The N-terminal domain of RfaH plays an active role in protein fold-switching

The bacterial elongation factor RfaH promotes the expression of virulence factors by specifically binding to RNA polymerases (RNAP) stalled at a DNA signal known as ops. This behavior is unlike that of its paralog NusG, the major representative of the protein family to which RfaH belongs. Both proteins have an N-terminal domain (NTD) bearing an RNAP binding site, yet NusG C-terminal domain (CTD) is folded as a {beta}-barrel while RfaH CTD is forming an -hairpin blocking such site. Upon recognition of the ops exposed by RNAP, RfaH is activated via interdomain dissociation and complete CTD structural rearrangement into a {beta}-barrel structurally identical to NusG CTD. Although RfaH transformation has been extensively characterized computationally, most studies employ tertiary biases towards each native state, hampering the analysis of sequence-encoded interactions on fold-switching. Here, we used Associative Water-mediated Structure and Energy Model (AWSEM) molecular dynamics to characterize the transformation of RfaH, spotlighting the sequence-dependent effects of NTD on CTD fold stabilization. Umbrella sampling simulations guided by native contacts recapitulate the thermodynamic equilibrium experimentally observed for RfaH and its isolated CTD. Temperature refolding simulations of full-length RfaH show a high success towards -folded CTD, whereas the NTD interferes with {beta}CTD folding, becoming trapped in a {beta}-barrel intermediate. Meanwhile, NusG CTD refolding is unaffected by the presence of RfaH NTD, showing that these NTD-CTD interactions are encoded in RfaH sequence. Altogether, these results suggest that the NTD of RfaH favors the -folded RfaH by specifically orienting the CTD upon interdomain binding and also by favoring {beta}-barrel rupture into an intermediate from which fold-switching proceeds.