Fluorinated Ethylamines as Electrospray-Compatible Neutral pH Buffers for Native Mass Spectrometry.

Native electrospray ionization mass spectrometry (ESI-MS) has emerged as a potent tool for examining the native-like structures of macromolecular complexes. Despite its utility, the predominant "buffer" used, ammonium acetate (AmAc) with pKa values of 4.75 for acetic acid and 9.25 for ammonium, provides very little buffering capacity within the physiological pH range of 7.0-7.4. ESI-induced redox reactions alter the pH of the liquid within the ESI capillary. This can result in protein unfolding or weakening of pH-sensitive interactions. Consequently, the discovery of volatile, ESI-compatible buffers, capable of effectively maintaining pH within a physiological range, is of high importance. Here, we demonstrate that 2,2-difluoroethylamine (DFEA) and 2,2,2-trifluoroethylamine (TFEA) offer buffering capacity at physiological pH where AmAc falls short, with pKa values of 7.2 and 5.5 for the conjugate acids of DFEA and TFEA, respectively. Native ESI-MS experiments on model proteins cytochrome c and myoglobin electrosprayed with DFEA and TFEA demonstrated the preservation of noncovalent protein-ligand complexes in the gas phase. Protein stability assays and collision-induced unfolding experiments further showed that neither DFEA nor TFEA destabilized model proteins in solution or in the gas phase. Finally, we demonstrate that multisubunit protein complexes such as alcohol dehydrogenase and concanavalin A can be studied in the presence of DFEA or TFEA using native ESI-MS. Our findings establish DFEA and TFEA as new ESI-compatible neutral pH buffers that promise to bolster the use of native ESI-MS for the analysis of macromolecular complexes, particularly those sensitive to pH fluctuations.

A methyl-TROSY approach for NMR studies of high-molecular-weight DNA with application to the nucleosome core particle.

The development of methyl-transverse relaxation-optimized spectroscopy (methyl-TROSY)-based NMR methods, in concert with robust strategies for incorporation of methyl-group probes of structure and dynamics into the protein of interest, has facilitated quantitative studies of high-molecular-weight protein complexes. Here we develop a one-pot in vitro reaction for producing NMR quantities of methyl-labeled DNA at the C5 and N6 positions of cytosine (5mC) and adenine (6mA) nucleobases, respectively, enabling the study of high-molecular-weight DNA molecules using TROSY approaches originally developed for protein applications. Our biosynthetic strategy exploits the large number of naturally available methyltransferases to specifically methylate DNA at a desired number of sites that serve as probes of structure and dynamics. We illustrate the methodology with studies of the 153-base pair Widom DNA molecule that is simultaneously methyl-labeled at five sites, showing that high-quality 13C-1H spectra can be recorded on 100 µM samples in a few minutes. NMR spin relaxation studies of labeled methyl groups in both DNA and the H2B histone protein component of the 200-kDa nucleosome core particle (NCP) establish that methyl groups at 5mC and 6mA positions are, in general, more rigid than Ile, Leu, and Val methyl probes in protein side chains. Studies focusing on histone H2B of NCPs wrapped with either wild-type DNA or DNA methylated at all 26 CpG sites highlight the utility of NMR in investigating the structural dynamics of the NCP and how its histone core is affected through DNA methylation, an important regulator of transcription.

Reversible inhibition of the ClpP protease via an N-terminal conformational switch.

Protein homeostasis is critically important for cell viability. Key to this process is the refolding of misfolded or aggregated proteins by molecular chaperones or, alternatively, their degradation by proteases. In most prokaryotes and in chloroplasts and mitochondria, protein degradation is performed by the caseinolytic protease ClpP, a tetradecamer barrel-like proteolytic complex. Dysregulating ClpP function has shown promise in fighting antibiotic resistance and as a potential therapy for acute myeloid leukemia. Here we use methyl-transverse relaxation-optimized spectroscopy (TROSY)-based NMR, cryo-EM, biochemical assays, and molecular dynamics simulations to characterize the structural dynamics of ClpP from Staphylococcus aureus (SaClpP) in wild-type and mutant forms in an effort to discover conformational hotspots that regulate its function. Wild-type SaClpP was found exclusively in the active extended form, with the N-terminal domains of its component protomers in predominantly ß-hairpin conformations that are less well-defined than other regions of the protein. A hydrophobic site was identified that, upon mutation, leads to unfolding of the N-terminal domains, loss of SaClpP activity, and formation of a previously unobserved split-ring conformation with a pair of 20-Å-wide pores in the side of the complex. The extended form of the structure and partial activity can be restored via binding of ADEP small-molecule activators. The observed structural plasticity of the N-terminal gates is shown to be a conserved feature through studies of Escherichia coli and Neisseria meningitidis ClpP, suggesting a potential avenue for the development of molecules to allosterically modulate the function of ClpP.

ClpB N-terminal domain plays a regulatory role in protein disaggregation.

ClpB/Hsp100 is an ATP-dependent disaggregase that solubilizes and reactivates protein aggregates in cooperation with the DnaK/Hsp70 chaperone system. The ClpB-substrate interaction is mediated by conserved tyrosine residues located in flexible loops in nucleotide-binding domain-1 that extend into the ClpB central pore. In addition to the tyrosines, the ClpB N-terminal domain (NTD) was suggested to provide a second substrate-binding site; however, the manner in which the NTD recognizes and binds substrate proteins has remained elusive. Herein, we present an NMR spectroscopy study to structurally characterize the NTD-substrate interaction. We show that the NTD includes a substrate-binding groove that specifically recognizes exposed hydrophobic stretches in unfolded or aggregated client proteins. Using an optimized segmental labeling technique in combination with methyl-transverse relaxation optimized spectroscopy (TROSY) NMR, the interaction of client proteins with both the NTD and the pore-loop tyrosines in the 580-kDa ClpB hexamer has been characterized. Unlike contacts with the tyrosines, the NTD-substrate interaction is independent of the ClpB nucleotide state and protein conformational changes that result from ATP hydrolysis. The NTD interaction destabilizes client proteins, priming them for subsequent unfolding and translocation. Mutations in the NTD substrate-binding groove are shown to have a dramatic effect on protein translocation through the ClpB central pore, suggesting that, before their interaction with substrates, the NTDs block the translocation channel. Together, our findings provide both a detailed characterization of the NTD-substrate complex and insight into the functional regulatory role of the ClpB NTD in protein disaggregation.

(13)CHD2-CEST NMR spectroscopy provides an avenue for studies of conformational exchange in high molecular weight proteins.

An NMR experiment for quantifying slow (millisecond) time-scale exchange processes involving the interconversion between visible ground state and invisible, conformationally excited state conformers is presented. The approach exploits chemical exchange saturation transfer (CEST) and makes use of (13)CHD2 methyl group probes that can be readily incorporated into otherwise highly deuterated proteins. The methodology is validated with an application to a G48A Fyn SH3 domain that exchanges between a folded conformation and a sparsely populated and transiently formed unfolded ensemble. Experiments on a number of different protein systems, including a 360 kDa half-proteasome, establish that the sensitivity of this (13)CHD2 (13)C-CEST technique can be upwards of a factor of 5 times higher than for a previously published (13)CH3 (13)C-CEST approach (Bouvignies and Kay in J Biomol NMR 53:303-310, 2012), suggesting that the methodology will be powerful for studies of conformational exchange in high molecular weight proteins.

Requirement for kinase-induced conformational change in eukaryotic initiation factor 2alpha (eIF2alpha) restricts phosphorylation of Ser51.

As phosphorylation of eukaryotic translation initiation factor 2α (eIF2α) on Ser51 inhibits protein synthesis, cells restrict this phosphorylation to the antiviral protein kinase PKR and related eIF2α kinases. In the crystal structure of the PKR-eIF2α complex, the C-terminal lobe of the kinase contacts eIF2α on a face remote from Ser51, leaving Ser51 ∼ 20 Å from the kinase active site. PKR mutations that cripple the eIF2α-binding site impair phosphorylation; here, we identify mutations in eIF2α that restore Ser51 phosphorylation by PKR with a crippled substrate-binding site. These eIF2α mutations either disrupt a hydrophobic network that restricts the position of Ser51 or alter a linkage between the PKR-docking region and the Ser51 loop. We propose that the protected state of Ser51 in free eIF2α prevents promiscuous phosphorylation and the attendant translational regulation by heterologous kinases, whereas docking of eIF2α on PKR induces a conformational change that regulates the degree of Ser51 exposure and thus restricts phosphorylation to the proper kinases.

Measurement of active site ionization equilibria in the 670 kDa proteasome core particle using methyl-TROSY NMR.

The 20S proteasome core particle is a molecular machine that plays a central role in the regulation of cellular function through proteolysis, and it has emerged as a valuable drug target for certain classes of cancers. Central to the development of new and potent pharmaceuticals is an understanding of the mechanism by which the proteasome cleaves substrates. A number of high-resolution structures of the 20S proteasome with and without inhibitors have emerged that provide insight into the chemistry of peptide bond cleavage and establish the role of Thr1 Oγ1 as the catalytic nucleophile. The source of the base that accepts the Thr1 Hγ1 is less clear. Using a highly deuterated sample of the proteasome labeled with (13)CH3 at the Thr-γ positions, the pKA of the Thr1 amino group has been measured to be 6.3 and hence deprotonated in the range of maximal enzyme activity. This provides strong evidence that the terminal amino group of Thr1 serves as the base in the first step of the peptide bond cleavage reaction.

Quantifying millisecond exchange dynamics in proteins by CPMG relaxation dispersion NMR using side-chain 1H probes.

A Carr-Purcell-Meiboom-Gill relaxation dispersion experiment is presented for quantifying millisecond time-scale chemical exchange at side-chain (1)H positions in proteins. Such experiments are not possible in a fully protonated molecule because of magnetization evolution from homonuclear scalar couplings that interferes with the extraction of accurate transverse relaxation rates. It is shown, however, that by using a labeling strategy whereby proteins are produced using {(13)C,(1)H}-glucose and D(2)O a significant number of 'isolated' side-chain (1)H spins are generated, eliminating such effects. It thus becomes possible to record (1)H dispersion profiles at the ß positions of Asx, Cys, Ser, His, Phe, Tyr, and Trp as well as the γ positions of Glx, in addition to the methyl side-chain moieties. This brings the total of amino acid side-chain positions that can be simultaneously probed using a single (1)H dispersion experiment to 16. The utility of the approach is demonstrated with an application to the four-helix bundle colicin E7 immunity protein, Im7, which folds via a partially structured low populated intermediate that interconverts with the folded, ground state on the millisecond time-scale. The extracted (1)H chemical shift differences at side-chain positions provide valuable restraints in structural studies of invisible, excited states, complementing backbone chemical shifts that are available from existing relaxation dispersion experiments.

NMR characterization of copper-binding domains 4-6 of ATP7B .

The Wilson disease protein (ATP7B) is a copper-transporting member of the P-type ATPase superfamily, which plays a central role in copper homeostasis and interacts with the copper chaperone Atox1. The N-terminus of ATP7B is comprised of six copper-binding domains (WCBDs), each capable of binding one copper atom in the +1 oxidation state. To better understand the regulatory effect of copper binding to these domains, we have performed NMR characterization of WCBD4-6 (domains 4-6 of ATP7B). (15)N relaxation measurements on the apo and Cu(I)-bound WCBD4-6 show that there is no dramatic change in the dynamic properties of this three-domain construct; the linker between domains 4 and 5 remains flexible, domains 5 and 6 do not form a completely rigid dimer but rather have some flexibility with respect to each other, and there is minimal change in the relative orientation of the domains in the two states. We also show that, contrary to previous reports, the protein-protein interaction between Atox1 and the copper-binding domains takes place even in the absence of copper. Comparison of apo and Cu(I)-bound spectra of WCBD1-6 shows that binding of Cu(I) does not induce the formation of a unit that tumbles as a single entity, consistent with our results for WCBD4-6. We propose that copper transfer to and between the N-terminal domains of the Wilson Cu-ATPase occurs via protein interactions that are facilitated by the flexibility of the linkers and the motional freedom of the domains with respect to each other.

A simple strategy for ¹³C, ¹H labeling at the Ile-γ2 methyl position in highly deuterated proteins.

A straightforward approach for the production of highly deuterated proteins labeled with ¹³C and ¹H at Ile-γ2 methyl positions is described. The utility of the methodology is illustrated with an application involving the half proteasome (360 kDa). High quality 2D Ile ¹³C(γ)²,¹H(γ)² HMQC data sets, exploiting the methyl-TROSY principle, are recorded with excellent sensitivity and resolution, that compare favorably with Ile ¹³C(δ)¹,¹H(δ)¹ spectra. This labeling scheme adds to a growing list of different approaches that are significantly impacting the utility of solution NMR spectroscopy in studies of supra-molecular systems.

Assignment of Ile, Leu, and Val methyl correlations in supra-molecular systems: an application to aspartate transcarbamoylase.

A number of complementary approaches for the assignment of Ile, Leu, and Val methyl groups in Methyl-TROSY spectra of supra-molecular protein complexes are presented and compared. This includes the transfer of assignments from smaller fragments to the complex using a "divide-and-conquer" approach, assignment transfer via exchange spectroscopy, or, alternatively, generating assignments of the complex through the measurement of pseudocontact shifts, facilitated by the introduction of paramagnetic probes. The methodology is applied to the assignment of the regulatory chains in the 300 kDa enzyme aspartate transcarbamoylase, ATCase. The "divide-and-conquer" method that has proven to be very powerful in applications to other systems produced assignments for approximately 60% of the observed methyl groups in TROSY maps of ATCase. By contrast, the combination of all approaches led to assignments for 86% of the methyls, providing a large number of probes of structure and dynamics. The derived assignments were used to interpret chemical shift changes of ATCase upon titration with the nucleotide ATP. Large shift changes in the N-terminal tails of the regulatory chain provide the first evidence for structural perturbations in a region that is known to play a critical role on the effect of nucleotide binding on distal catalytic sites of this allosteric enzyme.

Conserved conformational selection mechanism of Hsp70 chaperone-substrate interactions.

Molecular recognition is integral to biological function and frequently involves preferred binding of a molecule to one of several exchanging ligand conformations in solution. In such a process the bound structure can be selected from the ensemble of interconverting ligands a priori (conformational selection, CS) or may form once the ligand is bound (induced fit, IF). Here we focus on the ubiquitous and conserved Hsp70 chaperone which oversees the integrity of the cellular proteome through its ATP-dependent interaction with client proteins. We directly quantify the flux along CS and IF pathways using solution NMR spectroscopy that exploits a methyl TROSY effect and selective isotope-labeling methodologies. Our measurements establish that both bacterial and human Hsp70 chaperones interact with clients by selecting the unfolded state from a pre-existing array of interconverting structures, suggesting a conserved mode of client recognition among Hsp70s and highlighting the importance of molecular dynamics in this recognition event.

An economical method for production of (2)H, (13)CH3-threonine for solution NMR studies of large protein complexes: application to the 670 kDa proteasome.

NMR studies of very high molecular weight protein complexes have been greatly facilitated through the development of labeling strategies whereby (13)CH(3) methyl groups are introduced into highly deuterated proteins. Robust and cost-effective labeling methods are well established for all methyl containing amino acids with the exception of Thr. Here we describe an inexpensive biosynthetic strategy for the production of L-[α-(2)H; ß-(2)H;γ-(13)C]-Thr that can then be directly added during protein expression to produce highly deuterated proteins with Thr methyl group probes of structure and dynamics. These reporters are particularly valuable, because unlike other methyl containing amino acids, Thr residues are localized predominantly to the surfaces of proteins, have unique hydrogen bonding capabilities, have a higher propensity to be found at protein nucleic acid interfaces and can play important roles in signaling pathways through phosphorylation. The utility of the labeling methodology is demonstrated with an application to the 670 kDa proteasome core particle, where high quality Thr (13)C,(1)H correlation spectra are obtained that could not be generated from samples prepared with commercially available U-[(13)C,(1)H]-Thr.

Cross-validation of the structure of a transiently formed and low populated FF domain folding intermediate determined by relaxation dispersion NMR and CS-Rosetta.

We have recently reported the atomic resolution structure of a low populated and transiently formed on-pathway folding intermediate of the FF domain from human HYPA/FBP11 [Korzhnev, D. M.; Religa, T. L.; Banachewicz, W.; Fersht, A. R.; Kay, L.E. Science 2011, 329, 1312-1316]. The structure was determined on the basis of backbone chemical shift and bond vector orientation restraints of the invisible intermediate state measured using relaxation dispersion nuclear magnetic resonance (NMR) spectroscopy that were subsequently input into the database structure determination program, CS-Rosetta. As a cross-validation of the structure so produced, we present here the solution structure of a mimic of the folding intermediate that is highly populated in solution, obtained from the wild-type domain by mutagenesis that destabilizes the native state. The relaxation dispersion/CS-Rosetta structures of the intermediate are within 2 Å of those of the mimic, with the nonnative interactions in the intermediate also observed in the mimic. This strongly confirms the structure of the FF domain folding intermediate, in particular, and validates the use of relaxation dispersion derived restraints in structural studies of invisible excited states, in general.

Application of methyl-TROSY NMR to test allosteric models describing effects of nucleotide binding to aspartate transcarbamoylase.

Aspartate transcarbamoylase has emerged as a textbook example of an allosteric enzyme whose binding of active-site substrates can be explained on the basis of the classical Monod-Wyman-Changeux (MWC) model of allostery. There is still debate, however, regarding the mode of action of ATP and cytidine triphosphate (CTP)--allosteric effectors that bind at regulatory sites 60 A away from the nearest active site. A large body of data for nucleotide binding is consistent with the MWC model, including a previous NMR study showing a shift in the allosteric equilibrium between R and T states that is predicted by this scheme. The possibility of binding-promoted changes to the structures of the active sites, while not within the framework of the MWC model, cannot be excluded, however. Here, the effects of binding of nucleotides are monitored in a series of (1)H-(13)C methyl transverse relaxation optimized spectroscopy spectra recorded on the 300-kDa aspartate transcarbamoylase holoenzyme in both the absence and the presence of saturating amounts of ATP or CTP. No changes in shifts of methyl probes of the catalytic chains (c-chains) that include the active sites are observed, consistent with a lack of structural changes. In addition, methyl (1)H-(13)C residual dipolar couplings are measured that are exquisitely sensitive to methyl axis orientations, and correlations between couplings measured on samples with and without nucleotide show no changes in structure of the c-chains. These results indicate that the mechanism of action of ATP and CTP can be explained fully by the MWC model and that any scheme invoking structural changes of the c-chains is not correct.

The structure of alpha-parvin CH2-paxillin LD1 complex reveals a novel modular recognition for focal adhesion assembly.

Alpha-parvin is an essential component of focal adhesions (FAs), which are large multiprotein complexes that link the plasma membrane and actin cytoskeleton. Alpha-parvin contains two calponin homology (CH) domains and its C-terminal CH2 domain binds multiple targets including paxillin LD motifs for regulating the FA network and signaling. Here we describe the solution structure of alpha-parvin CH2 bound to paxillin LD1. We show that although CH2 contains the canonical CH-fold, a previously defined N-terminal linker forms an alpha-helix that packs unexpectedly with the C-terminal helix of CH2, resulting in a novel variant of the CH domain. Importantly, such packing generates a hydrophobic surface that recognizes the Leu-rich face of paxillin-LD1, and the binding pattern differs drastically from the classical paxillin-LD binding to four-helix bundle proteins such as focal adhesion kinase. These results define a novel modular recognition mode and reveal how alpha-parvin associates with paxillin to mediate the FA assembly and signaling.

Solution NMR of supramolecular complexes: providing new insights into function.

Solution NMR spectroscopy is an extremely powerful technology for the study of biomolecular dynamics and site-specific molecular interactions. An important limitation in the past has been molecule size, with molecular weights of targets seldom exceeding 50 kDa. New labeling technology and NMR experiments are changing this paradigm so that applications for investigating supramolecular complexes are starting to become feasible. Here we describe a strategy developed in our laboratory that involves the use of labeled methyl groups of isoleucine, leucine and valine residues in proteins as probes, along with experiments that significantly enhance the lifetimes of the resulting signals. We describe the application of these methods to a number of systems with molecular weights in the hundreds of kilodaltons.

A solution NMR study showing that active site ligands and nucleotides directly perturb the allosteric equilibrium in aspartate transcarbamoylase.

The 306-kDa aspartate transcarbamoylase is a well studied regulatory enzyme, and it has emerged as a paradigm for understanding allostery and cooperative binding processes. Although there is a consensus that the cooperative binding of active site ligands follows the Monod-Wyman-Changeux (MWC) model of allostery, there is some debate about the binding of effectors such as ATP and CTP and how they influence the allosteric equilibrium between R and T states of the enzyme. In this article, the binding of substrates, substrate analogues, and nucleotides is studied, along with their effect on the R-T equilibrium by using highly deuterated, (1)H,(13)C-methyl-labeled protein in concert with methyl-transverse relaxation optimized spectroscopy (TROSY) NMR. Although only the T state of the enzyme can be observed in spectra of wild-type unliganded aspartate transcarbamoylase, binding of active-site substrates shift the equilibrium so that correlations from the R state become visible, allowing the equilibrium constant (L') between ligand-saturated R and T forms of the enzyme to be measured quantitatively. The equilibrium constant between unliganded R and T forms (L) also is obtained, despite the fact that the R state is "invisible" in spectra, by means of an indirect process that makes use of relations that emerge from the fact that ligand binding and the R-T equilibrium are linked. Titrations with MgATP unequivocally establish that its binding directly perturbs the R-T equilibrium, consistent with the Monod-Wyman-Changeux model. This study emphasizes the utility of modern solution NMR spectroscopy in understanding protein function, even for systems with aggregate molecular masses in the hundreds of kilodaltons.

Structure of an ultraweak protein-protein complex and its crucial role in regulation of cell morphology and motility.

Weak protein-protein interactions (PPIs) (K(D) > 10(-6) M) are critical determinants of many biological processes. However, in contrast to a large growing number of well-characterized, strong PPIs, the weak PPIs, especially those with K(D) > 10(-4) M, are poorly explored. Genome wide, there exist few 3D structures of weak PPIs with K(D) > 10(-4) M, and none with K(D) > 10(-3) M. Here, we report the NMR structure of an extremely weak focal adhesion complex (K(D) approximately 3 x 10(-3) M) between Nck-2 SH3 domain and PINCH-1 LIM4 domain. The structure exhibits a remarkably small and polar interface with distinct binding modes for both SH3 and LIM domains. Such an interface suggests a transient Nck-2/PINCH-1 association process that may trigger rapid focal adhesion turnover during integrin signaling. Genetic rescue experiments demonstrate that this interface is indeed involved in mediating cell shape change and migration. Together, the data provide a molecular basis for an ultraweak PPI in regulating focal adhesion dynamics during integrin signaling.

Variable control of Ets-1 DNA binding by multiple phosphates in an unstructured region.

Cell signaling that culminates in posttranslational modifications directs protein activity. Here we report how multiple Ca2+-dependent phosphorylation sites within the transcription activator Ets-1 act additively to produce graded DNA binding affinity. Nuclear magnetic resonance spectroscopic analyses show that phosphorylation shifts Ets-1 from a dynamic conformation poised to bind DNA to a well-folded inhibited state. These phosphates lie in an unstructured flexible region that functions as the allosteric effector of autoinhibition. Variable phosphorylation thus serves as a "rheostat" for cell signaling to fine-tune transcription at the level of DNA binding.