Minimal mechanism for cyclic templating of length-controlled copolymers under isothermal conditions

TL;DR

This paper develops a coarse-grained model to address the challenge of product inhibition in templated copolymer synthesis, proposing a mechanism for autonomous, length-controlled copying under constant conditions.

Contribution

It introduces a simple model modification that enables reliable, autonomous cyclic copying of copolymers by overcoming product inhibition through energy diversion and bond weakening.

Findings

Product inhibition prevents reliable copying in basic models.

Diverting polymerization energy can disrupt copy-template bonds.

Weakening the final bond enables high-yield, full-length copying.

Abstract

The production of sequence-specific copolymers using copolymer templates is fundamental to the synthesis of complex biological molecules and is a promising framework for the synthesis of synthetic chemical complexes. Unlike the superficially similar process of self-assembly, however, the development of synthetic systems that implement templated copying of copolymers under constant environmental conditions has been challenging. The main difficulty has been overcoming product inhibition, or the tendency of products to adhere strongly to their templates - an effect that gets exponentially stronger with template length. We develop coarse-grained models of copolymerisation on a finite-length template and analyse them through stochastic simulation. We use these models first to demonstrate that product inhibition prevents reliable template copying, and then ask how this problem can be overcome to achieve cyclic production of polymer copies of the right length and sequence in an autonomous and chemically-driven context. We find that a simple addition to the model is sufficient to generate far longer polymer products that initially form on, and then separate from, the template. In this approach, some of the free energy of polymerisation is diverted into disrupting copy-template bonds behind the leading edge of the growing copy copolymer. By additionally weakening the final copy-template bond at the end of the template, the model predicts that reliable copying with a high yield of full-length, sequence-matched products is possible over large ranges of parameter space, opening the way to the engineering of synthetic copying systems that operate autonomously.