Temporal control by co-factors prevents kinetic trapping in retroviral Gag lattice assembly

Abstract

AbstractFor retroviruses like HIV to proliferate, they must form virions shaped by the self-assembly of Gag polyproteins into a rigid lattice. This immature Gag lattice has been structurally characterized and reconstitutedin vitro, revealing the sensitivity of lattice assembly to multiple co-factors. Due to this sensitivity, the energetic criterion for forming stable lattices is unknown, as are their corresponding rates. Here, we use a reaction-diffusion model designed from the cryo-ET structure of the immature Gag lattice to map a phase diagram of assembly outcomes controlled by experimentally constrained rates and free energies, over experimentally relevant timescales. We find that productive assembly of complete lattices in bulk solution is extraordinarily difficult due to the large size of this ∼3700 monomer complex. Multiple Gag lattices nucleate before growth can complete, resulting in loss of free monomers and frequent kinetic trapping. We therefore derive a time-dependent protocol to titrate or ‘activate’ the Gag monomers slowly within the solution volume, mimicking the biological roles of co-factors. This general strategy works remarkably well, yielding productive growth of self-assembled lattices for multiple interaction strengths and binding rates. By comparing to thein vitroassembly kinetics, we can estimate bounds on rates of Gag binding to Gag and the cellular co-factor IP6. Our results show that Gag binding to IP6 can provide the additional time-delay necessary to support smooth growth of the immature lattice with relatively fast assembly kinetics, mostly avoiding kinetic traps. Our work provides a foundation for predicting and disrupting formation of the immature Gag lattice via targeting specific protein- protein binding interactions.