Crystal structure of the active form of native human thymidylate synthase in the absence of bound substrates.

Human thymidylate synthase (hTS) provides the sole de novo intracellular source of thymidine 5'-monophosphate (dTMP). hTS is required for DNA replication prior to cell division, making it an attractive target for anticancer chemotherapy and drug discovery. hTS binds 2'-deoxyuridine 5'-monophosphate (dUMP) and the folate co-substrate N5,N10-methylenetetrahydrofolate (meTHF) in a pocket near the catalytic residue Cys195. The catalytic loop, which is composed of amino-acid residues 181-197, can adopt two distinct conformations related by a 180° rotation. In the active conformation Cys195 is close to the active site, while in the inactive conformation it is rotated and Cys195 is too distant from the active site for catalysis. Several hTS structures, either native or engineered, have been solved in the active conformation in complex with ligands or inhibitors and at different salt concentrations. However, apo hTS structures have been solved in an inactive conformation in high-salt and low-salt conditions (PDB entries 1ypv, 4h1i, 4gyh, 3egy and 3ehi). Here, the structure of apo hTS crystallized in the active form with sulfate ions coordinated by the arginine residue that binds dUMP is reported.

The human protein HSPC021 interacts with Int-6 and is associated with eukaryotic translation initiation factor 3.

The Int-6 protein has been shown to be a subunit of eukaryotic translation initiation factor 3 (eIF3) and to play a role in the control of cell growth. By immunoprecipitation experiments and mass spectrometry analyses, we identified a human protein previously known as HSPC021 that is associated with Int-6. Exposure of Jurkat cells to the phosphatase inhibitor H(2)O(2) triggers a marked phosphorylation on tyrosine of HSPC021. Several experiments were performed to evaluate whether this protein is associated with eIF3. It was observed that HSPC021 coelutes with Int-6 and eIF3 in gel filtration, coimmunoprecipitates with eIF3, and is incorporated into eIF3 both in rabbit reticulocyte lysates and in COS7 cells. A direct protein-protein interaction occurs between HSPC021 and Int-6, but the analysis of different mutants of HSPC021 indicated that a larger region of the protein is necessary for incorporation into eIF3 as compared with binding to Int-6. Taken together, our results establish that HSPC021 is tightly associated with the mammalian translation initiation factor eIF3. Analysis of the primary sequence of HSPC021 from different species revealed the presence of a tetratricopeptide repeat, a proteasome-COP9 (constitutive photomorphogenesis 9) signalosome-initiation factor 3 domain along with a Pumilio FBF repeat. These protein motifs are also present in subunits of eIF3, of the lid of the 26 S proteasome, and of the COP9 signalosome.

EF-hand calcium-binding proteins.

The EF-hand motif is the most common calcium-binding motif found in proteins. Several high-resolution structures containing different metal ions bound to EF-hand sites have given new insight into the modulation of their binding affinities. Recently determined structures of members of several newly identified protein families that contain the EF-hand motif in some of their domains, as well as of their complexes with target molecules, are throwing light on the surprising variety of functions that can be served by this simple and ingenious structural motif.

S100 protein-annexin interactions: a model of the (Anx2-p11)(2) heterotetramer complex.

The (Anx2)(2)(p11)(2) heterotetramer has been implicated in endo- and exocytosis in vivo and in liposome aggregation in vitro. Here we report on the modelling of the heterotetramer complex using docking algorithms. Two types of models are generated-heterotetramer and heterooctamer. On the basis of the agreement between the calculated (X-ray) electron density and the observed projected density from cryo-electron micrographs on the one hand, and calculated energy criteria on the other hand, the heterotetramer models are proposed as the most probable, and one of them is selected as the best model. Analysis of this model at an atomic level suggests that the interaction between the Anx2 core and p11 has an electrostatic character, being stabilised primarily through charged residues.

S100-annexin complexes: some insights from structural studies.

Several annexins have been shown to bind proteins that belong to the S100 calcium-binding protein family. The two best-characterized complexes are annexin II with p11 and annexin I with S100C, the former of which has been implicated in membrane fusion processes. We have solved the crystal structures of the complexes of p11 with annexin II N-terminus and of S100C with annexin I N-terminus. Using these structural results, as well as electron microscopy observations of liposome junctions formed in the presence of such complexes (Lambert et al., 1997 J Mol Biol 272, 42-55), we propose a computer generated model for the entire annexin II/p11 complex.

Structural basis of the Ca(2+)-dependent association between S100C (S100A11) and its target, the N-terminal part of annexin I.

BACKGROUND: S100C (S100A11) is a member of the S100 calcium-binding protein family, the function of which is not yet entirely clear, but may include cytoskeleton assembly and dynamics. S100 proteins consist of two EF-hand calcium-binding motifs, connected by a flexible loop. Like several other members of the family, S100C forms a homodimer. A number of S100 proteins form complexes with annexins, another family of calcium-binding proteins that also bind to phospholipids. Structural studies have been undertaken to understand the basis of these interactions. RESULTS: We have solved the crystal structure of a complex of calcium-loaded S100C with a synthetic peptide that corresponds to the first 14 residues of the annexin I N terminus at 2.3 A resolution. We find a stoichiometry of one peptide per S100C monomer, the entire complex structure consisting of two peptides per S100C dimer. Each peptide, however, interacts with both monomers of the S100C dimer. The two S100C molecules of the dimer are linked by a disulphide bridge. The structure is surprisingly close to that of the p11-annexin II N-terminal peptide complex solved previously. We have performed competition experiments to try to understand the specificity of the S100-annexin interaction. CONCLUSIONS: By solving the structure of a second annexin N terminus-S100 protein complex, we confirmed a novel mode of interaction of S100 proteins with their target peptides; there is a one-to-one stoichiometry, where the dimeric structure of the S100 protein is, nevertheless, essential for complex formation. Our structure can provide a model for a Ca(2+)-regulated annexin I-S100C heterotetramer, possibly involved in crosslinking membrane surfaces or organising membranes during certain fusion events.

The crystal structure of a complex of p11 with the annexin II N-terminal peptide.

The aggregation and membrane fusion properties of annexin II are modulated by the association with a regulatory light chain called p11.p11 is a member of the S100 EF-hand protein family, which is unique in having lost its calcium-binding properties. We report the first structure of a complex between p11 and its cognate peptide, the N-terminus of annexin II, as well as that of p11 alone. The basic unit for p11 is a tight, non-covalent dimer. In the complex, each annexin II peptide forms hydrophobic interactions with both p11 monomers, thus providing a structural basis for high affinity interactions between an S100 protein and its target sequence. Finally, p11 forms a disulfide-linked tetramer in both types of crystals thus suggesting a model for an oxidized form of other S100 proteins that have been found in the extracellular milieu.

pH-Dependent self-association of the Src homology 2 (SH2) domain of the Src homologous and collagen-like (SHC) protein.

The Src homologous and collagen-like (SHC) protein plays an essential role in signal transduction pathways in that it participates in the chain of events that leads to the activation of the protein Ras. The crystal structure of the SH2 domain of SHC has been determined using the method of multiple isomorphous replacement at a resolution of 2.5 A. The SH2 domain of SHC is similar in fold to other SH2 domains. The peptide-binding surfaces resemble that of the SH2 domain of Src in that a deep pocket is formed where the third amino acid C-terminal to the phosphotyrosine can insert. A novel feature of this structure is the observation of a disulfide bond and an extensive dimer interface between two symmetry-related molecules. Solution studies under reducing conditions using analytical centrifugation and PAGE suggest that the SH2 domain of SHC dimerizes in a pH-dependent manner where low pH conditions (approximately 4.5) are conducive to dimer formation. Dimerization of SHC may have important biological implications in that it may promote the assembly of large heteromultimeric signaling complexes.

Probing the nature of substrate binding in Humicola lanuginosa lipase through X-ray crystallography and intuitive modelling.

The catalytic triad of the neutral lipase from Humicola lanuginosa is buried by a short helix under aqueous conditions rendering the enzyme inactive. Upon adsorption to a lipid substrate interface this helix is displaced, thereby exposing the active site (interfacial activation). By covalently linking inhibitors to the active serine, it is possible to crystallize the enzyme in an interfacially activated state. Two such structures are reported here which mimic the tetrahedral transition states of lipolysis. To date, no crystal structures of a lipase--triglyceride complex exist for this enzyme. Therefore, possible interactions between this lipase and its substrate have been analysed through molecular modelling.