Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:3.4.21.1 (chymotrypsin)
10,938 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The 106-amino acid sequence motifs of spectrin have been suggested to fold into stable structural domains, consisting mostly of coiled coils of triple helices. With the advent of molecular biology and biophysical techniques, structural studies of these spectrin 106-amino acid structural domains became approachable. However, one of the difficulties in such an approach is determination of the correct phasing of the structural domains, which may or may not coincide with the phasing of the sequence motifs. Proper identification of the domain phasing is vital to the construction of stable spectrin domains for molecular studies. A previously published phasing shift for Drosophila alpha-spectrin indicated a downstream phase-shift of 26 amino acids for the structural domain (Winograd, E., Hume, D., and Branton, D. (1991) Proc. Natl. Acad. Sci. U. S. A. 88, 10788-10791). Using this phase-shift, we prepared a recombinant spectrin peptide with the sequence from residue 49 to residue 155 of human erythrocyte alpha-spectrin and found this peptide to be unstable relative to other peptides that we prepared. Using several other recombinant alpha-spectrin peptides and following the protease digestion approach, we digested spectrin peptides with elastase and chymotrypsin and analyzed the amino acid sequence of the digestive products. We provide the first experimental evidence in identifying the first amino acid residue of the first spectrin domain in human erythrocyte alpha-spectrin as residue 52 (Ser).
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PMID:The first human alpha-spectrin structural domain begins with serine. 792 3

The tryptophan that is highly conserved among repeating structural units of spectrin is reported to promote the conformational stability of one such unit of chicken brain alpha-spectrin. Four constructs were inserted into pET vectors for overexpression in Escherichia coli of the following spectrin peptides: (i) two adjacent but separately expressed "conformationally phased" repeating units, R16 and R17, one of which (R17) contains a single tryptophan; (ii) a mutant, M17, of the single tryptophan-containing unit with alanine substituted for the tryptophan; and (iii) a conformationally unphased unit, 1617, composed of half of each of the phased units. Both the mutant unit and the unphased unit were much more readily digested by chymotrypsin and by elastase than the phased units and exhibited only 38% and 54% as much alpha-helical structure, respectively, as the phased units by their far UV CD spectra; 90 degrees light scattering measurements revealed the folded peptides to be predominantly monomeric in solution, whereas the unfolded, protease-sensitive peptides consisted of dimers and/or trimers. This trend was corroborated by their dynamic light scattering. Both the blue-shifted wavelength of maximal emission and the relative inaccessibility to acrylamide of the single tryptophan in the folded unit indicate that the invariant tryptophan occupies a site that is shielded from the aqueous phase.
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PMID:Invariant tryptophan at a shielded site promotes folding of the conformational unit of spectrin. 810 5

The 64-residue chymotrypsin inhibitor 2 (CI2) folds by a two-state nucleation-condensation mechanism, whereby secondary and tertiary structure coalesce concomitantly in the transition state around Ala 16 in the helical N-cap. Permutation of the SH3-domain of alpha-spectrin apparently shifts its folding nucleus to another region of the protein, suggesting that a protein's transition state may be altered by altering the protein's connectivity. We have characterized the structure of the transition state of a circular and a permuted version of CI2 by a protein engineering study encompassing 11 mutations. Circular CI2 was obtained by the introduction of cysteines at residues 3 and 63 and linking them by disulfide bond formation. Subsequent cyanogen-bromide cleavage of the scissile bond, Met 40-Glu 41, yielded permuted CI2. Circular and permuted CI2 also fold according to a two-state mechanism. Permutation does not affect the folding rate constant, but circularization increases it 7-fold. The transition states of circular and permuted CI2 are essentially unchanged from that of wild-type CI2. Importantly, the folding nucleus around Ala16 is retained. These results complement a previous observation that the transition state for association of two CI2 fragments (residues 1-40 and 41-64, generated by CNBr cleavage) is very similar to the folding transition state of intact CI2. The similarity of rate constants for folding of wild-type and permuted CI2, and their value relative to that for the association of fragments, allows us to estimate the gain in entropy of activation on having the separate fragments linked: 18.3 cal M-1 K-1; i.e. an effective molarity of 10(4) M. The contrast between the retention of the folding nucleus on permutation of CI2 and its change for the SH3-domain of alpha-spectrin probably arises because the latter was cleaved in its folding nucleus whereas cleavage at sites other than 40-41 in CI2 is very destabilizing. Whether or not a folding nucleus can be changed probably depends on the specific protein and its permissivity to permutation.
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PMID:Folding of circular and permuted chymotrypsin inhibitor 2: retention of the folding nucleus. 960 9

The nature of the nucleation-collapse mechanism in protein folding is probed using 27-mer and 36-mer lattice models. Three different forms for the interaction potentials are used. Three of the four 27-mer sequences have maximally compact and identical native state while the other has a non-compact native conformation. All the sequences fold thermodynamically and kinetically by a two-state process. Analysis of individual trajectories for each sequence using a self-organizing neural net algorithm shows that upon formation of a critical set of contacts the polypeptide chain rapidly reaches the native conformation which is consistent with a nucleation-collapse mechanism. The algorithm, which reduces the identification of the folding nucleus for each trajectory to one of pattern recognition, is used to show that there are multiple folding nuclei. There is a distribution of nucleation contacts in the transition states with some of them occurring with more probability (when averaged over the denatured ensemble) than others. We also show that there is a distribution in the size of the nuclei with the average number of residues in the folding nuclei being less than about one-third of the chain size. The fluctuations in the sizes of the nuclei are large, suggestive of a broad transition region. The folding nuclei, the structures of each are the corresponding transition states, have varying degree of overlap with the native conformation. The distribution of the radius of gyration of the transition states shows that these structures are an expanded form (by about 25% in the radius of gyration) of the native conformation. Local contacts are most dominant in the folding nuclei while a certain fraction of non-local contacts is necessary to stabilize the transition states. The search for the critical nuclei initially involves the formation of local contacts, while non-local contacts are formed later. The fractional values of PhiF for the two 27-mer mutants found by using the protein engineering protocol are consistent with the microscopic picture of partial formation of structures involving these residues in the transition state. These observations lead to a multiple folding nuclei (MFN) model for nucleation-collapse mechanism in protein folding. The major implication of the MFN model is that, even if the residues whose tertiary interactions are formed nearly completely in the transition state are mutated, it does not disrupt the nature of the nucleation-collapse mechanism. We analyze the experiments on chymotrypsin inhibitor 2 and alpha-spectrin SH3 domain and two circular permutants in light of the MFN model. It is shown that the PhiF-value analysis for these proteins gives considerable support to the MFN model. The theoretical and experimental studies give a coherent picture of the nucleation-collapse mechanism in which there is a distribution of folding nuclei with some more probable than others. The formation of any specific nucleus is not necessary for efficient two-state folding.
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PMID:Lattice models for proteins reveal multiple folding nuclei for nucleation-collapse mechanism. 973 20

The structure of the transition state for folding/unfolding of the immunophilin FKBP12 has been characterised using a combination of protein engineering techniques, unfolding kinetics, and molecular dynamics simulations. A total of 34 mutations were made at sites throughout the protein to probe the extent of secondary and tertiary structure in the transition state. The transition state for folding is compact compared with the unfolded state, with an approximately 30 % increase in the native solvent-accessible surface area. All of the interactions are substantially weaker in the transition state, as probed by both experiment and molecular dynamics simulations. In contrast to some other proteins of this size, no element of structure is fully formed in the transition state; instead, the transition state is similar to that found for smaller, single-domain proteins, such as chymotrypsin inhibitor 2 and the SH3 domain from alpha-spectrin. For FKBP12, the central three strands of the beta-sheet, beta-strand 2, beta-strand 4 and beta-strand 5, comprise the most structured region of the transition state. In particular Val101, which is one of the most highly buried residues and located in the middle of the central beta-strand, makes approximately 60 % of its native interactions. The outer beta-strands and the ends of the central beta-strands are formed to a lesser degree. The short alpha-helix is largely unstructured in the transition state, as are the loops. The data are consistent with a nucleation-condensation model of folding, the nucleus of which is formed by side-chains within beta-strands 2, 4 and 5, and the C terminus of the alpha-helix. The precise residues involved in the nucleus differ in the two simulated transition state ensembles, but the interacting regions of the protein are conserved. These residues are distant in the primary sequence, demonstrating the importance of tertiary interactions in the transition state. The two independently derived transition state ensembles are structurally similar, which is consistent with a Bronsted analysis confirming that the transition state is an ensemble of states close in structure.
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PMID:Mapping the interactions present in the transition state for unfolding/folding of FKBP12. 1043 31

There have been many studies about the effect of circular permutation on the transition state/folding nucleus of proteins, with sometimes conflicting conclusions from different proteins and permutations. To clarify this important issue, we have studied two circular permutations of a lattice protein model with side-chains. Both permuted sequences have essentially the same native state as the original (wild-type) sequence. Circular permutant 1 cuts at the folding nucleus of the wild-type sequence. As a result, the permutant has a drastically different nucleus and folds more slowly than wild-type. In contrast, circular permutant 2 involves an incision at a site unstructured in the wild-type transition state, and the wild-type nucleus is largely retained in the permutant. In addition, permutant 2 displays both two-state and multi-state folding, with a native-like intermediate state occasionally populated. Neither the wild-type nor permutant 1 has a similar intermediate, and both fold in an apparently two-state manner. Surprisingly, permutant 2 folds at a rate identical with that of the wild-type. The intermediate in permutant 2 is stabilised by native and non-native interactions, and cannot be classified simply as on or off-pathway. So we advise caution in attributing experimental data to on or off-pathway intermediates. Finally, our work illuminates the results on alpha-spectrin SH3, chymotrypsin inhibitor 2 and beta-lactoglobulin, and supports a key assumption in the experimental efforts to locate potential nucleation sites of real proteins via circular permutations.
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PMID:Different circular permutations produced different folding nuclei in proteins: a computational study. 1117 98

To explore the role of entropy and chain connectivity in protein folding, a particularly interesting scheme, namely, the circular permutation, has been used. Recently, experimental observations showed that there are large differences in the folding mechanisms between the wild-type proteins and their circular permutants. These differences are strongly related to the change in the intrachain connectivity. Some results obtained by molecular dynamics simulations also showed a good agreement with the experimental findings. Here, we use a topology-based free-energy functional method to study the role of the chain connectivity in folding by comparing features of transition states of the wild-type proteins with those of their circular permutants. We concentrate our study on 3 small globular proteins, namely, the alpha-spectrin SH3 domain (SH3), the chymotrypsin inhibitor 2 (CI2), and the ribosomal protein S6, and obtain exciting results that are consistent with the available experimental and simulation results. A heterogeneity of the interaction energies between contacts for protein CI2 and for protein S6 is also introduced, which characterizes the strong interactions between contacts with long loops, as speculated from experiments for protein S6. The comparison between the folding nucleus of the wild-type proteins and those of their circular permutants indicates that chain connectivity affects remarkably the shapes of the energy profiles and thus the folding mechanism. Further comparisons between our theoretical calculated phi(th) values and the experimental observed phi(exp) values for the 3 proteins and their permutants show that our results are in good agreement with experimental ones and that correlations between them are high. These indicate that the free-energy functional method really provides a way to analyze the folding behavior of the circular-permuted proteins and therefore the folding mechanism of the wild-type proteins.
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PMID:Transition states for folding of circular-permuted proteins. 1532 1

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