IAS BMVP Eugene V. Koonin Public Lecture: The chemistry-biology interface and the origin of cells and viruses

10 October 2017, 1.00 PM - 27 September 2017, 2.00 PM

Dr Eugene Koonin, National Center for Biotechnology Information, NLM, National Institutes of Health, Bethesda, Maryland,USA

Reynolds Lecture Theatre, G25, Wills Memorial Building

Dr Koonin is the most prominent, contemporary computational biologist, and one of the most important evolutionary biologists of our time.

The talk is part of the WJ Sollas Lecture Series

Abstract: Origin and the earliest stages in the evolution of life arguably are the hardest problems in biology. Comparative analysis of modern life forms offers little insight into primordial evolution. However, it can be complemented by the ‘chemistry conservation principle’ whereby the fundamental features of the chemical composition of cells, in particular, inorganic ion balance, have been conserved through the entire course of cellular evolution. All cells contain much more potassium, phosphate, and transition metals than modern as well as reconstructed primeval oceans, lakes, or rivers. Given that the first cells could possess neither ion-tight membranes nor membrane pumps, the concentrations of small inorganic molecules and ions within protocells and in their environment would equilibrate. Hence, ‘chemistry conservation’: the ion composition of modern cells might reflect the inorganic ion composition of the habitats of protocells. Combining this principle with geochemical data, we come to an unexpected conclusion: the precellular stages of evolution might have transpired in shallow ponds of condensed and cooled geothermal vapor that were lined with porous silicate minerals mixed with metal sulfides and enriched in K+, Zn2+, and phosphorous compounds. In addition to the chemistry of the primordial life forms, we also attempt to reconstruct their genetic processes and genomic architecture. I will argue that molecular biology and genomics of extant viruses and other mobile genetic elements, which are associated with all cellular life forms, can inform such reconstructions. The earliest stages of evolution involved a pool of virus-like genetic elements with diverse genetic cycles.

Contact information

benjamin.moon@bristol.ac.uk