The enzyme peptidyl-prolyl cis-trans isomerase (PPIase) was recently discovered in mammalian tissues and purified from porcine kidney. It catalyses the slow cis-trans isomerization of proline peptide (Xaa-Pro) bonds in oligopeptides and accelerates slow, rate-limiting steps in the folding of several proteins. Here, we report the N-terminal sequence of PPIase together with further chemical and enzymatic properties. The results indicate that this enzyme is probably identical to cyclophilin, a recently discovered mammalian protein which binds tightly to cyclosporin A (CsA). Cyclophilin is thought to be linked to the immunosuppressive action of CsA. The first 38 amino-acid residues of porcine PPIase and of bovine cyclophilin are identical and the two proteins both have a relative molecular mass of about 17,000 (ref. 7). The catalysis of prolyl isomerization in oligopeptides and of protein folding by PPIase are strongly inhibited in the presence of low levels of CsA. The activities of both PPIase and cyclophilin depend on a single sulphydryl group. At present it is unknown whether the inhibition of prolyl isomerase activity is related with the immunosuppressive action of CsA.
Rates of protein folding reactions vary considerably. Some denatured proteins regain the native conformation within milliseconds or seconds, whereas others refold very slowly in the time range of minutes or hours. Varying folding rates are observed not only for different proteins, but can also be detected for single polypeptide species. This originates from the co-existence of fast- and slow-folding forms of the unfolded protein, which regain the native state with different rates. The proline hypothesis provides a plausible explanation for this heterogeneity. It assumes that the slow-folding molecules possess non-native isomers of peptide bonds between proline and another residue, and that crucial steps in the refolding of the slow-folding molecules are limited in rate by the slow reisomerization of such incorrect proline peptide bonds. Recently the enzyme peptidyl-prolyl cis-trans isomerase (PPIase) was discovered and purified from pig kidney. It catalyses efficiently the cis in equilibrium trans isomerization of proline imidic peptide bonds in oligopeptides. Here we show that it also catalyses slow steps in the refolding of a number of proteins of which fast- and slow-folding species have been observed and where it was suggested that proline isomerization was involved in slow refolding. The efficiency of catalysis depends on the accessibility for the isomerase of the particular proline peptide bonds in the refolding protein chain.
The growth potentiating effects of the insulin-like growth factor (IGF)-I and IGF-II are modulated by a family of six insulin-like growth factor binding proteins (IGFBPs). Despite the similarity in amino acid sequences of the IGFBPs, their effects on the growth of bone cells differ. Studies on the molecular mechanisms for IGFBP-4 actions revealed that coincubation of bone cells with IGFBP-4 and 125I-IGF-I or 125I-IGF-II decreased the binding of both of these ligands in a dose-dependent manner. In addition, IGFBP-4 decreased the binding of IGF-I tracer to purified type I IGF receptor. These data in conjunction with data showing that IGFBP-4 had no effect on cell proliferation induced by analogs of IGF-I or IGF-II, which exhibited > 100-fold reduced affinity for binding to IGFBP-4 suggest that IGFBP-4 may inhibit IGF action by preventing the binding of ligand to its membrane receptor. In contrast to IGFBP-4, IGFBP-5 treatment increased the binding of IGF tracer to bone cells but did not increase the binding of 125I-IGF-I to type I IGF receptor. Studies on the mechanism by which IGFBP-5 increased the binding of 125I-IGF tracer to bone cells suggest that IGFBP-5 could facilitate IGF binding by a mechanism in which IGFBP-5 has cell surface binding sites independent of IGF receptors. These data in conjunction with the findings that IGFBP-5 potentiated cell proliferation even in the presence of those same IGF analogs that exhibited > 200-fold reduced affinity for binding to IGFBP-5, suggest that IGFBP-5 may in part stimulate bone cell proliferation by an IGF-independent mechanism involving IGFBP-5-specific cell surface binding sites.
Binding proteins for insulin-like growth factors (IGFs) IGF-I and IGF-II, known as IGFBPs, control the distribution, function and activity of IGFs in various cell tissues and body fluids. Insulin-like growth factor-binding protein-5 (IGFBP-5) is known to modulate the stimulatory effects of IGFs and is the major IGF-binding protein in bone tissue. We have expressed two N-terminal fragments of IGFBP-5 in Escherichia coli; the first encodes the N-terminal domain of the protein (residues 1-104) and the second, mini-IGFBP-5, comprises residues Ala40 to Ile92. We show that the entire IGFBP-5 protein contains only one high-affinity binding site for IGFs, located in mini-IGFBP-5. The solution structure of mini-IGFBP-5, determined by nuclear magnetic resonance spectroscopy, discloses a rigid, globular structure that consists of a centrally located three-stranded anti-parallel beta-sheet. Its scaffold is stabilized further by two inside packed disulfide bridges. The binding to IGFs, which is in the nanomolar range, involves conserved Leu and Val residues localized in a hydrophobic patch on the surface of the IGFBP-5 protein. Remarkably, the IGF-I receptor binding assays of IGFBP-5 showed that IGFBP-5 inhibits the binding of IGFs to the IGF-I receptor, resulting in reduction of receptor stimulation and autophosphorylation. Compared with the full-length IGFBP-5, the smaller N-terminal fragments were less efficient inhibitors of the IGF-I receptor binding of IGFs.
The p53 protein is a transcription factor that acts as the major tumor suppressor in mammals. The core DNAbinding domain is mutated in about 50% of all human tumors. The crystal structure of the core domain in complex with DNA illustrated how a single core domain specifically interacts with its DNA consensus site and how it is inactivated by mutation. However, no structural information for the tetrameric full-length p53-DNA complex is available. Here, we present novel experimental insight into the dimerization of two p53 core domains upon cooperative binding to consensus DNA in solution obtained by NMR. The NMR data show that the p53 core domain itself does not appear to undergo major conformational changes upon addition of DNA and elucidate the dimerization interface between two DNA-bound core domains, which includes the short H1 helix. A NMR-based model for the dimeric p53 core-DNA complex incorporates these data and allows the conclusion that the dimerization interface also forms the actual interface in the tetrameric p53-DNA complex. The significance of this interface is further corroborated by the finding that hot spot mutations map to the H1 helix, and by the binding of the putative p53 inhibitor 53BP2 to this region via one of its ankyrin repeats. Based on symmetry considerations it is proposed that tetrameric p53 might link non-contigous DNA consensus sites in a sandwich-like manner generating DNA loops as observed for transcriptionally active p53 complexes.The tumor suppressor gene p53 is the most frequent site of genetic alterations found in human tumors (1) and acts as the major tumor suppressor in mammals. In addition to non-transcriptional functions, p53 acts primarily as a transcriptional activator, that regulates the expression of several genes involved in cell cycle arrest, cellular senescence, anti-angiogenesis, and apoptosis (reviewed in Refs. 2-4). Recently, two homologues of p53, p63 and p73, were discovered, coding for a variety of different isoforms. These three p53 family members play distinct roles in differentiation, development, and tumor suppression (reviewed in Ref. 5). p53 possesses a modular architecture with an N-terminal transactivation domain (TAD), 1 a strongly conserved core DNA-binding domain (DBD), a tetramerization domain (TD), and a regulatory C terminus (6, 7). Tetrameric p53 binds specifically to a DNA consensus sequence consisting of two consecutive palindromic 10-bp halfsites, where each half-site is formed by two head-to-head quarter-sites (8 -12). The isolated TD forms a symmetric dimer of dimers (13-15), and contrasting models have been proposed that describe how the DBDs of each dimer are attached to DNA, namely with either consecutive or alternating arrangements (16). The p53 DBD comprises several hot spot regions for mutation that inactivate p53 in more than half of all human tumors (1). Therefore, wild-type and mutant p53 DBDs have been the focus of various studies (17-21). The crystal structure of the p53 DBD in complex with DNA (10) showed that almost all known...
Insulin-like growth factors (IGFs) are key regulators of cell proliferation, differentiation and transformation, and are thus pivotal in cancer, especially breast, prostate and colon neoplasms. They are also important in many neurological and bone disorders. Their potent mitogenic and anti-apoptotic actions depend primarily on their availability to bind to the cell surface IGF-I receptor. In circulation and interstitial fluids, IGFs are largely unavailable as they are tightly associated with IGF-binding proteins (IGFBPs) and are released after IGFBP proteolysis. Here we report the 2.1 A crystal structure of the complex of IGF-I bound to the N-terminal IGF-binding domain of IGFBP-5 (mini-IGFBP-5), a prototype interaction for all N-terminal domains of the IGFBP family. The principal interactions in the complex comprise interlaced hydrophobic side chains that protrude from both IGF-I and the IGFBP-5 fragment and a surrounding network of polar interactions. A solvent-exposed hydrophobic patch is located on the IGF-I pole opposite to the mini-IGFBP-5 binding region and marks the IGF-I receptor binding site.
Insulin-like growth factor binding proteins (IGFBPs) control the extracellular distribution, function, and activity of IGFs. Here, we report an X-ray structure of the binary complex of IGF-I and the N-terminal domain of IGFBP-4 (NBP-4, residues 3-82) and a model of the ternary complex of IGF-I, NBP-4, and the C-terminal domain (CBP-4, residues 151-232) derived from diffraction data with weak definition of the C-terminal domain. These structures show how the IGFBPs regulate IGF signaling. Key features of the structures include (1) a disulphide bond ladder that binds to IGF and partially masks the IGF residues responsible for type 1 IGF receptor (IGF-IR) binding, (2) the high-affinity IGF-I interaction site formed by residues 39-82 in a globular fold, and (3) CBP-4 interactions. Although CBP-4 does not bind individually to either IGF-I or NBP-4, in the ternary complex, CBP-4 contacts both and also blocks the IGF-IR binding region of IGF-I.
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