Tumor suppressor protein Pdcd4 interacts with Daxx and modulates the stability of Daxx and the Hipk2-dependent phosphorylation of p53 at serine 46.

The tumor suppressor protein Pdcd4 is a nuclear/cytoplasmic shuttling protein that has been implicated in the development of several types of human cancer. In the nucleus, Pdcd4 affects the transcription of specific genes by modulating the activity of several transcription factors. We have identified the Daxx protein as a novel interaction partner of Pdcd4. Daxx is a scaffold protein with roles in diverse processes, including transcriptional regulation, DNA-damage signaling, apoptosis and chromatin remodeling. We show that the interaction of both proteins is mediated by the N-terminal domain of Pdcd4 and the central part of Daxx, and that binding to Pdcd4 stimulates the degradation of Daxx, presumably by disrupting the interaction of Daxx with the de-ubiquitinylating enzyme Hausp. Daxx has previously been shown to serve as a scaffold for protein kinase Hipk2 and tumor suppressor protein p53 and to stimulate the phosphorylation of p53 at serine 46 (Ser-46) in response to genotoxic stress. We show that Pdcd4 also disrupts the Daxx-Hipk2 interaction and inhibits the phosphorylation of p53. We also show that ultraviolet irradiation decreases the expression of Pdcd4. Taken together, our results support a model in which Pdcd4 serves to suppress the phosphorylation of p53 in the absence of DNA damage, while the suppressive effect of Pdcd4 is abrogated after DNA damage owing to the decrease of Pdcd4. Overall, our data demonstrate that Pdcd4 is a novel modulator of Daxx function and provide evidence for a role of Pdcd4 in restraining p53 activity in unstressed cells.

Pdcd4 directly binds the coding region of c-myb mRNA and suppresses its translation.

Pdcd4 is a novel tumor suppressor protein that functions in the nucleus and the cytoplasm, and appears to be involved in the regulation of transcription and translation. In the cytoplasm, Pdcd4 has been implicated in the suppression of translation of mRNAs containing structured 5'-untranslated regions; however, the mechanisms that recruit Pdcd4 to specific target mRNAs and the identities of these mRNAs are mostly unknown. In this study, we have identified c-myb mRNA as the first natural translational target mRNA of Pdcd4. We have found that translational suppression of c-myb mRNA by Pdcd4 is dependent on sequences located within the c-myb-coding region. Furthermore, we have found that the N-terminal domain of Pdcd4 has an important role in targeting Pdcd4 to c-myb RNA by mediating preferential RNA binding to the Pdcd4-responsive region of c-myb mRNA. Overall, our work demonstrates for the first time that Pdcd4 is directly involved in translational suppression of a natural mRNA and provides the first evidence for a key role of the RNA-binding domain in targeting Pdcd4 to a specific mRNA.

Structural characterization of the interaction of mTOR with phosphatidic acid and a novel class of inhibitor: compelling evidence for a central role of the FRB domain in small molecule-mediated regulation of mTOR.

The mammalian target of rapamycin (mTOR) is a large, multidomain protein kinase, which plays a central role in the regulation of cell growth and has recently emerged as an essential target of survival signals in many types of human cancer cells. Here, we report the solution structures of complexes formed between the FKBP12-rapamycin binding (FRB) domain of mTOR and phosphatidic acid, an important cellular activator of the kinase, and between the FRB domain and a novel inhibitor (HTS-1). The overall structure of the FRB domain is very similar to that seen in the ternary complex formed with FKBP12 and the immunosuppressive drug rapamycin; however, there are significant changes within the rapamycin-binding site with important consequences for rational drug design. The surface of the FRB domain contains a number of distinctive features that have previously escaped attention, including a potential new regulatory site on the opposite face to that involved in the binding of rapamycin, which displays the features expected for a specific binding site for a small molecule. The interaction sites for phosphatidic acid and HTS-1 were found to closely match the site responsible for rapamycin binding. In addition, the structures determined for the FRB-phosphatidic acid and FRB-HTS-1 complexes revealed a striking similarity between the conformations of buried portions of the ligands and that seen for the rapamycin backbone in contact with the domain. Our findings further highlight the importance of the FRB domain in small molecule-mediated regulation of mTOR, demonstrate the ability to identify novel inhibitors of mTOR that bind tightly to the rapamycin-binding site in the absence of FKBP12, and identify a potential new regulatory site that may be exploited in the design of new anticancer drugs.

Structure of the C-terminal MA-3 domain of the tumour suppressor protein Pdcd4 and characterization of its interaction with eIF4A.

Programmed cell death protein 4 (Pdcd4) is a novel tumour suppressor protein, which is involved in the control of eukaryotic transcription and translation. The regulation of translation involves specific interactions with eukaryotic initiation factor (eIF)4A and eIF4G, which are mediated via the two tandem MA-3 domains. We have determined the structure of the C-terminal MA-3 domain of Pdcd4 (Pdcd4 MA-3(C)), characterized its interaction with eIF4A and compared the features of nuclear magnetic resonance (NMR) spectra obtained from the single domain and tandem MA-3 region. Pdcd4 MA-3(C) is composed of three layers of helix-turn-helix hairpins capped by a single helix and shows close structural homology to the atypical HEAT repeats found in many eIFs. The sequence conservation and NMR data strongly suggest that the tandem MA-3 region is composed of two equivalent domains connected by a somewhat flexible linker. Pdcd4 MA-3(C) was found to interact with the N-terminal domain of eIF4A through a conserved surface region encompassing the loop connecting alpha5 and alpha6 and the turn linking alpha3 and alpha4. This site is strongly conserved in other MA-3 domains known to interact with eIF4A, including the preceding domain of Pdcd4, suggesting a common mode of binding.

High-resolution solution structure of human intestinal trefoil factor and functional insights from detailed structural comparisons with the other members of the trefoil family of mammalian cell motility factors.

The secreted proteins intestinal trefoil factor (ITF, 59 residues), pS2 (60 residues), and spasmolytic polypeptide (SP, 106 residues) form a small family of trefoil domain-containing mammalian cell motility factors, which are essential for the maintenance of all mucous-coated epithelial surfaces. We have used 1H NMR spectroscopy to determine the high-resolution structure of human ITF, which has allowed detailed structural comparisons with the other trefoil cell motility factors. The conformation of residues 10-53 of hITF is determined to high precision, but the structure of the N- and C-terrminal residues is poorly defined by the NMR data, which is probably indicative of significant mobility. The core of the trefoil domain in hITF consists of a two-stranded antiparallel beta-sheet (Cys 36 to Asp 39 and Trp 47 to Lys 50), which is capped by an irregular loop and forms a central hairpin (loop 3). The beta-sheet is preceded by a short alpha-helix (Lys 29 to Arg 34), with the majority of the remainder of the domain contained in two loops formed from His 25 to Pro 28 (loop 2) and Ala 12 to Arg 18 (loop 1), which lie on either side of the central hairpin. The region formed by the surface of loop 2, the cleft between loop 2 and loop 3, and the adjacent face of loop 3 has previously been proposed to form the functional site of trefoil domains. Detailed comparisons of the backbone conformations and surface features of the family of trefoil cell motility factors (porcine SP, pS2, and hITF) have identified significant structural and electrostatic differences in the loop 2/loop 3 regions, which suggest that each trefoil protein has a specific target or group of target molecules.

Tyrosine 36 plays a critical role in the interaction of the AB loop of tissue inhibitor of metalloproteinases-2 with matrix metalloproteinase-14.

The tissue inhibitor of metalloproteinases-2 (TIMP-2) is potentially an important inhibitor of all known matrix metalloproteinases (MMPs). However, it has been shown to undergo specific interactions with both MMP-2 (gelatinase A) and MMP-14 (MT1-MMP), and it has been proposed that these three proteins function as a cell surface-based activation cascade for matrix metalloproteinases and as a focus of proteolytic activity. In this study, we have carried out mutagenesis and kinetic analyses to examine the unique interactions between the AB loop of TIMP-2 and MMP-14. The results demonstrate that the major binding contribution of the AB loop is due solely to residue Tyr-36 at the tip of the hairpin. From this work, we propose that TIMP-2 may be engineered to abrogate MMP-14 binding, whereas its binding properties for other MMPs, including MMP-2, are maintained. Mutants of TIMP-2 with more directed specificity may be of use in gene therapeutic approaches to human disease.

The effect of matrix metalloproteinase complex formation on the conformational mobility of tissue inhibitor of metalloproteinases-2 (TIMP-2).

The backbone mobility of the N-terminal domain of tissue inhibitor of metalloproteinases-2 (N-TIMP-2) was determined both for the free protein and when bound to the catalytic domain of matrix metalloproteinase-3 (N-MMP-3). Regions of the protein with internal motion were identified by comparison of the T(1) and T(2) relaxation times and (1)H-(15)N nuclear Overhauser effect values for the backbone amide (15)N signals for each residue in the sequence. This analysis revealed rapid internal motion on the picosecond to nanosecond time scale for several regions of free N-TIMP-2, including the extended beta-hairpin between beta-strands A and B, which forms part of the MMP binding site. Evidence of relatively slow motion indicative of exchange between two or more local conformations on a microsecond to millisecond time scale was also found in the free protein, including two other regions of the MMP binding site (the CD and EF loops). On formation of a tight N-TIMP-2. N-MMP-3 complex, the rapid internal motion of the AB beta-hairpin was largely abolished, a change consistent with tight binding of this region to the MMP-3 catalytic domain. The extended AB beta-hairpin is not a feature of all members of the TIMP family; therefore, the binding of this highly mobile region to a site distant from the catalytic cleft of the MMPs suggests a key role in TIMP-2 binding specificity.

High resolution structure of the N-terminal domain of tissue inhibitor of metalloproteinases-2 and characterization of its interaction site with matrix metalloproteinase-3.

The high resolution structure of the N-terminal domain of tissue inhibitor of metalloproteinases-2 (N-TIMP-2) in solution has been determined using multidimensional heteronuclear NMR spectroscopy, with the structural calculations based on an extensive set of constraints, including 3132 nuclear Overhauser effect-based distance constraints, 56 hydrogen bond constraints, and 220 torsion angle constraints (an average of 26.9 constraints/residue). The core of the protein consists of a five-stranded beta-barrel that is homologous to the beta-barrel found in the oligosaccharide/oligonucleotide binding protein fold. The binding site for the catalytic domain of matrix metalloproteinases-3 (N-MMP-3) on N-TIMP-2 has been mapped by determining the changes in chemical shifts on complex formation for signals from the protein backbone (15N, 13C, and 1H). This approach identified a discrete N-MMP-3 binding site on N-TIMP-2 composed of the N terminus of the protein and the loops between beta-strands AB, CD, and EF. The beta-hairpin formed from strands A and B in N-TIMP-2 is significantly longer than the equivalent structure in TIMP-1, allowing it to make more extensive binding interactions with the MMP catalytic domain. A detailed comparison of the N-TIMP-2 structure with that of TIMP-1 bound to N-MMP-3 (Gomis-Ruth, F.-X., Maskos, K., Betz, M., Bergner, A., Huber, R., Suzuki, K., Yoshida, N., Nagase, H. , Brew, K., Bourne, G. P., Bartunik, H. & Bode, W. (1997) Nature 389, 77-80) revealed that the core beta-barrels are very similar in topology but that the loop connecting beta-strands CD (P67-C72) would need to undergo a large conformational change for TIMP-2 to bind in a similar manner to TIMP-1.

1H NMR structure of an antifungal gamma-thionin protein SIalpha1: similarity to scorpion toxins.

The three-dimensional structure of the Sorghum bicolor seed protein gamma-thionin SIalpha1 has been determined by 2D 1H nuclear magnetic resonance (NMR) spectroscopy. The secondary structure of this 47-residue antifungal protein with four disulphide bridges consists of a three-stranded antiparallel sheet and one helix. The helix is tethered to the sheet by two disulphide bridges which link two successive turns of the helix to alternate residues i, i+2 in one strand. Possible binding sites for antifungal activity are discussed. The same fold has been observed previously in several scorpion toxins.

Solution structure of the B-Myb DNA-binding domain: a possible role for conformational instability of the protein in DNA binding and control of gene expression.

Double- and triple-resonance heteronuclear NMR spectroscopy have been used to determine the high-resolution solution structure of the minimal B-Myb DNA-binding domain (B-MybR2R3) and to characterize the specific complex formed with a synthetic DNA fragment corresponding to the Myb target site on the Myb-regulated gene tom-1. B-MybR2R3 is shown to consist of two independent protein domains (R2 and R3) joined by a short linker, which have strikingly different tertiary structures despite significant sequence similarities. In addition, the C-terminal region of B-Myb R2 is confirmed to have a poorly defined structure, reflecting the existence of multiple conformations in slow to intermediate exchange. This contrasts with the tertiary structure reported for c-MybR2R3, in which both R2 and R3 have the same fold and the C-terminal region of R2 forms a stable, well-defined helix [Ogata, K., et al. (1995) Nat. Struct. Biol. 2, 309-320]. The NMR data suggest there are extensive contacts between B-MybR2R3 and its DNA target site in the complex and are consistent with a significant conformational change in the protein on binding to DNA, with one possibility being the formation of a stable helix in the C-terminal region of R2. In addition, conformational heterogeneity identified in R2 of B-MybR2R3 bound to the tom-1-A target site may play an important role in the control of gene expression by Myb proteins.

Is the phonological loop responsible for intelligence-related differences in forward digit span?

Children with mild mental retardation were compared with CA-matched and verbal-age-matched children without mental retardation on a forward digit span task. Forward digit span is typically used as a measure of the phonological loop (Baddeley, 1986). We hypothesized that intelligence-related differences in forward digit span are largely due to central executive functioning rather than phonological loop functioning. Results showed that the highly significant group difference in forward digit span was reduced to nonsignificance when a measure of central executive functioning was covaried out.

Mapping the binding site for matrix metalloproteinase on the N-terminal domain of the tissue inhibitor of metalloproteinases-2 by NMR chemical shift perturbation.

Changes in the NMR chemical shift of backbone amide nuclei (1H and 15N) have been used to map the matrix metalloproteinase (MMP) binding site on the N-terminal domain of the tissue inhibitor of metalloproteinase-2 (N-TIMP-2). Amide chemical shift changes were measured on formation of a stable complex with the catalytic domain of stromelysin-1 (N-MMP-3). Residues with significantly shifted amide signals mapped specifically to a broad site covering one face of the molecule. This site (the MMP binding site) consists primarily of residues 1-11, 27-41, 68-73, 87-90, and 97-104. The site overlaps with the OB-fold binding site seen in other proteins that share the same five-stranded beta-barrel topology. Sequence conservation data and recent site-directed mutagenesis studies are discussed in relation to the MMP binding site identified in this work.

Chemically and conformationally authentic active domain of human tissue inhibitor of metalloproteinases-2 refolded from bacterial inclusion bodies.

The aggregation of recombinant proteins into inclusion bodies is a major problem for expression in bacterial systems. The inclusion bodies must be solubilized and the denatured protein renatured if an active molecule is to be recovered. We have developed such a procedure for the active N-terminal domain of tissue inhibitor of metalloproteinases-2 [TIMP-2-(1-127)], a small mammalian protein containing three disulfide bonds. Conditions for its renaturation were determined by studying the refolding behaviour of reduced and denatured mammalian-cell-expressed TIMP-(1-127) by intrinsic fluorescence. This strategy allows the development of a refolding protocol before generation of a bacterial expression system, and allows rapid and systematic optimization of each refolding variable by assessing its effect on the rate and extent of the refolding reaction. TIMP-(1-127) was expressed at high levels in Escherichia coli, and refolded from TIMP-2-(1-127) inclusion bodies, by means of the method developed with mammalian-cell-expressed protein, to give a refolding efficiency of 30-40% and a final yield of 11-14 mg purified protein/l culture. The chemical structure and conformation of this material was characterized by electrospray mass spectrometry and two-dimensional 1H-NMR; no significant differences were found between it and the native protein. Mass analysis of uniformly 13C-labeled and 15N-labeled protein was used to help identify a mistranslated TIMP-(1-127) contaminant in the purified refolded sample. This technique provides additional information on the nature of the modification and allows a distinction to be made between those modifications that are cell derived, and those that arise from subsequent handling of the protein.

Structure of the B-Myb DNA-binding domain in solution and evidence for multiple conformations in the region of repeat-2 involved in DNA binding: implications for sequence-specific DNA binding by Myb proteins.

A range of double and triple resonance heteronuclear NMR has been used to obtain nearly complete sequence-specific 15N, 13C and 1H resonance assignments for a 110-residue protein corresponding to the B-Myb DNA-binding domain (B-MybR2R3) and to determine its secondary structure in solution. The protein was found to contain two stable helices in repeat-2 (R2) and three in repeat-3 (R3), involving residues K12-K24 (R2-1), W30-H36 (R2-2), E64-V76 (R3-1), W81-L87 (R3-2) and D93-K105 (R3-3). In addition, the chemical shift and nuclear Overhauser effect data suggest that amino acids Q44-W49 near the C-terminus of R2 form an unstable or nascent helix, which could be stabilised on binding to a specific DNA target site. The two N-terminal helices in R2 and R3 occupy essentially identical positions in the two domains, consistent with the high level of sequence similarity between these regions. In contrast, the C-terminal region forming the third helix in R3 shows low sequence similarity with R2, accounting for the differences in secondary structure. In the case of B-MybR2R3, there is a clear chemical shift and line-broadening evidence for the existence of multiple conformations in the C-terminal region of R2, which is believed to form one half of the DNA-binding site. We propose that conformational instability of part of the DNA-binding motif is a way of increasing the specificity of Myb proteins for a relatively short (6-bp) DNA target site by reducing their affinity for non-specific DNA sequences compared to specific sites.

NMR-based structural studies of the pNR-2/pS2 single domain trefoil peptide. Similarities to porcine spasmolytic peptide and evidence for a monomeric structure.

NMR spectroscopy measurements have been used to obtain structural information about the pNR-2/pS2 single-domain trefoil peptide. NMR data from 2D (two dimensional) double-quantum-filtered correlation spectroscopy (DQF-COSY), total correlation spectroscopy (TOCSY), NOE spectroscopy (NOESY), rotating frame NOE spectroscopy (ROESY) and 2D 13C-1H heteronuclear single-quantum coherence (HSQC) and 13C-1H HSQC-TOCSY spectra have been analysed to provide essentially complete 1H and 13C sequence-specific assignments for the pNR-2/pS2 protein. From a consideration of the NOE intensities, 3J(NH-alpha CH) coupling constants, 1H and 13C chemical shifts of backbone atoms and amide-proton exchange rates, the pNR-2/pS2 was found to contain two short antiparallel beta-strands (32-35 and 43-46), a short helix (25-30) and a type I beta-turn (11-15). These elements of secondary structure are very similar to those found in the two trefoil domains of pSP for which detailed structural information is already available. Similar 1H chemical shifts were noted for several conserved residues in pNR-2/pS2 and pSP and a characteristic Phe residue with a slowly flipping ring was found in the pNR-2/pS2 variant and in both domains of pSP. The tertiary structures of the domains therefore appear to be very similar in the two proteins and it is likely that the pNR-2/pS2 has the same pattern of disulphide bonds (1-5, 2-4, 3-6) as pSP. Correlation time measurements derived from 1H-1H NOE measurements indicate that the Cys58-->Ser form of the pNR-2/pS2 protein used in this study is monomeric in solution at approximately 2 mM.

Solution structure of the active domain of tissue inhibitor of metalloproteinases-2. A new member of the OB fold protein family.

Homonuclear two-dimensional and three-dimensional 1H nuclear magnetic resonance spectroscopy has been used to obtain essentially complete sequence-specific assignments for 123 of the 127 amino acid residues present in the truncated form of tissue inhibitor of metalloproteinases-2 (delta TIMP-2), the active N-terminal domain of the protein. Analysis of the through-space nuclear Overhauser effect data obtained for delta TIMP-2 allowed determination of both the secondary structure of the domain and also a low-resolution tertiary structure defining the protein backbone topology. The protein contains a five-stranded antiparallel beta-sheet that is rolled over on itself to form a closed beta-barrel, and two short helices which pack close to one another on the same barrel face. A comparison of the delta TIMP-2 structure with other known protein folds reveals that the beta-barrel topology is homologous to that seen in proteins of the oligosaccharide/oligonucleotide binding (OB) fold family. The common structural features include the number of beta-strands and their arrangement, the beta-barrel shear number, an interstrand hydrogen bond network, the packing of the hydrophobic core, and a conserved beta-bulge. Superpositions of the beta-barrels from delta TIMP-2 and two previously known members of the OB protein fold family (staphylococcal nuclease and Escherichia coli heat-labile enterotoxin) confirmed the similarity in beta-barrel topology. The three-dimensional structure of delta TIMP-2 has allowed a more detailed interpretation than was previously possible of the functional significance of available protein sequence and site-directed mutagenesis data for the TIMP family. Furthermore, the structure has revealed conserved surface regions of potential functional importance.

Solution structure of a trefoil-motif-containing cell growth factor, porcine spasmolytic protein.

The porcine spasmolytic protein (pSP) is a 106-residue cell growth factor that typifies a family of eukaryotic proteins that contain at least one copy of an approximately 40-amino acid protein domain known as the trefoil motif. In fact, pSP contains two highly homologous trefoil domains. We have determined the complete three-dimensional solution structure of pSP by using a combination of two- and three-dimensional 1H NMR spectroscopy and distance geometry calculations. pSP is a relatively elongated molecule, consisting of two compact globular domains joined via a small interface. The protein's two trefoil domains adopt the same tertiary structure and contain a core C-terminal two-stranded antiparallel beta-sheet, preceded by a 6-residue helix that packs against the N-terminal beta-strand. The remainder of the protein backbone is taken up by two short loops that lie on either side of the beta-hairpin and are linked by an extended region that wraps around the C-terminal beta-strand. The topology of the protein backbone observed for the trefoil domains in pSP represents an unusual polypeptide fold. A striking feature of both trefoil domains is a surface patch formed from five conserved residues that have no obvious structural role. The two patches are located at the far ends of the protein molecule, and we propose that these residues form at least part of the receptor binding site, or sites, on pSP.

Stereospecific assignments of the leucine methyl resonances in the 1H NMR spectrum of Lactobacillus casei dihydrofolate reductase.

A general method is described for the stereospecific assignment of methyl resonances in protein NMR spectra based on selective deuteration procedures. A selectively deuterated dihydrofolate reductase from L. casei was prepared by incorporating stereoselectively deuterated L-leucine, (2S,4R)[5,5,5-2H3]leucine. By comparing the COSY spectra of the dihydrofolate reductase-methotrexate complexes formed using deuterated and non-deuterated enzyme the stereospecific assignments for resonances of all 13 leucine residues were obtained by noting the absence of cross-peaks in spectra from the deuterated proteins.