Abstract
A central and long-standing issue in evolutionary theory is the origin of the biological variation upon which natural selection acts1. Some hypotheses suggest that evolutionary change represents an adaptation to the surrounding environment within the constraints of an organism's innate characteristics1,2,3. Elucidation of the origin and evolutionary relationship of species has been complemented by nucleotide sequence4 and gene content5 analyses, with profound implications for recognizing life's major domains4. Understanding of evolutionary relationships may be further expanded by comparing systemic higher-level organization among species. Here we employ multivariate analyses to evaluate the biochemical reaction pathways characterizing 43 species. Comparison of the information transfer pathways of Archaea and Eukaryotes indicates a close relationship between these domains. In addition, whereas eukaryotic metabolic enzymes are primarily of bacterial origin6, the pathway-level organization of archaeal and eukaryotic metabolic networks is more closely related. Our analyses therefore suggest that during the symbiotic evolution of eukaryotes,7,8,9 incorporation of bacterial metabolic enzymes into the proto-archaeal proteome was constrained by the host's pre-existing metabolic architecture.
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Acknowledgements
We would like to acknowledge all members of the WIT project for making their invaluable database publicly available for the scientific community. Research at Eötvös University was supported by the Hungarian National Research Grant Foundation (OTKA), by the National Science Foundation at the University of Notre Dame, and at Northwestern University by grants from the National Cancer Institute.
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Podani, J., Oltvai, Z., Jeong, H. et al. Comparable system-level organization of Archaea and Eukaryotes. Nat Genet 29, 54–56 (2001). https://doi.org/10.1038/ng708
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DOI: https://doi.org/10.1038/ng708
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