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A hydrophobic ratchet entrenches molecular complexes

Georg K. A. Hochberg, Yang Liu, Erik G. Marklund, Brian P. H. Metzger, Arthur Laganowsky and Joseph W. Thornton ()
Additional contact information
Georg K. A. Hochberg: University of Chicago
Yang Liu: Texas A&M University
Erik G. Marklund: Uppsala University
Brian P. H. Metzger: University of Chicago
Arthur Laganowsky: Texas A&M University
Joseph W. Thornton: University of Chicago

Nature, 2020, vol. 588, issue 7838, 503-508

Abstract: Abstract Most proteins assemble into multisubunit complexes1. The persistence of these complexes across evolutionary time is usually explained as the result of natural selection for functional properties that depend on multimerization, such as intersubunit allostery or the capacity to do mechanical work2. In many complexes, however, multimerization does not enable any known function3. An alternative explanation is that multimers could become entrenched if substitutions accumulate that are neutral in multimers but deleterious in monomers; purifying selection would then prevent reversion to the unassembled form, even if assembly per se does not enhance biological function3–7. Here we show that a hydrophobic mutational ratchet systematically entrenches molecular complexes. By applying ancestral protein reconstruction and biochemical assays to the evolution of steroid hormone receptors, we show that an ancient hydrophobic interface, conserved for hundreds of millions of years, is entrenched because exposure of this interface to solvent reduces protein stability and causes aggregation, even though the interface makes no detectable contribution to function. Using structural bioinformatics, we show that a universal mutational propensity drives sites that are buried in multimeric interfaces to accumulate hydrophobic substitutions to levels that are not tolerated in monomers. In a database of hundreds of families of multimers, most show signatures of long-term hydrophobic entrenchment. It is therefore likely that many protein complexes persist because a simple ratchet-like mechanism entrenches them across evolutionary time, even when they are functionally gratuitous.

Date: 2020
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DOI: 10.1038/s41586-020-3021-2

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