Polycomb group proteins are repressive chromatin modifiers with essential roles in metazoan development, cellular differentiation and cell fate maintenance. How Polycomb proteins access active chromatin to confer transcriptional silencing during lineage transitions remains unclear. Here we show that the Polycomb repressive complex 2 (PRC2) component PHF19 binds trimethylated histone H3 Lys36 (H3K36me3), a mark of active chromatin, via its Tudor domain. PHF19 associates with the H3K36me3 demethylase NO66, and it is required to recruit the PRC2 complex and NO66 to stem cell genes during differentiation, leading to PRC2-mediated trimethylation of histone H3 Lys27 (H3K27), loss of H3K36me3 and transcriptional silencing. We propose a model whereby PHF19 functions during mouse embryonic stem cell differentiation to transiently bind the H3K36me3 mark via its Tudor domain, forming essential contact points that allow recruitment of PRC2 and H3K36me3 demethylase activity to active gene loci during their transition to a Polycomb-repressed state.
Single-molecule experimental techniques have recently shown to be of significant interest for use in numerous applications in both the research laboratory and industrial settings. Although many single-molecule techniques exist, the nanopore platform is perhaps one of the more popular techniques due to its ability to act as a molecular sensor of biological macromolecules. For example, nanopores offer a unique, new method for probing various properties of proteins and can contribute to elucidating key biophysical information in conjunction with existing techniques. In the present study, various forms of bovine serum albumin (BSA) are detected including thermally refolded BSA, urea-denatured BSA, and multiple forms of BSA detected at elevated electric field strengths (with and without urea). We also provide excluded volume measurements for each of these states that normally are difficult to obtain due to unknown and unstable protein conformations.
Protein-protein interactions mediated by modular protein domains are critical for cell scaffolding, differentiation, signaling, and ultimately, evolution. Given the vast number of ligands competing for binding to a limited number of domain families, it is often puzzling how specificity can be achieved. Selectivity may be modulated by intradomain allostery, whereby a remote residue is energetically connected to the functional binding site via side chain or backbone interactions. Whereas several energetic pathways, which could mediate intradomain allostery, have been predicted in modular protein domains, there is a paucity of experimental data to validate their existence and roles. Here, we have identified such functional energetic networks in one of the most common protein-protein interaction modules, the PDZ domain. We used double mutant cycles involving site-directed mutagenesis of both the PDZ domain and the peptide ligand, in conjunction with kinetics to capture the fine energetic details of the networks involved in peptide recognition. We performed the analysis on two homologous PDZ-ligand complexes and found that the energetically coupled residues differ for these two complexes. This result demonstrates that amino acid sequence rather than topology dictates the allosteric pathways. Furthermore, our data support a mechanism whereby the whole domain and not only the binding pocket is optimized for a specific ligand. Such cross-talk between binding sites and remote residues may be used to fine tune target selectivity.Several studies on protein-protein interaction modules (1), such as SH2, SH3, and PDZ 5 domains, have highlighted the apparent problem of how selectivity is achieved in a cellular context (2-4). For example, the synapse contains several PDZ proteins (5) with apparently overlapping specificity, and yet they have distinct roles in scaffolding and signaling (6). One mechanism that could modulate specificity is intradomain allostery (7). Multisubunit proteins such as hemoglobin are well known for their allosteric behavior whereby the oxygen binding is cooperative because ligation of one subunit will modulate the affinity in the other subunits of the tetramer (8). But allostery is also present within monomeric proteins (9), and it may be invoked even in the absence of a detectable conformational change (10 -15).Previous studies on monomeric globular proteins have predicted allosteric pathways on an amino acid residue level based on analysis of co-evolution (16, 17), molecular dynamics simulations (18), or NMR-constrained molecular dynamics (19). Although the PDZ domain family has served as a prime model system for these studies, experimental data that detect intramolecular allosteric pathways are scarce and sometimes conflicting (16,20,21).In protein folding studies, it proved illuminating to compare homologous proteins to unravel basic determinants of the underlying mechanism (22). Here, we employ the same strategy to assess the structural pattern of intradomain allostery by looking at the coupling fr...
Significance Hepatitis B virus (HBV) is a major pathogen, yet no fully effective therapies exist. HBc is the multifunctional, capsid-forming protein essential for HBV replication. HBc structural plasticity is reportedly functionally important. We analyzed the folding mechanism of HBc using a multidisciplinary approach, including microscale thermophoresis and ion mobility spectrometry–mass spectrometry. HBc folds in a 3-state transition with a dimeric, helical intermediate. We found evidence of a strained native ensemble wherein the energy landscapes for folding, allostery, and capsid formation are linked. Mutations thermodynamically trapped HBc in conformations unable to form capsids, suggesting chemical chaperones could elicit similar, potentially antiviral, effects.
Hepatitis B virus (HBV) is an infectious, potentially lethal human pathogen. However, there are no effective therapies for chronic HBV infections. Antiviral development is hampered by the lack of high-resolution structures for essential HBV protein-protein interactions. The interaction between preS1, an HBV surface-protein domain, and its human binding partner, γ2-adaptin, subverts the membrane-trafficking apparatus to mediate virion export. This interaction is a putative drug target. We report here atomic-resolution descriptions of the binding thermodynamics and structural biology of the interaction between preS1 and the EAR domain of γ2-adaptin. NMR, protein engineering, X-ray crystallography and MS showed that preS1 contains multiple γ2-EAR-binding motifs that mimic the membrane-trafficking motifs (and binding modes) of host proteins. These motifs localize together to a relatively rigid, functionally important region of preS1, an intrinsically disordered protein. The preS1-γ2-EAR interaction was relatively weak and efficiently outcompeted by a synthetic peptide. Our data provide the structural road map for developing peptidomimetic antivirals targeting the γ2-EAR-preS1 interaction.
Protein domains usually fold without or with only transiently populated intermediates, possibly to avoid misfolding, which could result in amyloidogenic disease. Whether observed intermediates are productive and obligatory species on the folding reaction pathway or dispensable by-products is a matter of debate. Here, we solved the crystal structure of a small protein domain, SAP97 PDZ2 I342W C378A, and determined its folding pathway. The presence of a folding intermediate was demonstrated both by single and double-mixing kinetic experiments using urea-induced (un)folding as well as ligand-induced folding. This protein domain was found to fold via a triangular scheme, where the folding intermediate could be either on-or off-pathway, depending on the experimental conditions. Furthermore, we found that the intermediate was present at equilibrium, which is rarely seen in folding reactions of small protein domains. The folding mechanism observed here illustrates the roughness and plasticity of the protein folding energy landscape, where several routes may be employed to reach the native state. The results also reconcile the folding mechanisms of topological variants within the PDZ domain family.The role and even the presence of intermediates in the folding reactions of protein domains are under constant debate (1, 2). Domains that fold without populated intermediates appear to have been selected for during evolution, possibly to avoid misfolding (3). Yet the polymeric nature of proteins implies their folding energy landscape to be rough (4), and clearly, intermediates do occur, sometimes as high energy species, which can only be indirectly monitored (5-7) but sometimes as low energy species, which can be observed directly (8 -14). One problem with studying these intermediates is that they are only transiently populated and thus difficult to isolate and characterize. A successful strategy to isolate folding intermediates has been to destabilize the native state by mutation, which works if the intermediate state is less destabilized by the modification (9,11,15,16). Further, general mechanisms of folding may be deduced if several members of a protein family are compared, for example regarding the influence of sequence and topology on the folding reaction (17-20). We have used this strategy on the PDZ domain family of proteins (21-24) and demonstrated that the folding reaction of all members investigated so far involves an intermediate, which at least in one case is on-pathway (6), often high energy, but off-pathway and low energy compared with the denatured state for a circularly permutated bacterial PDZ domain (25). Here we describe the folding reaction of SAP97 PDZ2 I342W C378A, referred to as pseudo-wild type PDZ2 (pwPDZ2). A triangular scheme explains the folding of this pwPDZ2. The intermediate in the scheme is of low energy and either on-or off-pathway depending on experimental conditions. The folding reaction of pwPDZ2 thus reflects the plasticity of the energy landscape for protein folding. We also discuss how ...
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