Intrinsically disordered protein regions (IDRs) lack a well defined three-dimensional structure but often facilitate key protein functions. Some interactions between IDRs and folded protein domains rely on short linear motifs (SLiMs). These motifs are challenging to identify, but once found they can point to larger networks of interactions, such as with proteins that serve as hubs for essential cellular functions. The stress-associated plant protein radical-induced cell death1 (RCD1) is one such hub, interacting with many transcription factors via their flexible IDRs. To identify the SLiM bound by RCD1, we analyzed the IDRs in three protein partners, DREB2A (dehydration-responsive element-binding protein 2A), ANAC013, and ANAC046, considering parameters such as disorder, context, charges, and pI. Using a combined bioinformatics and experimental approach, we have identified the bipartite RCD1-binding SLiM as (DE)X(1,2)(YF)X(1,4)(DE)L, with essential contributions from conserved aromatic, acidic, and leucine residues. Detailed thermodynamic analysis revealed both favorable and unfavorable contributions from the IDRs surrounding the SLiM to the interactions with RCD1, and the SLiM affinities ranged from low nanomolar to 50 times higher K values. Specifically, although the SLiM was surrounded by IDRs, individual intrinsic α-helix propensities varied as shown by CD spectroscopy. NMR spectroscopy further demonstrated that DREB2A underwent coupled folding and binding with α-helix formation upon interaction with RCD1, whereas peptides from ANAC013 and ANAC046 formed different structures or were fuzzy in the complexes. These findings allow us to present a model of the stress-associated RCD1-transcription factor interactome and to contribute to the emerging understanding of the interactions between folded hubs and their intrinsically disordered partners.
Recently, an enzymatic reaction was utilized to covalently link the N and C termini of membrane scaffold proteins to produce circularized nanodiscs that were more homogeneous and stable than standard nanodiscs. We continue this development and aim for obtaining high yields of stable and monodisperse nanodiscs for structural studies of membrane proteins by solution small‐angle scattering techniques. Based on the template MSP1E3D1, we designed an optimized membrane scaffold protein (His‐lsMSP1E3D1) with a sortase recognition motif and high abundance of solubility‐enhancing negative charges. With these modifications, we show that high protein expression is maintained and that the circularization reaction is efficient, such that we obtain a high yield of circularized membrane scaffold protein (csMSP1E3D1) and downstream circularized nanodiscs. We characterize the circularized protein and corresponding nanodiscs biophysically by small‐angle X‐ray scattering, size‐exclusion chromatography, circular dichroism spectroscopy, and light scattering and compare to noncircularized samples. First, we show that circularized and noncircularized (lsMSP1E3D1) nanodiscs are structurally similar and have the expected nanodisc structure. Second, we show that lsMSP1E3D1 nanodiscs are more stable compared to the template MSP1E3D1 nanodiscs as an effect of the extra negative charges and that csMSP1E3D1 nanodiscs have further improved stability as an effect of circularization. Finally, we show that a membrane protein can be efficiently incorporated in csMSP1E3D1 nanodiscs. Large‐scale production methods for circularized nanodiscs with improved thermal and temporal stability will facilitate better access to the nanodisc technology and enable applications at physiologically relevant temperatures.
Intrinsic disorder (ID) constitutes a new dimension to the protein structure−function relationship. The ability to undergo conformational changes upon binding is a key property of intrinsically disordered proteins and remains challenging to study using conventional methods. A 1994 paper by R. S. Spolar and M. T. Record presented a thermodynamic approach for estimating changes in conformational entropy based on heat capacity changes, allowing quantification of residues folding upon binding. Here, we adapt the method for studies of intrinsically disordered proteins. We integrate additional data to provide a broader experimental foundation for the underlying relations and, based on >500 protein−protein complexes involving disordered proteins, reassess a key relation between polar and nonpolar surface area changes, previously determined using globular protein folding. We demonstrate the improved suitability of the adapted method to studies of the folded αα-hub domain RST from radical-induced cell death 1, whose interactome is characterized by ID. From extensive thermodynamic data, quantifying the conformational entropy changes upon binding, and comparison to the NMR structure, the adapted method improves accuracy for ID-based studies. Furthermore, we apply the method, in conjunction with NMR, to reveal hitherto undetected effects of interaction−motif context. Thus, inclusion of the disordered context of the DREB2A RST-binding motif induces structuring of the binding motif, resulting in major enthalpy−entropy compensation in the interaction interface. This study, also evaluating additional interactions, demonstrates the strength of the ID-adapted Spolar−Record thermodynamic approach for dissection of structural features of ID-based interactions, easily overlooked in traditional studies, and for translation of these into mechanistic knowledge.
In vitro characterization of membrane proteins requires experimental approaches providing mimics of the microenvironment that proteins encounter in native membranes. In this context, supported lipid bilayers provide a suitable platform to investigate membrane proteins by a broad range of surface-sensitive techniques such as neutron reflectometry (NR), quartz crystal microbalance with dissipation monitoring (QCM-D), surface plasmon resonance (SPR), atomic force microscopy (AFM), and fluorescence microscopy. Nevertheless, the successful incorporation of membrane proteins in lipid bilayers with sufficiently high concentration and controlled orientation relative to the bilayer remains challenging. We propose the unconventional use of peptide discs made by phospholipids and amphipathic 18A peptides to mediate the formation of supported phospholipid bilayers with two different types of membrane proteins, CorA and tissue factor (TF). The membrane proteins are reconstituted in peptide discs, deposited on a solid surface, and the peptide molecules are then removed with extensive buffer washes. This leaves a lipid bilayer with a relatively high density of membrane proteins on the support surface. As a very important feature, the strategy allows membrane proteins with one large extramembrane domain to be oriented in the bilayer, thus mimicking the in vivo situation. The method is highly versatile, and we show its general applicability by characterizing with the above-mentioned surface-sensitive techniques two different membrane proteins, which were efficiently loaded in the supported bilayers with ∼0.6% mol/mol (protein/lipid) concentration corresponding to 35% v/v for CorA and 8% v/v for TF. Altogether, the peptide disc mediated formation of supported lipid bilayers with membrane proteins represents an attractive strategy for producing samples for structural and functional investigations of membrane proteins and for preparation of suitable platforms for drug testing or biosensor development.
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