Proteins can exist in a trinity of structures: the ordered state, the molten globule and the random coil. Five examples follow which suggest that native protein structure can correspond to any of the three states (not just the ordered state) and that protein function can arise from any of the three states and their transitions. 1. In a process that likely mimics infection, fd phage converts from the ordered into the disordered molten globular state. 2. Nucleosome hyperacetylation is crucial to DNA replication and transcription; this chemical modification greatly increases the net negative charge of the nucleosome core particle. We propose that the increased charge imbalance promotes its conversion to a much less rigid form. 3. Clusterin contains an ordered domain and also a native molten globular region. The molten globular domain likely functions as a proteinaceous detergent for cell remodeling and removal of apoptotic debris. 4. In a critical signaling event, a helix in calcineurin becomes bound and surrounded by calmodulin, thereby turning on calcineurin's serine/threonine phosphatase activity.Locating the calcineurin helix within a region of disorder is essential for enabling calmodulin to surround its target upon binding. 5. Calsequestrin regulates calcium levels in the sarcoplasmic reticulum by binding about 50 ions/molecule. Disordered polyanion tails at the carboxy terminus bind many of these calcium ions, perhaps without adopting a unique structure. In addition to these examples, 16 more proteins with native disorder will be discussed. These disordered regions include molecular recognition domains, protein folding inhibitors, flexible linkers, entropic springs, entropic clocks and entropic bristles.Motivated by such examples of intrinsic disorder, we are studying the relationships between amino acid sequence and order/disorder, and from this information we are predicting intrinsic order/disorder from amino acid sequence.The sequence/structure relationships indicate that disorder is an encoded property, and the predictions strongly suggest that proteins in nature are much richer in intrinsic disorder than are those in the Protein Data Bank. Recent predictions on 29 genomes indicate that proteins from eucaryotes apparently have more intrinsic disorder than those from either bacteria or archaea, with typically > 30 % of eucaryotic proteins having disordered regions of length = 50 consecutive residues.
Calcineurin (CaN) is a calcium- and calmodulin-dependent protein serine/threonine phosphate which is critical for several important cellular processes, including T-cell activation. CaN is the target of the immunosuppressive drugs cyclosporin A and FK506, which inhibit CaN after forming complexes with cytoplasmic binding proteins (cyclophilin and FKBP12, respectively). We report here the crystal structures of full-length human CaN at 2.1 A resolution and of the complex of human CaN with FKBP12-FK506 at 3.5 A resolution. In the native CaN structure, an auto-inhibitory element binds at the Zn/Fe-containing active site. The metal-site geometry and active-site water structure suggest a catalytic mechanism involving nucleophilic attack on the substrate phosphate by a metal-activated water molecule. In the FKBP12-FK506-CaN complex, the auto-inhibitory element is displaced from the active site. The site of binding of FKBP12-FK506 appears to be shared by other non-competitive inhibitors of calcineurin, including a natural anchoring protein.
A new procedure for molecular replacement is presented in which an ef®cient six-dimensional search is carried out using an evolutionary optimization algorithm. In this procedure, a population of initially random molecular-replacement solutions is iteratively optimized with respect to the correlation coef®cient between observed and calculated structure factors. The sensitivity and reliability of the method is enhanced by uniform sampling of the rotational-search space and the use of continuously variable rotational and translational parameters. The process is several orders of magnitude faster than a systematic six-dimensional search, and comparisons show that it can identify solutions using signi®cantly less accurate or less complete search models than is possible with two existing molecular-replacement methods. A program incorporating the method, EPMR, allows the rapid and highly automated solution of molecular-replacement problems involving single or multiple molecules in the asymmetric unit. EPMR has been used to solve a number of dif®cult molecular-replacement problems.
The targets of the Structural GenomiX (SGX) bacterial genomics project were proteins conserved in multiple prokaryotic organisms with no obvious sequence homolog in the Protein Data Bank of known structures. The outcome of this work was 80 structures, covering 60 unique sequences and 49 different genes. Experimental phase determination from proteins incorporating Se-Met was carried out for 45 structures with most of the remainder solved by molecular replacement using members of the experimentally phased set as search models. An automated tool was developed to deposit these structures in the Protein Data Bank, along with the associated X-ray diffraction data (including refined experimental phases) and experimentally confirmed sequences. BLAST comparisons of the SGX structures with structures that had appeared in the Protein Data Bank over the intervening 3.5 years since the SGX target list had been compiled identified homologs for 49 of the 60 unique sequences represented by the SGX structures. This result indicates that, for bacterial structures that are relatively easy to express, purify, and crystallize, the structural coverage of gene space is proceeding rapidly. More distant sequence-structure relationships between the SGX and PDB structures were investigated using PDB-BLAST and Combinatorial Extension (CE). Only one structure, SufD, has a truly unique topology compared to all folds in the PDB.
The structure of the Drosophila engrailed homeodomain has been solved by molecular replacement and refined to an R-factor of 19.7% at a resolution of 2.1 A. This structure offers a high-resolution view of an important family of DNA-binding proteins and allows comparison to the structure of the same protein bound to DNA. The most significant difference between the current structure and that of the 2.8-A engrailed-DNA complex is the close packing of an extended strand against the rest of the protein in the unbound protein. Structural features of the protein not previously noted include a "herringbone" packing of 4 aromatic residues in the core of the protein and an extensive network of salt bridges that covers much of the helix 1-helix 2 surface. Other features that may play a role in stabilizing the native state include the interaction of buried carbonyl oxygen atoms with the edge of Phe 49 and a bias toward statistically preferred side-chain dihedral angles. There is substantial disorder at both ends of the 61 amino acid protein. A 51-amino acid variant of engrailed (residues 6-56) was synthesized and shown by CD and thermal denaturation studies to be structurally and thermodynamically similar to the full-length domain.Keywords: crystallography; homeodomain; protein stability; protein structure Homeodomains are common eukaryotic DNA-binding domains that consist of a short extended strand followed by 3 helices (Qian et al., 1989;Kissinger et al., 1990;Laughon 1991;Wolberger et al., 1991). The homeodomain itself (conventionally defined as being 60 amino acids in length on the basis of homology) contains much of the DNA-binding specificity and affinity of the much larger proteins in which it is found (Kornberg, 1993). Moderate-resolution crystal structures of 3 protein:DNA complexes that include homeodomains (engrailed, MATa2, and Oct-1) have been determined, as have the NMR structures of Antennapedia (Antp), an Antp:DNA complex, and fushi tarazu (ftz) (Qian et al., 1989(Qian et al., , 1994Kissinger et al., 1990;Wolberger et al., 1991;Billeter et al., 1993;Klemm et al., 1994). There is considerable interest in understanding how these domains recognize DNA.Homeodomains are also of interest because they present an extremely simple model system for studies related to protein folding. They are small and monomeric and do not require disulfide bonds or ligands in order to fold stably. There is considerable sequence diversity among the several hundred homeodomain sequences known, but a conserved pattern of hydrophobic residues and the similarity of the known structures suggests that each of the hundreds of sequences adopts the same overall structure (Scott et al., 1989;Laughon, 1991).We have obtained a high-resolution structure of the engrailed homeodomain in the absence of DNA (Kinemage 1). This structure is useful because (1) it allows direct comparison to the crystallographic structure of a homedomain bound to DNA and (2) it provides a more accurate coordinate set for studies of the sequence-structure relations...
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