prove useful, but it appears limited in that the search for causality seems to remain focused on the identity of the genetic entities. A more interesting acknowledgment of complexity, in this case in the brain, comes from Edelman and his group. They are evolving models of the brain that also identify subsystem activities, but that attempt to show how “…the complex brain can deal with context and go ‘beyond the information given’.” Going beyond the information given clearly implies going beyond the genome and the need for some epigenetic function having to do with emergent behavior. (Tononi.G., Scorns, O., and Edelman, G.M. 1996. A complexity measure for selective matching of signals by the brain Proc. Natl. Acad. Sci. USA 96: 3422-3427)

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8. Epigenesis has been given a modem definition as follows: “Classical genetics has revealed the mechanisms for the transmission of genes from generation to generation, but the strategy of the genes in unfolding the developmental programme remains obscure. Epigenetics comprises the study of the mechanisms that impart temporal and spatial control on the activity of all those genes required for the development of a complex organism from the zygote to the adult.”( Holliday, R. 1990. Phil. Trans. Royal Soc. Lond. 8326: 329–338). As such, it establishes the basis for a level of organizational control above the genome; a level that is now well established in fact, but continues to evade decisive theoretical insight.

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12. The process involved in editing premessage RNAfrom the genome involves major surgery by enzymes that cut and splice the RNA. In other words, in higher organisms the functional gene is not really in the DNA but emerges only as a result of this higher order cellular manipulation of genetic messages. Therefore, even this linear paradigm of the gene harbors, in higher organisms, a nonlinear component. For a discussion of this and of other epigenetic processes that intervene to change patterns of gene expression, see a recent review by Tim Cavalier-Smith (Trends Genet. 13:7-9,1997).

13. The terms “linear” and “nonlinear” offer sources of confusion because they mean different things in different scientific settings. In mathematics, linearity means simply that we can know the value of the whole by adding up the sum of the parts. So, for example, if we know the values of the initial conditions of a system and these conditions don't interact with one another, we can predict the system's future behavior. A nonlinear system, then, is one in which initial conditions interact so that outcome prediction is difficult at best, even when a complete knowledge of initial conditions is possible. In biology, initial conditions are often taken simply as genomic information and an additive (noninteractive) environmental component. But this is oversimplified in the extreme. Biological systems are nonlinear. For a more fulsome explanation of these two terms and for the clearest (and shortest) explanation of how non-linear systems, while being difficult to predict, are nevertheless determinative, consult ref. 24.

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