TY - GEN
T1 - Origins of scaling in genetic code
AU - Obst, Oliver
AU - Polani, Daniel
AU - Prokopenko, Mikhail
PY - 2011
Y1 - 2011
N2 - ![CDATA[The principle of least effort in communications has been shown, by Ferrer i Cancho and Solé, to explain emergence of power laws (e.g., Zipf's law) in human languages. This paper applies the principle and the information-theoretic model of Ferrer i Cancho and Solé to genetic coding. The application of the principle is achieved via equating the ambiguity of signals used by "speakers" with codon usage, on the one hand, and the effort of "hearers" with needs of amino acid translation mechanics, on the other hand. The re-interpreted model captures the case of the typical (vertical) gene transfer, and confirms that Zipf's law can be found in the transition between referentially useless systems (i.e., ambiguous genetic coding) and indexical reference systems (i.e., zero-redundancy genetic coding). As with linguistic symbols, arranging genetic codes according to Zipf's law is observed to be the optimal solution for maximising the referential power under the effort constraints. Thus, the model identifies the origins of scaling in genetic coding - via a trade-off between codon usage and needs of amino acid translation. Furthermore, the paper extends the model to multiple inputs, reaching out toward the case of horizontal gene transfer (HGT) where multiple contributors may share the same genetic coding. Importantly, the extended model also leads to a sharp transition between ambiguous HGT and zero-redundancy HGT. Zipf's law is also observed to be the optimal solution in the HGT case.]]
AB - ![CDATA[The principle of least effort in communications has been shown, by Ferrer i Cancho and Solé, to explain emergence of power laws (e.g., Zipf's law) in human languages. This paper applies the principle and the information-theoretic model of Ferrer i Cancho and Solé to genetic coding. The application of the principle is achieved via equating the ambiguity of signals used by "speakers" with codon usage, on the one hand, and the effort of "hearers" with needs of amino acid translation mechanics, on the other hand. The re-interpreted model captures the case of the typical (vertical) gene transfer, and confirms that Zipf's law can be found in the transition between referentially useless systems (i.e., ambiguous genetic coding) and indexical reference systems (i.e., zero-redundancy genetic coding). As with linguistic symbols, arranging genetic codes according to Zipf's law is observed to be the optimal solution for maximising the referential power under the effort constraints. Thus, the model identifies the origins of scaling in genetic coding - via a trade-off between codon usage and needs of amino acid translation. Furthermore, the paper extends the model to multiple inputs, reaching out toward the case of horizontal gene transfer (HGT) where multiple contributors may share the same genetic coding. Importantly, the extended model also leads to a sharp transition between ambiguous HGT and zero-redundancy HGT. Zipf's law is also observed to be the optimal solution in the HGT case.]]
KW - Zipf's law
KW - codon usage
KW - genetic code
KW - genetic transformation
UR - http://handle.uws.edu.au:8081/1959.7/uws:36091
UR - http://www.alife.org/conference/ecal-2009
U2 - 10.1007/978-3-642-21314-4_11
DO - 10.1007/978-3-642-21314-4_11
M3 - Conference Paper
SN - 9783642213137
SP - 85
EP - 93
BT - Advances in Artificial Life: 10th European Conference, ECAL 2009, Budapest, Hungary, September 13-16, 2009, Revised Selected Papers
PB - Springer
T2 - European Conference on Artificial Life
Y2 - 13 September 2009
ER -