Solution structure of the first SRC homology 3 domain of human Nck2

Structural study of hNck2 SH3 domain protein in solution by circular dichroism and X-ray solution scattering

We have done conformational study of hNck2 SH3 domain by means of far-ultraviolet (far-UV) circular dichroism (CD) and X-ray solution scattering (XSS). The results indicated that the following: (1) hNck2 SH3 domain protein exhibited concentration dependent monomer-dimer transition at neutral pH, while the secondary structure of this protein was independent of the protein concentration. (2) The hNck2 SH3 domain also exhibited pH dependent monomer-dimer transition. This monomer-dimer transition was accompanied with helix-β transition of the secondary structural change. Moreover, the acid-induced conformation, which was previously studied by Liu and Song by CD and nuclear magnetic resonance (NMR), was found to be not compact, but the conformation of the protein at acidic pH was similar to the cold denatured state (C-state) reported by Yamada et al. for equine β-lactoglobulin. We calculated that a structure of the equilibrium helix-rich intermediate of the hNck2 SH3 domain by DAMMIF program.

Autoinhibitory interaction in the multidomain adaptor protein Nck: possible roles in improving specificity and functional diversity

Nck is a functionally versatile multidomain adaptor protein consisting of one SH2 and three SH3 domains. In most cases, the SH2 domain mediates binding to tyrosine-phosphorylated receptors or cytosolic proteins, which leads to the formation of larger protein complexes via the SH3 domains. Nck plays a pivotal role in T-cell receptor-mediated reorganization of the actin cytoskeleton as well as in the formation of the immunological synapses. The modular domain structure and the functionality of the individual domains suggest that they might act independently. Here we report an interesting intramolecular interaction within Nck that occurs between a noncanonical yet conserved (K/R)x(K/R)RxxS sequence in the linker between the first and second SH3 domain (SH3.1/SH3.2) and the second SH3 domain (SH3.2). Because this interaction masks the proline-rich sequence binding site of the SH3.2 domain, the intramolecular interaction is self-inhibitory. This intramolecular interaction could, at least partially, explain the remarkable specificity of Nck toward proteins with proline-rich sequences. It may prevent nonspecific low-affinity binding while keeping the site available for high-affinity bivalent ligands that can bind multiple sites in Nck. This indicates that Nck does not simply adopt a "beads on a string" architecture but incorporates a higher-order organization for improved specificity and functionality.

Insights into protein aggregation by NMR characterization of insoluble SH3 mutants solubilized in salt-free water

Protein aggregation in vivo has been extensively associated with a large spectrum of human diseases. On the other hand, mechanistic insights into protein aggregation in vitro were incomplete due to the inability in solubilizing insoluble proteins for high-resolution biophysical investigations. However, a new avenue may be opened up by our recent discovery that previously-thought insoluble proteins can in fact be solubilized in salt-free water. Here we use this approach to study the NMR structural and dynamic properties of an insoluble SH3 mutant with a naturally-occurring insertion of Val22 at the tip of the diverging turn. The obtained results reveal: 1) regardless of whether the residue is Val, Ala, Asp or Arg, the insertion will render the first hNck2 SH3 domain to be insoluble in buffers. Nevertheless, all four mutants could be solubilized in salt-free water and appear to be largely unfolded as evident from their CD and NMR HSQC spectra. 2) Comparison of the chemical shift deviations reveals that while in V22-SH3 the second helical region is similarly populated as in the wild-type SH3 at pH 2.0, the first helical region is largely unformed. 3) In V22-SH3, many non-native medium-range NOEs manifest to define non-native helical conformations. In the meanwhile a small group of native-like long-range NOEs still persists, indicating the existence of a rudimentary native-like tertiary topology. 4) Although overall, V22-SH3 has significantly increased backbone motions on the ps-ns time scale, some regions still own restricted backbone motions as revealed by analyzing ¹⁵N relaxation data. Our study not only leads to the establishment of the first high-resolution structural and dynamic picture for an insoluble protein, but also shed more light on the molecular events for the nonhierarchical folding mechanism. Furthermore, a general mechanism is also proposed for in vivo protein aggregation triggered by the genetic mutation and posttranslational modification.

Alternate 13C-12C labeling for complete mainchain resonance assignments using C alpha direct-detection with applicability toward fast relaxing protein systems

Experiments that use direct (13)C detection and take advantage of the slower relaxation of (13)C magnetization compared to (1)H offer an attractive strategy for extending the limits of NMR to include larger, highly dynamic, or paramagnetic proteins. Because carbonyl carbons ((13)C') suffer from serious relaxation enhancement as a consequence of their large chemical shift anisotropy, deuterated alpha carbons are the preferred nuclei for (13)C detection in large and/or fast relaxing systems. However, direct detection of (13)C alpha is not straightforward owing to the presence of one-bond (13)C-(13)C couplings with (13)C' and (13)C beta that split the signals into multiples and hence reduce the sensitivity. Here we present the use of (13)C enrichment at alternating carbon sites and deuteration at the C alpha position to overcome these difficulties. The desired labeling pattern is achieved by expressing the protein in E. coli in D(2)O with either [2-(13)C] or [1,3-(13)C] glycerol as the carbon source. With this labeling strategy, we show that complete assignment of the main chain (including prolyl residues) can be achieved with a single CaN HSQC experiment. This approach offers advantages for the detection of NMR signals from sites with fast nuclear relaxation and offers promise for investigations of larger proteins and/or protein complexes that are inaccessible by proton-detected experiments.

Interaction between the N-terminal SH3 domain of Nck-alpha and CD3-epsilon-derived peptides: non-canonical and canonical recognition motifs

The first SH3 domain (SH3.1) of Nckalpha specifically recognizes the proline-rich region of CD3varepsilon, a subunit of the T cell receptor complex. We have solved the NMR structure of Nckalpha SH3.1 that shows the characteristic SH3 fold consisting of two antiparallel beta-sheets tightly packed against each other. According to chemical shift mapping analysis, a peptide encompassing residues 150-166 of CD3varepsilon binds at the canonical SH3 binding site. An exhaustive comparison with the structures of other SH3 domains able and unable to bind CD3varepsilon reveals that Nckalpha SH3.1 recognises a non-canonical PxxPxxDY motif that orientates at the binding site as a class II ligand. A positively charged residue (K/R) at position -2 relative to the WW sequence at the beginning of strand beta3 is crucial for PxxDY recognition. A 14-mer optimised Nckalpha SH3.1 ligand was found using a multi-substitution approach. Based on NMR data, this improved ligand binds Nckalpha SH3.1 through a PxxPxRDY motif that combines specific stabilising interactions corresponding to both canonical class II, PxxPx(K/R), and non-canonical PxxPxxDY motifs. This explains its higher capacity for Nckalpha SH3.1 binding relative to the wild type sequence.

NMR evidence for forming highly populated helical conformations in the partially folded hNck2 SH3 domain

Recent studies of several proteins implied that the folding of beta-proteins may follow a nonhierarchical mechanism in which two major transitions are essential, i.e., the collapse of a random coil to form a nonnative helical intermediate, followed by a transformation into the native beta-structure. We report that the first hNck2 SH3 domain, assuming an all-beta barrel in the native form, can be reversibly transformed into a stable and nonnative helical state by acid-unfolding. We also conducted extensive NMR and mutagenesis studies that led to two striking findings: 1), NMR analysis reveals that in the helical state formed at pH 2.0, the first and last beta-strands in the native form become unstructured, whereas the rest is surprisingly converted into two highly populated helices with a significantly limited backbone motion; and 2), a conserved four-residue sequence is identified on the second beta-strand, a mutation of which suddenly renders the SH3 domain into a helical state even at pH 6.5, with NMR conformational and dynamic properties highly similar to those of the wild-type at pH 2.0. This observation implies that the region might contribute key interactions to disrupt the helical state, and to facilitate a further transformation into the native SH3 fold in the second transition.

Structural and functional evidence that Nck interaction with CD3epsilon regulates T-cell receptor activity

Recruitment of signaling molecules to the cytoplasmic domains of the CD3 subunits of the T-cell receptor (TCR) is crucial for early T-cell activation. These transient associations either do or do not require tyrosine phosphorylation of CD3 immune tyrosine activation motifs (ITAMs). Here we show that the non-ITAM-requiring adaptor protein Nck forms a complex with an atypical PxxDY motif of the CD3epsilon tail, which encompasses Tyr166 within the ITAM and a TCR endocytosis signal. As suggested by the structure of the complex, we find that Nck binding inhibits phosphorylation of the CD3epsilon ITAM by Fyn and Lck kinases in vitro. Moreover, the CD3epsilon-Nck interaction downregulates TCR surface expression upon physiological stimulation in mouse primary lymph node cells. This indicates that Nck performs an important regulatory function in T lymphocytes by inhibiting ITAM phosphorylation and/or removing cell surface TCR via CD3epsilon interaction.

Specificity determinants of a novel Nck interaction with the juxtamembrane domain of the epidermal growth factor receptor

Nck is a ubiquitously expressed adaptor protein containing Src homology 2 (SH2) and Src homology 3 (SH3) domains. It integrates downstream effector proteins with cell membrane receptors, such as the epidermal growth factor receptor (EGFR). EGFR plays a critical role in cellular proliferation and differentiation. The 45-residue juxtamembrane domain of EGFR (JM), located between the transmembrane and kinase domains, regulates receptor activation and trafficking to the basolateral membrane of polarized epithelia through a proline-rich motif that resembles a consensus SH3 domain binding site. We demonstrate here that the JM region can bind to Nck, showing a notable binding preference for the second SH3 domain. To elucidate the structural determinants for this interaction, we have determined the NMR solution structures of both the first and second Nck SH3 domains (Nck1-1 and Nck1-2). These domains adopt a canonical SH3 beta-barrel-like fold, containing five antiparallel strands separated by three loop regions and one 3 10-helical turn. Chemical shift perturbation studies have identified the residues that form the binding cleft of Nck1-2, which are primarily located in the RT and n-Src loops. JM binds to Nck1-2 with an affinity of approximately 80 microM through a positively charged sequence near the N-terminus, as opposed to the polyproline sequence. The two Nck SH3 domains exhibit both steric and electrostatic differences in their RT-Src and n-Src loops, and a model of the Nck1-2 domain complexed with the JM highlights the factors that define the putative binding mode for this ligand.

Reciprocal regulation of SH3 and SH2 domain binding via tyrosine phosphorylation of a common site in CD3epsilon

Recruitment of cellular signaling proteins by the CD3 polypeptides of the TCR complex mediates T cell activation. We have screened a human Src homology 3 (SH3) domain phage display library for proteins that can bind to the proline-rich region of CD3epsilon. This screening identified Eps8L1 (epidermal growth factor receptor pathway substrate 8-like 1) together with the N-terminal SH3 domain of Nck1 and Nck2 as its preferred SH3 partners. Studies with recombinant proteins confirmed strong binding of CD3epsilon to Eps8L1 and Nck SH3 domains. CD3epsilon bound well also to Eps8 and Eps8L3, and modestly to Eps8L2, but not detectably to other SH3 domains tested. Interestingly, binding of Nck and Eps8L1 SH3 domains was mapped to a PxxDY motif that shared its tyrosine residue (Y166) with the ITAM of CD3epsilon. Phosphorylation of this residue abolished binding of Eps/Nck SH3 domains in peptide spot filter assays, as well as in cells cotransfected with a dominantly active Lck kinase. TCR ligation-induced binding and phosphorylation-dependent loss of binding were also demonstrated between Eps8L1 and endogenous CD3epsilon in Jurkat T cells. Thus, phosphorylation of Y166 serves as a molecular switch during T cell activation that determines the capacity of CD3epsilon to interact with either SH3 or SH2 domain-containing proteins.

1-13C amino acid selective labeling in a 2H15N background for NMR studies of large proteins

Isotope labeling by residue type (LBRT) has long been an important tool for resonance assignments at the limit where other approaches, such as triple-resonance experiments or NOESY methods do not succeed in yielding complete assignments. While LBRT has become less important for small proteins it can be the method of last resort for completing assignments of the most challenging protein systems. Here we present an approach where LBRT is achieved by adding protonated (14)N amino acids that are (13)C labeled at the carbonyl position to a medium for uniform deuteration and (15)N labeling. This has three important benefits over conventional (15)N LBRT in a deuterated back ground: (1) selective TROSY-HNCO cross peaks can be observed with high sensitivity for amino-acid pairs connected by the labeling, and the amide proton of the residue following the (13)C labeled amino acid is very sharp since its alpha position is deuterated, (2) the (13)C label at the carbonyl position is less prone to scrambling than the (15)N at the alpha-amino position, and (3) the peaks for the 1-(13)C labeled amino acids can be identified easily from the large intensity reduction in the (1)H-(15)N TROSY-HSQC spectrum for some residues that do not significantly scramble nitrogens, such as alanine and tyrosine. This approach is cost effective and has been successfully applied to proteins larger than 40 kDa.

Resurrecting abandoned proteins with pure water: CD and NMR studies of protein fragments solubilized in salt-free water

Many proteins expressed in Escherichia coli cells form inclusion bodies that are neither refoldable nor soluble in buffers. Very surprisingly, we recently discovered that all 11 buffer-insoluble protein fragments/domains we have, with a great diversity of cellular function, location, and molecular size, could be easily solubilized in salt-free water. The circular dichroism (CD) and NMR characterization led to classification of these proteins into three groups: group 1, with no secondary structure by CD and with narrowly-dispersed but sharp (1)H-(15)N heteronuclear single quantum correlation (HSQC) peaks; group 2, with secondary structure by CD but with HSQC peaks broadened and, consequently, only a small set of peaks detectable; and group 3, with secondary structure by CD and also well-separated HSQC peaks. Intriguingly, we failed to find any protein with a tight tertiary packing. Therefore, we propose that buffer-insoluble proteins may lack intrinsic ability to reach or/and to maintain a well-packed conformation, and thus are trapped in partially-folded states with many hydrophobic side chains exposed to the bulk solvent. As such, a very low ionic strength is sufficient to screen out intrinsic repulsive interactions and, consequently, allow the hydrophobic clustering/aggregation to occur. Marvelously enough, it appears that in pure water, proteins have the potential to manifest their full spectrum of structural states by utilizing intrinsic repulsive interactions to suppress the attractive hydrophobic clustering. Our discovery not only gives a novel insight into the properties of insoluble proteins, but also sheds the first light that we know of on previously unknown regimes associated with proteins.