Making ends meet: the importance of the N- and C-termini for the structure, stability, and function of the third SH3 domain of CIN85.

SH3 domains are common structure, interaction, and regulation modules found in more than 200 human proteins. In this report, we studied the third SH3 domain from the human CIN85 adaptor protein, which plays an important role in both receptor tyrosine kinase downregulation and phosphatidylinositol 3 kinase inhibition. The structure of this domain includes an additional 90° kink after the last canonical ß-strand and features unusual interactions between the termini well outside the boundaries of the standard SH3 domain definition. The extended portions of the domain are well-structured and held together entirely by side chain-side chain interactions. Extensive expression screening showed that these additional contacts provide significantly increased stability to the domain. A similar 90° kink is found in only one other SH3 domain structure, while side chain contacts linking the termini have never been described before. As a result of the increased size of CIN85 SH3 domain C, the proximal proline rich region is positioned such that a possible intramolecular interaction is structurally inhibited. Using the key interactions of the termini as the basis for sequence analysis allowed the identification of several SH3 domains with flanking sequences that could adopt similar structures. This work illustrates the importance of careful experimental analysis of domain boundaries even for a well-characterized fold such as the SH3 domain.

A complex of Shc and Ran-GTPase localises to the cell nucleus.

The three isoforms of the adaptor protein Shc play diverse roles in cell signalling. For example, the observation of p46 Shc in the nuclei of hepatocellular carcinoma cells suggests a function quite distinct from the better characterised cytoplasmic role. Ligands responsible for the transport of various Shc isoforms into organelles such as the nucleus have yet to be reported. To identify such ligands a far western approach was used to determine the p52 Shc interactome. The Ran-GTPase nuclear transport protein was identified and found to bind to p52 Shc in vitro with low micromolar affinity. Co-immunoprecipitation, pull down and fluorescence lifetime imaging microscopy experiments in stable cells confirmed cellular interaction and nuclear localisation. The nuclear transport factor protein NTF2, which functions in cohort with Ran, was shown to form a complex with both RAN and Shc, suggesting a mechanism for Shc entry into the nucleus as part of a tertiary complex.

Phosphorylation of threonine residues on Shc promotes ligand binding and mediates crosstalk between MAPK and Akt pathways in breast cancer cells.

Scaffold proteins play important roles in regulating signalling network fidelity, the absence of which is often the basis for diseases such as cancer. In the present work, we show that the prototypical scaffold protein Shc is phosphorylated by the extracellular signal-regulated kinase, Erk. In addition, Shc threonine phosphorylation is specifically up-regulated in two selected triple-negative breast cancer (TNBC) cell lines. To explore how Erk-mediated threonine phosphorylation on Shc might play a role in the dysregulation of signalling events, we investigated how Shc affects pathways downstream of EGF receptor. Using an in vitro model and biophysical analysis, we show that Shc threonine phosphorylation is responsible for elevated Akt and Erk signalling, potentially through the recruitment of the 14-3-3 ζ and Pin-1 proteins.

StpA protein from Escherichia coli condenses supercoiled DNA in preference to linear DNA and protects it from digestion by DNase I and EcoKI.

The nucleoid-associated protein, StpA, of Escherichia coli binds non-specifically to double-stranded DNA (dsDNA) and apparently forms bridges between adjacent segments of the DNA. Such a coating of protein on the DNA would be expected to hinder the action of nucleases. We demonstrate that StpA binding hinders dsDNA cleavage by both the non-specific endonuclease, DNase I, and by the site-specific type I restriction endonuclease, EcoKI. It requires approximately one StpA molecule per 250-300 bp of supercoiled DNA and approximately one StpA molecule per 60-100 bp on linear DNA for strong inhibition of the nucleases. These results support the role of StpA as a nucleoid-structuring protein which binds DNA segments together. The inhibition of EcoKI, which cleaves DNA at a site remote from its initial target sequence after extensive DNA translocation driven by ATP hydrolysis, suggests that these enzymes would be unable to function on chromosomal DNA even during times of DNA damage when potentially lethal, unmodified target sites occur on the chromosome. This supports a role for nucleoid-associated proteins in restriction alleviation during times of cell stress.

Counting the calories to stay in the groove.

High-sensitivity microcalorimetry is beginning to make an impact on the determination of thermodynamic parameters associated with protein-DNA interactions and the understanding of the relationship of these data to structural details of complex formation.

Structure of the PH domain from Bruton's tyrosine kinase in complex with inositol 1,3,4,5-tetrakisphosphate.

BACKGROUND: The activity of Bruton's tyrosine kinase (Btk) is important for the maturation of B cells. A variety of point mutations in this enzyme result in a severe human immunodeficiency known as X-linked agammaglobulinemia (XLA). Btk contains a pleckstrin-homology (PH) domain that specifically binds phosphatidylinositol 3,4,5-trisphosphate and, hence, responds to signalling via phosphatidylinositol 3-kinase. Point mutations in the PH domain might abolish membrane binding, preventing signalling via Btk. RESULTS: We have determined the crystal structures of the wild-type PH domain and a gain-of-function mutant E41K in complex with D-myo-inositol 1,3,4,5-tetra-kisphosphate (Ins (1,3,4,5)P4). The inositol Ins (1,3,4,5)P4 binds to a site that is similar to the inositol 1,4,5-trisphosphate binding site in the PH domain of phospholipase C-delta. A second Ins (1,3,4,5)P4 molecule is associated with the domain of the E41K mutant, suggesting a mechanism for its constitutive interaction with membrane. The affinities of Ins (1,3,4,5)P4 to the wild type (Kd = 40 nM), and several XLA-causing mutants have been measured using isothermal titration calorimetry. CONCLUSIONS: Our data provide an explanation for the specificity and high affinity of the interaction with phosphatidylinositol 3,4,5-trisphosphate and lead to a classification of the XLA mutations that reside in the Btk PH domain. Mis-sense mutations that do not simply destabilize the PH fold either directly affect the interaction with the phosphates of the lipid head group or change electrostatic properties of the lipid-binding site. One point mutation (Q127H) cannot be explained by these facts, suggesting that the PH domain of Btk carries an additional function such as interaction with a Galpha protein.

Mass spectrometric and thermodynamic studies reveal the role of water molecules in complexes formed between SH2 domains and tyrosyl phosphopeptides.

BACKGROUND: SH2 domains have a fundamental role in signal transduction. These domains interact with proteins containing phosphorylated tyrosine residues and, in doing so, mediate the interactions of proteins involved in tyrosine kinase signalling. The issue of specificity in SH2 domain interactions is therefore of great interest in terms of understanding tyrosine kinase signal-transduction pathways and in the discovery of drugs to inhibit them. Water molecules are found at the interfaces of many complexes, however, to date little attention has been paid to their role in dictating specificity. RESULTS: Here we use a combination of nanoflow electrospray ionization mass spectrometry (ESI-MS), isothermal titration calorimetry and structural data to investigate the effect of water molecules in complexes formed between the SH2 domain of tyrosine kinase Src and tyrosyl phosphopeptides. Binding studies have been performed using a series of different peptides that were selected to allow changes in the water content at the complex interface and demonstrate changes in specificity. ESI-MS enables quantification of the number of water molecules that interact with a higher affinity than those generally found solvating the biomolecular complex. CONCLUSIONS: Comparing the interactions of different peptides, we show that an intricate network of water molecules have a key role in dictating specificity. The use of mass spectrometry to quantify tightly bound water molecules may prove of general use in structural biology, where an independent determination of the water molecules associated with a structure would be advantageous. Furthermore, the ability to assess whether given water molecules are important in high-affinity binding could make this method a precious tool in drug design.

Localization and characterization of the hyaluronan-binding site on the link module from human TSG-6.

BACKGROUND: The interactions of hyaluronan (HA) with proteins are important in extracellular matrix integrity and leukocyte migration and are usually mediated by a domain termed a Link module. Although the tertiary structure of a Link module has been determined, the molecular basis of HA-protein interactions remains poorly understood. RESULTS: Isothermal titration calorimetry was used to characterize the interaction of the Link module from human TSG-6 (Link_TSG6) with HA oligosaccharides of defined length (HA(4)-HA(16)). All oligomers bound (except HA(4)) with K(d) values ranging from 0.2-0.5 microM at 25 degrees C. The reaction is exothermic with a favourable entropy and the thermodynamic profile is similar to those of other glycosaminoglycan-protein interactions. The HA(8) recognition site on Link_TSG6 was localized by comparing nuclear magnetic resonance (NMR) spectra from a 1:1 complex with free protein. Residues perturbed on HA binding include both amino acids that are likely to be directly involved in the interaction (i.e., Lys11, Tyr59, Asn67, Phe70, Lys72 and Tyr78) and those affected by a ligand-induced conformational change in the beta4/beta5 loop. The sidechain of Asn67 becomes more rigid in the complex suggesting that it is in close proximity to the binding site. CONCLUSIONS: In TSG-6 a single Link module is sufficient for a high-affinity interaction with HA. The HA-binding surface on Link_TSG6 is found in a similar position to that suggested previously for CD44, indicating that its location might be conserved across the Link module superfamily. Here we find no evidence for the involvement of linear sequence motifs in HA binding.

Grb2 depletion under non-stimulated conditions inhibits PTEN, promotes Akt-induced tumor formation and contributes to poor prognosis in ovarian cancer.

In the absence of extracellular stimulation the adaptor protein growth factor receptor-bound protein (Grb2) and the phospholipase Plcγ1 compete for the same binding site on fibroblast growth factor receptor 2 (FGFR2). Reducing cellular Grb2 results in upregulation of Plcγ1 and depletion of the phospholipid PI(4,5)P2. The functional consequences of this event on signaling pathways are unknown. We show that the decrease in PI(4,5)P2 level under non-stimulated conditions inhibits PTEN activity leading to the aberrant activation of the oncoprotein Akt. This results in excessive cell proliferation and tumor progression in a xenograft mouse model. As well as defining a novel mechanism of Akt phosphorylation with important therapeutic consequences, we also demonstrate that differential expression levels of FGFR2, Plcγ1 and Grb2 correlate with patient survival. Oncogenesis through fluctuation in the expression levels of these proteins negates extracellular stimulation or mutation and defines them as novel prognostic markers in ovarian cancer.

Crystallographic and calorimetric analysis of peptide binding to OppA protein.

Isothermal titration calorimetry has been used to study the binding of 20 different peptides to the peptide binding protein OppA, and the crystal structures of the ligand complexes have been refined. This periplasmic binding protein, part of the oligopeptide permease system of Gram negative bacteria, has evolved to bind and enclose small peptides of widely varying sequences. The peptides used in this study have the sequence Lys-X-Lys, where X is any of the 20 commonly occurring amino acids. The various side-chains found at position 2 on the ligand fit into a hydrated pocket. The majority of side-chains are restrained to particular conformations within the pocket. Water molecules act as flexible adapters, matching the hydrogen-bonding requirements of the protein and ligand and shielding charges on the buried ligand. This use of water by OppA to broaden the repertoire of its binding site is not unique, but contrasts sharply with other proteins which use water to help bind ligands highly selectively. Predicting the thermodynamics of binding from the structure of the complexes is highly complicated by the influence of water on the system.

Oct-1 POU and octamer DNA co-operate to recognise the Bob-1 transcription co-activator via induced folding.

The expression of immunoglobulin genes is controlled in part by the DNA-binding protein Oct-1 and the B cell-specific transcription co-activator, Bob1 (also known as OCA-B or OBF-1) that together form a complex on the Igkappa promoter. We have characterised the assembly of the ternary complex using biophysical methods. Bob1 binds specifically as a monomer to the complex of the Oct-1 DNA-binding domain (Oct-1 POU) and the Igkappa promoter, but binds weakly to either Oct-1 POU or the Igkappa promoter alone, indicating that both are required to make an avid complex. Ternary complex formation requires a defined DNA sequence, as the stability of the complex can be strongly affected by a single base-pair change or by removing 5-methyl groups from selected thymine bases.In isolation, Bob1 appears to have little secondary structure, but may become partially structured upon recruitment into the ternary complex as demonstrated by circular dichroism spectra and calorimetry. These and other findings suggest that ternary complex formation requires a defined geometry of the POU/DNA complex, and that the co-activator makes stereo-specific contacts to both the POU protein and the major groove of the DNA that induces its fold.

Specific binding of hoechst 33258 to the d(CGCAAATTTGCG)2 duplex: calorimetric and spectroscopic studies.

Fluorescence spectroscopy and high-sensitivity isothermal titration calorimetry (ITC) techniques have been used to examine the binding characteristics of Hoechst 33258 with the extended AT-tract DNA duplex d(CGCAAATTTGCG)2 in aqueous solution. The method of continuous variation reveals a 1:1 binding stoichiometry. Fluorescence equilibrium studies carried out at three different, but fixed, ligand concentrations show that the binding isotherm shifts towards higher [DNA] as the concentration of ligand is increased. The data show tight binding with Kb=3.2(+/-0.6)x10(8) M(duplex)-1 at 25 degrees C in solutions containing 200 mM Na+. Based on UV studies of duplex melting, which show that strand separation starts at approximately 35 degrees C and has a Tm at 54 degrees C in 300 mM NaCl, binding enthalpies were determined by ITC in the 10 to 30 degrees C range. Binding is endothermic at all temperatures examined, with DeltaH values ranging from +10.24(+/-0.18) to +4.2(+/-0.10) kcal mol(duplex)-1 at 9.4 degrees C and 30.1 degrees C, indicating that the interaction is entropically driven. The temperature dependence of DeltaH shows a binding-induced change in heat capacity (DeltaCp) of -330(+/-50) cal mol-1 K-1. This value is similar to that predicted from a consideration of the effects of hydrophobic and hydrophilic solvent-accessible surface burial on complexation. This result, almost entirely dictated by a removal from exposure of the non-polar reactant surfaces, represents the first demonstration of such behavior in a DNA-drug system. The salt dependence of the binding constant was examined using reverse-salt fluorescence titrations, with a value of 0.99 determined for the deltalnK/deltaln[Na+] parameter. These data provide a detailed thermodynamic profile for the interaction that enables a dissection of DeltaGobs into the component free energy terms. Analysis of data obtained at 25 degrees C reveals that DeltaGobs is dominated by the free energy for hydrophobic transfer of ligand from solution to the DNA binding site. Molecular interactions, including H-bonding and van der Waals contacts, are found to play only a minor role in stabilizing the resulting complex, a somewhat surprising finding given the emphasis placed on such interactions from structural studies.

A thermodynamic study of the trp repressor-operator interaction.

We have measured the heats of formation of the trp repressor/operator complex by direct titration calorimetry over the temperature range 10 degrees C to 40 degrees C. A primary strong mode of binding displays the characteristic large negative heat capacity change observed by other methods in the formation of specific protein/DNA complexes. Unlike most such reactions, however, the formation of the trp repressor/operator complex is enthalpically driven throughout the physiological temperature range. After saturation of this principal mode, we also detected a secondary weaker binding mode, which we ascribe to a now well documented interaction called "half-site" binding. Although weak, this mode also exhibits an unusually large negative heat capacity change. Since the interface of the proposed secondary half-site binding mode has the same complementary stereochemistry as the primary one (due to internal symmetry), we correlate the negative heat capacity change with the formation of a stereospecific interface and not with high affinity. As in similar cases, the empirical correlation between buried non-polar surfaces and reduction of heat capacity does not account for the large negative delta Cp, nor do crystal structures reveal any further reduction in solvent excluded surfaces within the reactants upon complex formation. We attribute the "unaccounted for" decrement in the heat capacity of the complex to the stereospecific restriction of the hydrated polar elements that form the specific interface. We suggest that the "tightening of soft internal modes" at and near the polar interface of the complex is more important than previously recognized because previous considerations did not take into account the highly hydrated nature of these polar elements and the concomitant reduction in the degrees of freedom of the water structure.

The effects of salt on the TATA binding protein-DNA interaction from a hyperthermophilic archaeon.

This study investigates the thermodynamics of the interaction of the TATA box binding protein (TBP) from Pyrococcus woesei (Pw) with an oligonucleotide containing a specific binding site. Pw is a hyperthermophilic archeal organism which exists under conditions of high salt and high temperature. A measurable protein-DNA interaction only occurs at high salt concentrations. Isothermal titration calorimetric binding studies were performed under a range of salts (potassium chloride, potassium phosphate, potassium acetate and sodium acetate) at varying concentrations (0.8 to 1.6 M). At the high salt concentrations used the observed equilibrium binding constant increases with increasing salt concentration. This is very different to the effect reported for all other protein-DNA interactions which have been studied at lower salt concentrations. Thermodynamic data suggest that the protein-DNA interaction at high salt concentration is accompanied by the removal of large numbers of water molecules from the buried hydrophobic surface area. In addition, the involvement of ions appears to influence the binding which can be explained by binding of cations in the interface between the electrostatically negative lateral lobes on the protein and the negatively charged DNA.

Specificity and interactions of the protein OppA: partitioning solvent binding effects using mass spectrometry.

Mass spectrometry (MS) was used to characterise the binding of the 58 kDa protein OppA to 11 peptides with diverse properties. Peptides with two, three and five amino acid residues were added to OppA, and the mass spectra showed that the highest-affinity complexes are formed between OppA and tripeptide ligands. Lower-affinity complexes were observed for OppA and dipeptide ligands, and no complex formation was detected with pentapeptides or a tripeptide in which the N-terminal amino group was acetylated. Tripeptides containing a single d amino acid residue were found not to bind to native OppA. Evidence from the peak width and the, charge in the spectra of the complexes suggests that the bound peptides are encapsulated by the protein in a solvent-filled cavity in the gas phase of the mass spectrometer. Analysis of the proportions of peptide-bound and free proteins under low-energy MS conditions shows a good correlation with solution-phase K(d) measurements where available. Increasing the internal energy of the gas-phase complex led to dissociation of the complex. The ease of dissociation is interpreted in terms of the intrinsic stability of the complex in the absence of the stabilising effects of bulk solvent. The results from this study demonstrate insensitivity to the hydrophobic and ionic properties, of the side-chains of the peptides, in contrast to the investigation of other protein ligand systems by MS. Moreover, these findings are in accord with the physiological role of this protein in allowing into the cell di- and tripeptides containing naturally occurring amino acids, regardless of their sequence, while barring access to potentially harmful peptide mimics.

Structural characterization of the N-terminal oligomerization domain of the bacterial chromatin-structuring protein, H-NS.

The H-NS protein plays a key role in condensing DNA and modulating gene expression in bacterial nucleoids. The mechanism by which this is achieved is dependent, at least in part, on the oligomerization of the protein. H-NS consists of two distinct domains; the N-terminal domain responsible for protein oligomerization, and the C-terminal DNA binding domain, which are separated by a flexible linker region. We present a multidimensional NMR study of the amino-terminal 64 residues of H-NS (denoted H-NS1-64) from Salmonella typhimurium, which constitute the oligomerization domain. This domain exists as a homotrimer, which is predicted to be self-associated through a coiled-coil configuration. NMR spectra show an equivalent magnetic environment for each monomer indicating that the polypeptide chains are arranged in parallel with complete 3-fold symmetry. Despite the limited resonance dispersion, an almost complete backbone assignment for 1H(N), 1H(alpha), 15N, 13CO and 13C(alpha) NMR resonances was obtained using a suite of triple resonance experiments applied to uniformly 15N-, 13C/15N- and 2H/13C/15N-labelled H-NS1-64 samples. The secondary structure of H-NS1-64 has been identified on the basis of the analysis of 1H(alpha), 13C(alpha), 13Cbeta and 13CO chemical shifts, NH/solvent exchange rates, intra-chain H(N)-H(N) and medium-range nuclear Overhauser enhancements (NOEs). Within the context of the homotrimer, each H-NS1-64 protomer consists of three alpha-helices spanning residues 2-8, 12-20 and 22-53, respectively. A topological model is presented for the symmetric H-NS1-64 trimer based upon the combined analysis of the helical elements and the pattern of backbone amide group 15N nuclear relaxation rates within the context of axially asymmetric diffusion tensor. In this model, the longest of the three helices (helix 3, residues 22-53) forms a coiled-coil interface with the other chains in the homotrimer. The two shorter N-terminal helices fold back onto the outer surface of the coiled-coil core and potentially act to stabilise this configuration.

Just add water! The effect of water on the specificity of protein-ligand binding sites and its potential application to drug design.

Recent data have highlighted the enigmatic role that water plays in biomolecular complexes. Water at the interface of a complex can increase the promiscuity of an interaction, yet it can also provide increased specificity and affinity. The ability to engineer water-binding sites into the interface between a drug and its target might prove useful in drug design.

Sensing the heat: the application of isothermal titration calorimetry to thermodynamic studies of biomolecular interactions.

Biomolecular interactions can be defined by combining thermodynamic data on the energetic properties of the interaction with high-resolution structural data. The development of high sensitivity isothermal titration calorimetric equipment provides a dramatic advance in the gathering of thermodynamic data, and the interactions between biological macromolecules can now be described with unprecedented accuracy.

Searching for specificity in SH domains.

Elucidating protein-protein interactions has been a central feature to understanding intracellular signal transduction. Many of the binding sites of the interacting proteins in these pathways are within highly sequentially homologous and structurally conserved domains. We challenge the dogma that mutual exclusivity in signalling is derived from a high level of specificity in these domains.

Water-mediated protein-DNA interactions: the relationship of thermodynamics to structural detail.

The elucidation of a relationship between the thermodynamic parameters and the structural changes accompanying biomolecular interactions could lead to predictive algorithms. For example, based on some knowledge of the structure of a target molecule the affinities of ligands could be determined with obvious implications for the pharmaceutical industry. In attempting to relate the thermodynamic and structural changes on formation of a protein-DNA complex, the correlation between change in heat capacity and burial of surface area has proved successful. However, this correlation appears to break down when water molecules are included in the binding interface. Here we present data that support the hypothesis that bound water molecules have to be considered as contributing to the change in heat capacity and could, thus, be used in ligand design.