Capillarity Theory for the Fly-Casting Mechanism

Biomolecular folding and function are often coupled. During molecular recognition events, one of the binding partners may transiently or partially unfold, allowing more rapid access to a binding site. We describe a simple model for this flycasting mechanism based on the capillarity approximation and polymer chain statistics. The model shows that flycasting is most effective when the protein unfolding barrier is small and the part of the chain which extends towards the target is relatively rigid. These features are often seen in known examples of flycasting in protein-DNA binding. Simulations of protein-DNA binding based on well-funneled native-topology models with electrostatic forces confirm the trends of the analytical theory

DNA search efficiency is modulated by charge composition and distribution in the intrinsically disordered tail

Intrinsically disordered tails are common in DNA-binding proteins and can affect their search efficiency on nonspecific DNA by promoting the brachiation dynamics of intersegment transfer. During brachiation, the protein jumps between distant DNA regions via an intermediate state in which the tail and globular moieties are bound to different DNA segments. While the disordered tail must be long and positively charged to facilitate DNA search, the effect of its residue sequence on brachiation is unknown. We explored this issue using the NK-2 and Antp homeodomain transcription factors. We designed 566 NK-2 tail-variants and 55 Antp tail-variants having different net charges and positive charge distributions and studied their dynamics and DNA search efficiencies using coarse-grained molecular dynamics simulations. More intersegment transfers occur when the tail is moderately positively charged and the positive charges are clustered together in the middle of the tail or towards its N terminus. The presence of a negatively charged residue does not significantly affect protein brachiation, although it is likely that the presence of many negatively charged residues will complicate the DNA search mechanism. A bioinformatic analysis of 1,384 wild-type homeodomains illustrates that the charge composition and distribution in their N-tail sequences are consistent with an optimal charge pattern to promote intersegment transfer. Our study thus indicates that the residue sequence of the disordered tails of DNA-binding proteins has unique characteristics that were evolutionarily selected to achieve optimized function and suggests that the sequence-structure-function paradigm known for structured proteins is valid for intrinsically disordered proteins as well

Net charge per residue modulates conformational ensembles of intrinsically disordered proteins

Intrinsically disordered proteins (IDPs) adopt heterogeneous ensembles of conformations under physiological conditions. Understanding the relationship between amino acid sequence and conformational ensembles of IDPs can help clarify the role of disorder in physiological function. Recent studies revealed that polar IDPs favor collapsed ensembles in water despite the absence of hydrophobic groups—a result that holds for polypeptide backbones as well. By studying highly charged polypeptides, a different archetype of IDPs, we assess how charge content modulates the intrinsic preference of polypeptide backbones for collapsed structures. We characterized conformational ensembles for a set of protamines in aqueous milieus using molecular simulations and fluorescence measurements. Protamines are arginine-rich IDPs involved in the condensation of chromatin during spermatogenesis. Simulations based on the ABSINTH implicit solvation model predict the existence of a globule-to-coil transition, with net charge per residue serving as the discriminating order parameter. The transition is supported by quantitative agreement between simulation and experiment. Local conformational preferences partially explain the observed trends of polymeric properties. Our results lead to the proposal of a schematic protein phase diagram that should enable prediction of polymeric attributes for IDP conformational ensembles using easily calculated physicochemical properties of amino acid sequences. Although sequence composition allows the prediction of polymeric properties, interresidue contact preferences of protamines with similar polymeric attributes suggest that certain details of conformational ensembles depend on the sequence. This provides a plausible mechanism for specificity in the functions of IDPs