Collective Evolution of Biological and Physical Systems
Vetsigian, Kalin
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https://hdl.handle.net/2142/35234
Description
Title
Collective Evolution of Biological and Physical Systems
Author(s)
Vetsigian, Kalin
Issue Date
2005
Department of Study
Physics
Discipline
Physics
Degree Name
Ph.D.
Degree Level
Dissertation
Keyword(s)
microbial
genome
microbial genomes
asymtotic
homologous recombination
speciation
Deoxyribonucleic acid (DNA)
Transfer ribonucleic acid (tRNA)
Messenger Ribonucleic Acid (mRNA)
Bacillus
microogranism
genetic drift
deleterius
Horizontal Gene Transfer (HGT)
phase-feild model
invasion-equilibrium cycle
amino acid
fitness noise
Language
en
Abstract
In this dissertation, I study the evolution of solidification fronts propagating in undercooled liquids, the evolution of microbial communities through diversification fronts propagating along
microbial genomes, the evolution of the universality and optimality of the genetic code, and the emergence of genome biases.
I present a new phase-field model of solidification which allows efficient computations in the regime when interface kinetic effects dominate over capillary effects. The asymptotic analysis
required to relate the parameters in the phase-field with those of the original sharp interface model is straightforward, and the resultant phase-field model can be used for a wide range of material parameters. I model the competition between homologous recombination and point mutation in microbial
genomes, and present evidence for two distinct phases, one uniform, the other genetically diverse. Depending on the specifics of homologous recombination, I find that global sequence divergence
can be mediated by fronts propagating along the genome, whose characteristic signature on genome structure is elucidated, and apparently observed in closely related genomes from the Bacillus cereus group. Front propagation provides an emergent, generic mechanism for microbial “speciation,” and suggests a classification of microorganisms on the basis of their propensity to support propagating fronts. I propose that selection on the speed, accuracy and energy efficiency of template-directed synthesis processes such as translation, transcription and replication can lead to the spontaneous
emergence of genome biases. Selection on translation leads to codon usage bias; selection on transcription or replication leads to nucleotide composition biases such as the GC content. These biases result from the generic tradeoffs inherent to template-directed synthesis and occur even in the absence of biased mutation or direct selection on the nucleotide composition coming from, say, DNA or mRNA stability. In the case of translation, it is the coevolution between codon usage and tRNA
expression levels that creates a fitness landscape that enforces quasi-stable patterns of codon usage.
Occasional transitions between patterns are expected, due to genetic drift or hitchhiking of slightly deleterious adjustments of the translational system on other beneficial traits. Then, I show that the above coevolutionary dynamics provides an efficient mechanism for optimization of genetic codes, even if, as the frozen accident theory assumes, every amino acid
substitution is lethal at least at some genome sites. This research shows that it is possible to account for the optimality of the code within the framework of translation as a standardized competition between tRNA adaptors. Finally, I investigate the proposition that genetic exchange dominating the early evolution of life naturally leads to a common genetic code for all organisms, while promoting their incredible
diversity in all other aspects. I present three possible mechanisms through which HGT brings universality - communal advantage of popular codes, HGT of translational components and HGT of protein coding regions. A possible consequence of the interplay of these mechanisms is the
concerted evolution towards optimality of a community of organisms sharing the same genetic code and having compatible translational machineries.
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