Processing and presentation of insulin. I. Analysis of immunogenic peptides and processing requirements for insulin A loop-specific T cells

The processing and presentation of insulin by B hybridoma cells to insulin A loop-specific T cell hybridomas was investigated. We found that the activation of these T cells requires insulin to be processed in a manner that permits unfolding of the molecule and prevents extensive proteolysis. An analysis of insulin peptides formed by either enzymatic digestion in vitro or solid phase synthesis revealed that a conformational determinant comprised of residues A1-A14 disulfide-linked to B7-B15 is most immunogenic to these T cells. Reduction and/or proteolysis of this peptide markedly decreases its immunogenicity. The pork insulin A1-A14/B7-B15 peptide differs only at residue A4 from its mouse insulin homolog. Thus, Glu A4 forms part of the antigenic site recognized by a pork insulin/I-Ad-specific mouse T cell. This insulin peptide can be induced to assume an alpha-helical configuration in a hydrophobic environment. In addition, virtually all of the residues of this peptide are identical with those predicted to be situated in amphipathic regions of the native insulin molecule. N-Ethylmaleimide and bacitracin, which inhibit the activity of two cytosolic enzymes that cleave insulin, enhance the antigen presentation of insulin. This suggests that these enzymes may participate in the nonlysosomal antigen processing of insulin by a B lymphocyte. A comparison of the relative avidity of several T cell hybridomas, which have the same apparent specificity for this insulin peptide, showed that an increase in their avidity was associated with a degeneracy in their fine specificity. Our data demonstrate that the efficiency of processing and presentation of a given antigenic determinant is related to the conformation of the determinant and the specificity and avidity of the T cell.     

In vitro processing of insulin for recognition by murine T cells results in the generation of A chains with free CysSH.

Studies on the processing of insulin as an Ag for the presentation to MHC class II-restricted T cells revealed that the amino acid residues 1-14 of the insulin A chain are recognized by insulin-specific T cells. An A1-14 peptide containing three cys-residues that were protected by S-sulfonate groups still needed processing by APC for efficient presentation similar to native insulin. We suspected that reductive deblocking or opening of disulfide bonds that generates CysSH-residues may be an essential processing step for these Ag. Due to the instability of SH-groups it was not possible to test A chain peptides with free SH-groups in the usual way for processing-independent presentation by fixed APC. However, under acidic conditions (pH 5) during APC pulsing with the Ag we could demonstrate that the freshly reduced A1-14 fragment as well as reduced insulin are able to bind to Ia Ag and to stimulate appropriate T cells without further processing. Various substitutions of cys-residues by Ser within this peptide revealed that only CysA7 is critical for Ia binding and/or T cell recognition. In intact insulin, this residue links the A chain containing the T cell epitope to the B chain. Therefore, we propose that insulin processing is not dependent on proteolysis or on the generation of a conformational determinant but on the separation of A and B chains resulting in A chains whose cys-residues are converted into CysSH.     

T cell autoreactivity to insulin in diabetic and related non-diabetic individuals

T cell autoreactivity to insulin in type I diabetic and related non-diabetic individuals was analyzed. Peripheral T lymphocytes from both insulin-treated diabetic and untreated non-diabetic members of four families were found to proliferate in vitro in response to human insulin. T cell autoreactivity to insulin therefore does not appear to be diagnostic of the onset of type I diabetes. Highest T cell responses to human insulin were usually detected in insulin-dependent type I diabetes patients treated with a mixture of beef and pork insulin than with self insulin, the greater the dose of animal insulin the higher the T cell response. The T cell repertoires for self insulin appear to be similar in diabetics and non-diabetics based on their patterns of T cell reactivity to beef insulin, port insulin, human insulin, and various peptide of human insulin. The autoreactive T cells analyzed recognize two conformational epitopes of human insulin formed by interactions between A chain and B chain residues. One epitope is associated with the A chain loop and is present in the A1-A14/B1-B16 peptide, and the other epitope consists mainly of B chain residues located in the A16-A21/B10-B25 peptide. These two epitopes are present in amphipathic alpha-helical regions of insulin. HLA-DR (DR3, DR4, and DR5) and HLA-DQ (DQw2/DQw3) Ag can restrict these T cell responses to human insulin epitopes. The ability to detect insulin-specific autoreactive T cells in healthy non-diabetic individuals supports the hypothesis that autoreactive lymphocytes do not necessarily elicit autoimmune disease if present in an environment in which their activity is immunoregulated.     

Identification of insulin intermediates and sites of cleavage of native insulin by insulin protease from human fibroblasts

We have studied the time sequence degradation of native insulin by insulin protease from human fibroblast using multiple steps involving purification of the products by high performance liquid chromatography, determination of peak composition by amino acid sequence analysis, and confirmation of structure by mass spectrometry and thus elucidated the sites of cleavage of insulin by human insulin protease. We observed that as early as 0.5 min of incubation, three major new peptide peaks, intact insulin, and four smaller peptide peaks can be detected. The major peptides are portions of the insulin molecule, with the amino ends of the A and B chains or the carboxyl ends of the A and B chains still connected by disulfide bonds. Peptide peak I is A1-13-B1-9. Peptide peak II is A1-14-B1-9. Peptide peak III is A14-21-B14-30. The smaller peptide peaks are A14-21-B17-30, A15-21-B14-30, A15-21-B10-30, and A14-21-B10-30. The major peptide bond cleavage sites therefore consist of A13-14, A14-15, B9-10, B13-14, and B10-17. With longer incubation times, peptide peak II appears to lose the A14 tyrosine to form peptide peak I. This peptide I, which is the amino end of the A and B chains, is not further degraded even after 1.5 h of incubation. With longer incubation times, the peptides containing the carboxyl ends of the A and B chains are further degraded to form products from cleavage at the A18-19, B14-15, B25-26, and a small amount of A19-20, B10-11, and B24-25 cleavage and the emergence of 2-5-amino acid peptide chains, tyrosine, alanine, histidine, and leucine-tyrosine. We conclude, based on the three-dimensional structure of insulin, that human insulin protease recognizes the alpha-helical regions around leucine-tyrosine bonds and that final degradation steps to small peptides do not require lysosomal involvement.     

A protein caught in a kinetic trap: structures and stabilities of insulin disulfide isomers

Proinsulin contains six cysteines whose specific pairing (A6-A11, A7-B7, and A20-B19) is a defining feature of the insulin fold. Pairing information is contained within A and B domains as demonstrated by studies of insulin chain recombination. Two insulin isomers containing non-native disulfide bridges ([A7-A11,A6-B7,A20-B19] and [A6-A7,A11-B7,A20-B19]), previously prepared by directed chemical synthesis, are metastable and biologically active. Remarkably, the same two isomers are preferentially formed from native insulin or proinsulin following disulfide reassortment in guanidine hydrochloride. The absence of other disulfide isomers suggests that the observed species exhibit greater relative stability and/or kinetic accessibility. The structure of the first isomer ([A7-A11,A6-B7,A20-B19], insulin-swap) has been described [Hua, Q. X., Gozani, S. N., Chance, R. E., Hoffmann, J. A., Frank, B. H., and Weiss, M. A. (1995) Nat. Struct. Biol. 2, 129-138]. Here, we demonstrate that the second isomer (insulin-swap2) is less ordered than the first. Nativelike elements of structure are retained in the B chain, whereas the A chain is largely disordered. Thermodynamic studies of guanidine denaturation demonstrate the instability of the isomers relative to native insulin (DeltaDeltaG(u) > 3 kcal/mol). In contrast, insulin-like growth factor I (IGF-I) and the corresponding isomer IGF-swap, formed as alternative products of a bifurcating folding pathway, exhibit similar cooperative unfolding transitions. The insulin isomers are similar in structure and stability to two-disulfide analogues whose partial folds provide models of oxidative folding intermediates. Each exhibits a nativelike B chain and less-ordered A chain. This general asymmetry is consistent with a hierarchical disulfide pathway in which nascent structure in the B chain provides a template for folding of the A chain. Structures of metastable disulfide isomers provide probes of the topography of an energy landscape.     

Role of disulfide bonds in the structure and activity of human insulin

Insulin contains two inter-chain disulfide bonds between the A and B chains (A7-B7 and A20-B19), and one intra-chain linkage in the A chain (A6-A11). To investigate the role of each disulfide bond in the structure, function and stability of the molecule, three des mutants of human insulin, each lacking one of the three disulfide bonds, were prepared by enzymatic conversion of refolded mini-proinsulins. Structural and biological studies of the three des mutants revealed that all three disulfide bonds are essential for the receptor binding activity of insulin, whereas the different disulfide bonds make different contributions to the overall structure of insulin. Deletion of the A20-B19 disulfide bond had the most substantial influence on the structure as indicated by loss of ordered secondary structure, increased susceptibility to proteolysis, and markedly reduced compactness. Deletion of the A6-A11 disulfide bond caused the least perturbation to the structure. In addition, different refolding efficiencies between the three des mutants suggest that the disulfide bonds are formed sequentially in the order A20-B19, A7-B7 and A6-A11 in the folding pathway of proinsulin.     

Structure-specific effects of protein topology on cross-beta assembly: studies of insulin fibrillation

Systemic amyloidoses, an important class of protein misfolding diseases, are often due to fibrillation of disulfide-cross-linked globular proteins otherwise unrelated in sequence or structure. Although cross-beta assembly is regarded as a universal property of polypeptides, it is not understood how such amyloids accommodate diverse disulfide connectivities. Does amyloidogenicity depend on protein topology? A model is provided by insulin, a two-chain protein containing three disulfide bridges. The importance of chain topology is demonstrated by mini-proinsulin (MP), a single-chain analogue in which the C-terminus of the B chain (residue B30) is tethered to the N-terminus of the A chain (A1). The B30-A1 tether impedes the fiber-specific alpha --> beta transition, leading to slow formation of a structurally nonuniform amorphous precipitate. Conversely, fibrillation is robust to interchange of disulfide bridges. Whereas native insulin exhibits pairings [A6-A11, A7-B7, and A20-B19], metastable isomers with alternative pairings [A6-B7, A7-A11, A20-B19] or [A6-A7, A11-B7, A20-B1] readily undergo fibrillation with essentially identical alpha --> beta transitions. Respective pairing schemes are in each case retained. Isomeric fibrils and the amorphous MP precipitate are each able to seed the fibrillation of wild-type insulin, suggesting a structural correspondence between respective nuclei or modes of assembly. Together, our results demonstrate that effects of polypeptide topology on amyloidogenicity depend on structural context. Although the native structures and stabilities of single-chain insulin analogues are similar to those of wild-type insulin, the interchain tether constrains the extent of conformational distortion at elevated temperature, retards initial non-native aggregation, and is apparently incompatible with the mature structure of an insulin protofilament. We speculate that the general danger of fibrillation has imposed a constraint in protein evolution, selecting for topologies unfavorable to amyloid formation.     

Replacement of the interchain disulfide bridge-forming amino acids A7 and B7 by glutamate impairs the structure and activity of insulin

Insulin contains three disulfide bonds, one intrachain bond, A6-A11, and two interchain bonds, A7-B7 and A20-B19. Site-directed mutagenesis results (the two cysteine residues of disulfide A7-B7 were replaced by serine) showed that disulfide A7-B7 is crucial to both the structure and activity of insulin. However, chemical modification results showed that the insulin analogs still retained relatively high biological activity when A7Cys and B7Cys were modified by chemical groups with a negative charge. Did the negative charge of the modification groups restore the loss of activity and/or the disturbance of structure of these insulin analogs caused by deletion of disulfide A7-B7? To answer this question, an insulin analog with both A7Cys and B7Cys replaced by Glu, which has a long side-chain and a negative charge, was prepared by protein engineering, and its structure and activity were analyzed. Both the structure and activity of the present analog are very similar to that of the mutant with disulfide A7-B7 replaced by Ser, but significantly different from that of wild-type insulin. The present results suggest that removal of disulfide A7-B7 will result in serious loss of biological activity and the native conformation of insulin, even if the disulfide is replaced by residues with a negative charge.     

The folding nucleus of the insulin superfamily: a flexible peptide model foreshadows the native state

Oxidative folding of insulin-like growth factor I (IGF-I) and single-chain insulin analogs proceeds via one- and two-disulfide intermediates. A predominant one-disulfide intermediate in each case contains the canonical A20-B19 disulfide bridge (cystines 18-61 in IGF-I and 19-85 in human proinsulin). Here, we describe a disulfide-linked peptide model of this on-pathway intermediate. One peptide fragment (19 amino acids) spans IGF-I residues 7-25 (canonical positions B8-B26 in the insulin superfamily); the other (18 amino acids) spans IGF-I residues 53-70 (positions A12-A21 and D1-D8). Containing only half of the IGF-I sequence, the disulfide-linked polypeptide (designated IGF-p) is not well ordered. Nascent helical elements corresponding to native alpha-helices are nonetheless observed at 4 degrees C. Furthermore, (13)C-edited nuclear Overhauser effects establish transient formation of a native-like partial core; no non-native nuclear Overhauser effects are observed. Together, these observations suggest that early events in the folding of insulin-related polypeptides are nucleated by a native-like molten subdomain containing Cys(A20) and Cys(B19). We propose that nascent interactions within this subdomain orient the A20 and B19 thiolates for disulfide bond formation and stabilize the one-disulfide intermediate once formed. Substitutions in the corresponding region of insulin are associated with inefficient chain combination and impaired biosynthetic expression. The intrinsic conformational propensities of a flexible disulfide-linked peptide thus define a folding nucleus, foreshadowing the structure of the native state.     

Shortened insulin analogues: marked changes in biological activity resulting from replacement of TyrB26 and N-methylation of peptide bonds in the C-terminus of the B-chain

The role of three highly conserved insulin residues PheB24, PheB25, and TyrB26 was studied to better understand the subtleties of the structure-function relationship between insulin and its receptor. Ten shortened insulin analogues with modifications in the beta-strand of the B-chain were synthesized by trypsin-catalyzed coupling of des-octapeptide (B23-B30)-insulin with synthetic peptides. Insulin analogues with a single amino acid substitution in the position B26 and/or single N-methylation of the peptide bond at various positions were all shortened in the C-terminus of the B-chain by four amino acids. The effect of modifications was followed by two types of in vitro assays, i.e., by the binding to the receptor of rat adipose plasma membranes and by the stimulation of the glucose transport into the isolated rat adipocytes. From our results, we can deduce several conclusions: (i) the replacement of tyrosine in the position B26 by phenylalanine has no significant effect on the binding affinity and the stimulation of the glucose transport of shortened analogues, whereas the replacement of TyrB26 by histidine affects the potency highly positively; [HisB26]-des-tetrapeptide (B27-B30)-insulin-B26-amide and [NMeHisB26]-des-tetrapeptide (B27-B30)-insulin-B26-amide show binding affinity 529 and 5250%, respectively, of that of human insulin; (ii) N-methylation of the B24-B25 peptide bond exhibits a disruptive effect on the potency of analogues in both in vitro studies regardless the presence of amino acid in the position B26; (iii) N-methylation of the B23-B24 peptide bond markedly reduces the binding affinity and the glucose transport of respective analogue [NMePheB24]-des-tetrapeptide (B27-B30)-insulin-B26-amide.     

Antigen processing and the human T cell receptor repertoire for insulin

Three human T cell lines specific for the A loop of beef insulin were studied to determine the requirements for Ag processing. The data show that the conformation of the A loop of insulin is required for recognition and that the B chain of insulin per se is not necessary for this response. Processing of native insulin was required for responses of all three T cell lines; however, each displayed a different pattern of sensitivity to inhibition of processing and aldehyde fixation of APC. A peptide comprised of two disulfide-linked A chains was partially stimulatory when presented by fixed APC whereas A chain monomers and disulfide-linked A and B chain peptides were not. The response to native insulin, peptides, and A chain dimers was sensitive to chloroquine suggesting that none of these moieties is the terminal processed peptide recognized by insulin immune T cells. The unique patterns of fine specificity, processing requirements, and recognition of aldehyde-fixed antigen-MHC for each T cell line suggest the hypothesis that Ag processing leads to heterogeneity of the T cell repertoire for a single epitope of insulin.     

Flexibility and bioactivity of insulin: an NMR investigation of the solution structure and folding of an unusually flexible human insulin mutant with increased biological activity

The structure and folding of a novel human insulin mutant, [Thr(B27) --> Pro, Pro(B28) --> Thr]insulin (PT insulin), in aqueous solution and in mixtures of water and 2,2,2-trifluoroethanol (TFE) have been studied by NMR spectroscopy. It was found that PT insulin has a highly flexible structure in pure water and is present in at least two different conformations, although with an overall tertiary structure similar to that of native insulin. Furthermore, the native helical structures are poorly defined. Surprisingly, the mutant has a biological activity about 50% higher than native insulin. In contrast, in TFE/water solution the mutant reveals a propensity of forming a well-defined structure at the secondary structure level, similar to monomeric native insulin. Thus, as shown by a detailed determination of the structure from 208 distance restraints and 52 torsion angle restraints by distance geometry, simulated annealing, and restrained energy minimization, the native insulin helices (A2-A7, A13-A19, and B10-B19) as well as the beta-turn (B20-B23) are formed in 35% TFE. However, the amount of tertiary structure is decreased significantly in TFE/water solution. The obtained results suggest that only an overall tertiary fold, as observed for PT insulin in pure water, is necessary for expressing the biological activity of insulin, as long as the molecule is flexible and retains the propensity to form the secondary structure required for its receptor binding. In contrast, a compact secondary structure, as found for native insulin in solution, is unnecessary for the biological activity. A model for the receptor binding of insulin is suggested that relates the increased bioactivity to the enhanced flexibility of the mutant.     

Dissecting the role of disulfide bonds on the amyloid formation of insulin

Disulfide bonds play a critical role in the stability and folding of proteins. Here, we used insulin as a model system, to investigate the role of its individual disulfide bond during the amyloid formation of insulin. Tris(2-carboxyethyl)phosphine (TCEP) was applied to reduce two of the three disulfide bonds in porcine insulin and the reduced disulfide bonds were then alkylated by iodoacetamide. Three disulfide bond-modified insulin analogs, INS-2 (lack of A6-A11), INS-3 (lack of A7-B7) and INS-6 (lack of both A6-A11 and A7-B7), were obtained. Far-UV circular dichroism (CD) spectroscopy results indicated that the secondary structure of INS-2 was the closest to insulin under neutral conditions, followed by INS-3 and INS-6, whereas in an acidic solution all analogs were essentially unfolded. To test how these modifications affect the amyloidogenicity of insulin, thioflavin-T (ThT) fluorescence and transmission electronic microscopy (TEM) were performed. Our results showed that all analogs were more prone to aggregation than insulin, with the order of aggregation rates being INS-6>INS-3>INS-2. Cross-linking of unmodified proteins (PICUP) assay results showed that analogs without A6-A11 (INS-2 and INS-6) have a higher potential for oligomerization than insulin and INS-3, which is accompanied with a higher cytotoxicity as the hemolytic assays of human erythrocytes suggested. The results indicated that breakage of A7-B7 induced more unfolding of the insulin structure and a higher amyloidogenicity than breakage of A6-A11, but breakage of A6-A11 caused a significant cytotoxicity increase and a higher potency to form high order toxic oligomers.     

A peripheral mechanism preserves self-tolerance to a secreted protein in transgenic mice

We have examined mechanisms of tolerance to circulating self-proteins in mice that are transgenic for human insulin. Normal, nontransgenic mice develop serum antibody responses when injected with human insulin in CFA; syngeneic transgenic mice do not. B cell responsiveness was assessed by immunizing with human insulin coupled to a T-independent Ag, Brucella abortus. No differences were found in the numbers of insulin-specific splenic plaque-forming cells between transgenic and nontransgenic mice suggesting that insulin-specific B cells are not tolerant in transgenic mice. Similarly, APC from transgenic and nontransgenic mice display no differences in their ability to process and present human insulin to human insulin-specific T cells in vitro. However, marked differences were detected between transgenic and nontransgenic T cells. Lymph node T cells from transgenic mice primed with human insulin provided no detectable helper activity for secondary antibody responses to human insulin whereas, lymph node T cells from nontransgenic mice did. Nevertheless, lymph node T cells from transgenic mice developed significant proliferative responses to human insulin. Lymph node T cells obtained from transgenic and nontransgenic mice were fused to BW5147 and human insulin-specific T cell hybridomas were generated. The fact that human insulin-specific T cell hybridomas were obtained from the transgenic mice suggests that these T cells were not clonally deleted. In addition, APC from transgenic mice did not stimulate human insulin-specific hybridomas from normal mice in the absence of exogenous insulin. We suggest that T cells specific for human insulin are not deleted in the thymus of transgenic mice because APC in the thymus do not bear the requisite levels of endogenous human insulin/Ia complexes. Therefore, we conclude that tolerance in the transgenic mice is preserved by peripheral mechanisms.     

Peptide models of four possible insulin folding intermediates with two disulfides

The single-chain insulin (PIP) can spontaneously fold into native structure through preferred kinetic intermediates. During refolding, pairing of the first disulfide A20-B19 is highly specific, whereas pairing of the second disulfide is likely random because two two-disulfide intermediates have been trapped. To get more details of pairing property of the second disulfide, four model peptides of possible folding intermediates with two disulfides were prepared by protein engineering, and their properties were analyzed. The four model peptides were named [A20-B19, A7-B7]PIP, [A20-B19, A6-B7]PIP, [A20-B19, A6-A11]PIP, and [A20-B19, A7-A11]PIP according to their remaining disulfides. The four model peptides all adopt partially folded structure with moderate conformational differences. In redox buffer, the disulfides of the model peptides are more easily reduced than those of the wild-type PIP. During in vitro refolding, the reduced model peptides share similar relative folding rates but different folding yields: The refolding efficiency of the reduced [A20-B19, A7-A11]PIP is about threefold lower than that of the other three peptides. The present results indicate that the folding intermediates corresponding to the present model peptides all adopt partially folded conformation, and can be formed during PIP refolding, but the chance of forming the intermediate with disulfide [A20-B19, A7-A11] is much lower than that of forming the other three intermediates.     

1H n.m.r. studies of insulin. Assignment of resonances and properties of tyrosine residues.

The assignment of the aromatic 1H n.m.r. resonances of the four tyrosine residues of bovine 2-zinc insulin is reported, based on double resonance techniques, use of Hahn spin echo pulse sequences and examination of specific derivatives nitrated at tyrosines A14 and A19 as well as des-(B26-B30)-insulin. Titration curves of the four tyrosine residues show that residues A14 and B16 have normal pK' values of 10.3-10.6 in solution, consistent with their accessibility to solvent in monomer and dimer in the crystal. Tyrosine residues A19 and B26 have pK' values of 11.4 and exhibit other features in their titration curves that are consistent with limited accessibility to solvent and a nonpolar environment. The meta protons of residues B16 and B26 both observe the titration of a nearby tyrosine residue, probably A19. Interpretation of the n.m.r. data obtained in solution is consistent with the crystallographic data for the monomer and dimer obtained on insulin crystals [Blundell, Dodson, Hodgkin & Mercola (1972) Adv. Protein Chem. 26, 279-402].     

The identification of a major product of the degradation of insulin by ''insulin proteinase'' (EC 3.4.22.11).

We have studied a major product in the degradation of insulin by insulin proteinase (EC 3.4.22.11). Semisynthetic [[3H]PheB1]insulin and [[3H]GlyA1]insulin were used in the experiments. The structure of the fragment was deduced by observing the chromatographic and electrophoretic migration of the label both before and after further digestion of the fragment with proteinases of known specificity, with and without additional treatment by performic acid. Ambiguities were resolved by studying the behaviour of authentic fragments of known structure, isolated and characterized after digestion of intact insulin by proteinases of known specificity. We conclude that a major product in the degradation of insulin by insulin proteinase consists of a truncated section of the A chain, joined by the disulphide bridge B7-A7 to a truncated section of the B chain. The A-chain fragment consists most probably of residues A1-A13, and the B-chain fragment consists most probably of residues B1-B9. The similarity between this fragment and that found by other workers when insulin is degraded by intact hepatocytes is significant in the light of proposals that insulin proteinase is a possible participant in the physiological degradation of insulin by target cells.     

Nonlocal structural perturbations in a mutant human insulin: sequential resonance assignment and 13C-isotope-aided 2D-NMR studies of [PheB24-->Gly]insulin with implications for receptor recognition.

Insulin's mechanism of receptor binding is not well understood despite extensive study by mutagenesis and X-ray crystallography. Of particular interest are "anomalous" analogues whose bioactivities are not readily rationalized by crystal structures. Here the structure and dynamics of one such analogue (GlyB24-insulin) are investigated by circular dichroism (CD) and isotope-aided 2D-NMR spectroscopy. The mutant insulin retains near-native receptor-binding affinity despite a nonconservative substitution (PheB24-->Gly) in the receptor-binding surface. Relative to native insulin, GlyB24-insulin exhibits reduced dimerization; the monomer (the active species) exhibits partial loss of ordered structure, as indicated by CD studies and motional narrowing of selected 1H-NMR resonance. 2D-NMR studies demonstrate that the B-chain beta-turn (residues B20-23) and beta-strand (residues B24-B28) are destabilized; essentially native alpha-helical secondary structure (residues A3-A8, A13-A18, and B9-B19) is otherwise maintained. 13C-Isotope-edited NOESY studies demonstrate that long-range contacts observed between the B-chain beta-strand and the alpha-helical core in native insulin are absent in the mutant. Implications for the mechanism of insulin's interaction with its receptor are discussed.     

Inactive conformation of an insulin despite its wild-type sequence.

The peptide group between residues B24 and B25 of insulin was replaced by an ester bond. This modification only in the backbone was meant to eliminate a structurally important H-bond between the amide proton of B25 and the carbonyl oxygen of A19, and consequently to enhance detachment of the C-terminal B-chain from the body of the molecule, exposing the underlying A-chain. According to a model derived from the effects of side-chain substitutions, main-chain shortening, and crosslinking, this conformational change is prerequisite for receptor binding. Contrary to the expectation that increased flexibility would increase receptor binding and activity, depsi-insulin ([B24-B25 CO-O]insulin) has turned out be only 3-4% potent. In search of an explanation for this observation, the solution structure of depsi-insulin was determined by two-dimensional 1H-NMR spectroscopy. It was found that the loss of the B25-A19 H-bond does not entail detachment of the C-terminal B-chain. On the contrary, it is overcompensated by a gain in hydrophobic interaction achieved by insertion of the Phe B25 side chain into the molecule's core. This is possible because of increased rotational freedom in the backbone owing to the ester bond. Distortion of the B20-B23 turn and an altered direction of the distal B-chain are consequences that also affect self-association. The exceptional position of the B25 side chain is thus the key feature of the depsi-insulin structure. Being buried in the interior, it is not available for guiding the interaction with the receptor, a crucial role attributed to it by the model. This seems to be the main reason why the structure of depsi-insulin represents an inactive conformation.     

Specificity of acid proteinase A from Aspergillus niger var. macrosporus towards B-chain of performic acid oxidized bovine insulin.

1. A comparative study on the mode of action of two highly purified acid endopeptidases (EC 3.4.-) from Aspergillus niger var. macrosporus, acid proteinase A and B, on the B-chain of performic acid oxidized insulin was performed, putting emphasis on the quantitative analysis of the effects of enzyme A. Acid proteinase A behaved very specifically towards the substrate and hydrolyzed four peptide bonds exclusively: three major sites, where hydrolysis proceeded rapidly and almost completely, Asn3-Gln4, Glu13-Ala14, and Tyr26-Thr27; and a minor one, Gly20-Glu21, at which hydrolysis was much slower. 2. The effects of four protease inhibitors, pepstatin, diazoacetyl-D,L-norleucine methyl ester/Cu(II), di-isopropyl phosphorofluoridate, and 1,2-epoxy-3-(p-nitrophenozy) propane on acid proteinases A and B were studied. Acid proteinase A preparations, treated with the former two inhibitors, were used to establish that the major sites of attack were really affected by enzyme A and not by contaminating proteinase B.