Computer Simulations of RNA Replication in Protocells

Abstract

The RNA world hypothesis posits that at some stage in the development of life, RNA functioned as both an informational polymer and a catalyst for important reactions. However, many questions remain as to how RNA molecules might have evolved into living organisms. This thesis uses computer simulations to model processes thought to be important to the development of an RNA world. First, a model is discussed which describes non-enzymatic polymerization of single-stranded RNA from different kinds of activated nucleotides, a necessary first step towards an RNA world. It was found that a system undergoing polymerization of RNA from 5′-activated triphosphates or imidazolides behaves differently from an equilibrium system undergoing reversible polymerization reactions from 2′,3′-cyclic monophosphates, for example. In the 5′-triphosphate case, the system is not in equilibrium but rather in a state of circular reaction flux that must be maintained by an external source of phosphates. This model is then adapted to investigate non-enzymatic template-directed replication of RNA strands. It is found that this process fulfills all the necessary requirements to function as a metabolism which maintains a difference between the outside non-living environment and the internal environment of the cell. Finally, byproducts arising from the template copying mechanism in this model are discussed, including the development of highly regular sequence patterns in the strand population due to selection for the ability to form duplexes with neighbouring strands. Altogether, this thesis illustrates new implications, potential pitfalls, and possibilities of the RNA world hypothesis for the origin of life. In particular, it emphasizes the fundamental link between the processes of replication and metabolism, both of which must have been crucial to the functioning of the earliest protocells. This link has been largely overlooked in scientific literature on the topic to date.