Structure of TCTP reveals unexpected relationship with guanine nucleotide-free chaperones.

The translationally controlled tumor-associated proteins (TCTPs) are a highly conserved and abundantly expressed family of eukaryotic proteins that are implicated in both cell growth and the human acute allergic response but whose intracellular biochemical function has remained elusive. We report here the solution structure of the TCTP from Schizosaccharomyces pombe, which, on the basis of sequence homology, defines the fold of the entire family. We show that TCTPs form a structural superfamily with the Mss4/Dss4 family of proteins, which bind to the GDP/GTP free form of Rab proteins (members of the Ras superfamily) and have been termed guanine nucleotide-free chaperones (GFCs). Mss4 also acts as a relatively inefficient guanine nucleotide exchange factor (GEF). We further show that the Rab protein binding site on Mss4 coincides with the region of highest sequence conservation in the TCTP family. This is the first link to any other family of proteins that has been established for the TCTP family and suggests the presence of a GFC/GEF at extremely high abundance in eukaryotic cells.

Wild-type and met-65-->Leu variants of human cystatin A are functionally and structurally identical.

The solution structure of an N-terminally truncated and mutant form (M65L(2-98)) of the human cysteine protease inhibitor cystatin A has been reported that reveals extensive structural differences when compared to the previously published structure of full-length wild-type (WT) cystatin A. On the basis of the M65L(2-98) structure, a model of the inhibitory mechanism of cystatin A was proposed wherein specific interactions between the N- and C-terminal regions of cystatin A are invoked as critical determinants of protease binding. To test this model and to account for the reported differences between the two structures, we undertook additional structural and mechanistic analyses of WT and mutant forms of human cystatin A. These show that modification at the C-terminus of cystatin A by the addition of nine amino acids has no effect upon the affinity of papain inhibition (K(D) = 0.18+/-0.02 pM) and the consequences of such modification are not propagated to other parts of the structure. These findings indicate that perturbation of the C-terminus can be achieved without any measurable effect on the N-terminus or the proteinase binding loops. In addition, introduction of the methionine-65 --> leucine substitution into cystatin A that retains the N-terminal methionine (M65L(1-98)) has no significant effect upon papain binding (K(D) = 0.34+/-0.02 pM). Analyses of the structures of WT and M65L(1-98) using (1)H NMR chemical shifts and residual dipolar couplings in a partially aligning medium do not reveal any evidence of significant differences between the two inhibitors. Many of the differences between the published structures correspond to major violations by M65L(2-98) of the WT constraints list, notably in relation to the position of the N-terminal region of the inhibitor, one of three structural motifs indicated by crystallographic studies to be involved in protease binding by cystatins. In the WT structure, and consistent with the crystallographic data, this region is positioned adjacent to another inhibitory motif (the first binding loop), whereas in M65L(2-98) there is no proximity of these two motifs. As the NMR data for both WT9C and M65L(1-98) are wholly consistent with the published structure of WT cystatin A and incompatible with that of M65L(2-98), we conclude that the former represents the most reliable structural model of this protease inhibitor.

Structural mobility of the human prion protein probed by backbone hydrogen exchange.

Prions, the causative agents of Creutzfeldt-Jacob Disease (CJD) in humans and bovine spongiform encephalopathy (BSE) and scrapie in animals, are principally composed of PrPSc, a conformational isomer of cellular prion protein (PrPC). The propensity of PrPC to adopt alternative folds suggests that there may be an unusually high proportion of alternative conformations in dynamic equilibrium with the native state. However, the rates of hydrogen/deuterium exchange demonstrate that the conformation of human PrPC is not abnormally plastic. The stable core of PrPC has extensive contributions from all three alpha-helices and shows protection factors equal to the equilibrium constant for the major unfolding transition. A residual, hyper-stable region is retained upon unfolding, and exchange analysis identifies this as a small nucleus of approximately 10 residues around the disulfide bond. These results show that the most likely route for the conversion of PrPC to PrPSc is through a highly unfolded state that retains, at most, only this small nucleus of structure, rather than through a highly organized folding intermediate.

Characterisation of low free-energy excited states of folded proteins.

It is demonstrated that the identity of residues accessing excited conformational states that are of low free energy relative to the ground state in proteins can be obtained from amide proton NMR chemical shift temperature dependences displaying significant curvature. For the N-terminal domain of phosphoglycerate kinase, hen egg-white lysozyme and BPTI, conformational heterogeneity arises from a number of independent sources, including: structural instability resulting from deletion of part of the protein; a minor conformer generated through disulphide bond isomerisation; an alternative hydrogen bond network associated with buried water molecules; alternative hydrogen bonds involving backbone amides and surface-exposed side-chain hydrogen bond acceptors; and the disruption of loops, ends of secondary structural elements and chain termini. In many of these cases, the conformational heterogeneity at these sites has previously been identified by X-ray and/or NMR studies, but conformational heterogeneity of buried water molecules has hitherto received little attention. These multiple independent low free-energy excited states each involve a small number of residues and are shown to be within 2.5 kcal mol-1 of the ground state. Their relationship with the partially unfolded forms previously characterised using amide proton exchange studies is discussed.

Temperature dependence of 1H chemical shifts in proteins.

Temperature coefficients have been measured by 2D NMR methods for the amide and C alpha H proton chemical shifts in two globular proteins, bovine pancreatic trypsin inhibitor and hen egg-white lysozyme. The temperature-dependent changes in chemical shift are generally linear up to about 15 degrees below the global denaturation temperature, and the derived coefficients span a range of roughly -16 to +2 ppb/K for amide protons and -4 to +3 ppb/K for C alpha H. The temperature coefficients can be rationalized by the assumption that heating causes increases in thermal motion in the protein. Precise calculations of temperature coefficients derived from protein coordinates are not possible, since chemical shifts are sensitive to small changes in atomic coordinates. Amide temperature coefficients correlate well with the location of hydrogen bonds as determined by crystallography. It is concluded that a combined use of both temperature coefficients and exchange rates produces a far more reliable indicator of hydrogen bonding than either alone. If an amide proton exchanges slowly and has a temperature coefficient more positive than -4.5 ppb/K, it is hydrogen bonded, while if it exchanges rapidly and has a temperature coefficient more negative than -4.5 ppb/K, it is not hydrogen bonded. The previously observed unreliability of temperature coefficients as measures of hydrogen bonding in peptides may arise from losses of peptide secondary structure on heating.

Multiple interactions between polyphenols and a salivary proline-rich protein repeat result in complexation and precipitation.

Polyphenols (tannins) in the diet not only precipitate oral proteins, producing an astringent sensation, but also interact with dietary proteins and digestive enzymes in the gut, resulting in a variety of antinutritive and toxic effects. Salivary proline-rich proteins (PRPs), which are secreted into the oral cavity, form complexes with and precipitate dietary polyphenols, and thus, they constitute the primary mammalian defense directed against ingested tannins. In order to characterize the interaction, NMR studies were performed which involved titrating a series of polyphenols into a synthetic 19-residue PRP fragment. The results show that the predominant mode of association is a hydrophobic stacking of the polyphenol ring against the pro-S face of proline and that the first proline residue of a Pro-Pro sequence is a particularly favored binding site. Measurement of dissociation constants indicates that the larger and more complex polyphenols interact more strongly with the PRP fragment; the order of binding affinity was determined as procyanidin dimer B-2 > pentagalloylglucose > trigalloylglucose >> proanthocyanidin monomer (-)-epicatechin approximately propyl gallate. Smaller polyphenols can bind with one phenolic ring stacked against each proline residue, whereas larger polyphenols occupy two or three consecutive prolines. The more complex polyphenols interact with the PRP fragment in a multidentate fashion; moreover, they self-associate or stack when bound. Thus, a model is proposed in which multiple polyphenol/polyphenol and polyphenol/PRP interactions act cooperatively to achieve precipitation.

Tannin interactions with a full-length human salivary proline-rich protein display a stronger affinity than with single proline-rich repeats.

The protein IB5 has been purified from human parotid saliva. This protein contains several repeats of a short proline-rich sequence. Dissociation constants have been measured at several discrete binding sites using 1H-NMR for the hydrolysable tannins (polyphenols) beta-1,3,6-tri-O-galloyl-D-glucopyranose, beta-1,2,4,6-tetra-O-galloyl-D-glucopyranose and beta-1,2,3,4,6-penta-O-galloyl-D-glucopyranose and the condensed proanthocyanidin (--)-epicatechin. The dissociation constants for trigalloyl glucose and pentagalloyl glucose were 15 X 10(-5) and 1.7 X 10(-5) M, respectively, which are 115 and 1660 times stronger than those previously measured under the same conditions for a single repeat of a mouse salivary proline-rich protein. The increase in affinity is ascribed to intramolecular secondary interactions, which are strengthened by the rigidity of the interacting molecules.