Immobilization of the thrombin inhibitor r-hirudin conserving its biological activity.

Surface immobilization of the thrombin inhibitor r-hirudin was carried out on two different polymers. Linkage to poly(urethane-graft-acrylic acid) (PAC/PU) was done via carboxylic acid groups, using a water soluble carbodimide, while the immobilization on a modified poly[(ethene-co-vinyl acetate)-graft-vinyl chloride] (PVC/EVA) was achieved via the alcohol groups of the polymer using HDI as spacer. Direct immobilization of r-hirudin leaded to a remarkable loss of thrombin activity. As proved by means of protein chemical analysis, loss of activity was due to a selective coupling via the N-terminal amino group of r-hirudin, which is essential for its thrombin activity. Based on these results we developed an immobilization method via an epsilon-amino group of r-hirudin preserving full biological activity of the r-hirudin coated surface.

Cross-linking by 1-ethyl-3- (3-dimethylaminopropyl)-carbodiimide (EDC) of a collagen/elastin membrane meant to be used as a dermal substitute: effects on physical, biochemical and biological features in vitro.

Next to in vitro-cultured autogeneic keratinocytes for the restoration of epidermis, a suitable dermal matrix is a mandatory component of an artificial skin substitute for the permanent covering of full thickness skin defects. In our model a xenogeneic membrane, consisting of processed native collagen and elastin of porcine origin is meant to serve as a template for the formation of a neo-dermis. In order to improve the resistance of this matrix against enzymatical degradation, we cross-linked it by using the carbodiimide 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide (EDC) together with N-hydroxysuccinimide. Chemical cross-linking by these agents at two different degrees (shrinkage temperatures 63 degrees C and 81 degrees C) had no relevant effect on mechanical features or water-uptake capacity. The time needed for enzymatic digestion was increased by cross-linking. Concerning growth and spreading of fibroblasts and keratinocytes on and within the structure of this membrane, we did not observe a difference between cross-linked and non-cross-linked material (shrinkage temperature 48 degrees C). We therefore expect that cross-linking by EDC is an effective means to control the degradation of the collagen/elastin membranes in vivo without a significant influence on their biocompatibility.

The solution structure of a superpotent B-chain-shortened single-replacement insulin analogue.

This paper reports on an insulin analogue with 12.5-fold receptor affinity, the highest increase observed for a single replacement, and on its solution structure, determined by NMR spectroscopy. The analogue is [D-AlaB26]des-(B27-B30)-tetrapeptide-insulin-B26-amide. C-terminal truncation of the B-chain by four (or five) residues is known not to affect the functional properties of insulin, provided the new carboxylate charge is neutralized. As opposed to the dramatic increase in receptor affinity caused by the substitution of D-Ala for the wild-type residue TyrB26 in the truncated molecule, this very substitution reduces it to only 18% of that of the wild-type hormone when the B-chain is present in full length. The insulin molecule in solution is visualized as an ensemble of conformers interrelated by a dynamic equilibrium. The question is whether the "active" conformation of the hormone, sought after in innumerable structure/function studies, is or is not included in the accessible conformational space, so that it could be adopted also in the absence of the receptor. If there were any chance for the active conformation, or at least a predisposed state to be populated to a detectable extent, this chance should be best in the case of a superpotent analogue. This was the motivation for the determination of the three-dimensional structure of [D-AlaB26]des-(B27-B30)-tetrapeptide-insulin-B26-amide. However, neither the NMR data nor CD spectroscopic comparison of a number of related analogues provided a clue concerning structural features predisposing insulin to high receptor affinity. After the present study it seems more likely than before that insulin will adopt its active conformation only when exposed to the force field of the receptor surface.

Analysis of protein self-association at constant concentration by fluorescence-energy transfer.

Fluorescence-resonance-energy transfer from subunits labelled with a fluorescence donor group to subunits labelled with a fluorescence acceptor group can be used for quantitative analysis of protein self-association. The present approach evaluates fluorescence measurements on mixtures of equimolar solutions of donor-labelled and acceptor-labelled protein composed by systematic variation of the volume ratio. Its attractive feature is that it allows the determination of equilibrium constants at fixed total concentration. Problems encountered by most other methods, which require the equilibria to be followed to high dilution, are avoided. Conditions to be fulfilled are that a reactive site is available on the protein for specific introduction of the labels and that labelling neither affects the conformation nor interferes with the intermolecular interactions. It is desirable that the Forster distance of the donor/acceptor pair complies with its separation. While dimerisation constants can be determined exclusively by fluorescence measurements, the analysis of more complex cases of self-association depends on additional independent information. This communication reports on an application of the approach to the association/dissociation equilibrium between insulin monomers and dimers. Labelling of insulin at the epsilon-amino group of LysB29 does not disturb the conformation nor does it affect dimerisation. 2-Aminobenzoyl and 3-nitrotyrosyl residues served as the donor/acceptor pairs. Because they are less bulky than most other fluorescence labels and are of balanced polarity they do not alter the chemical nature of the protein. Their Forster distance of 29 A matches their 32-A separation in the insulin dimer. Energy transfer was measured as a function of the molar fractions of donor-insulin and acceptor-insulin at constant total concentration. Evaluation of this dependence resulted in a dimerisation constant, K12, of 0.72x10(5) M(-1). Its agreement with values obtained with other methods demonstrates that the present approach is a reliable alternative.

Hair sulfur amino acid analysis.

This overview emphasizes present aspects of sulfur-containing amino acids in hair. A selection of analytical procedures to determine cystine, cysteine, S-sulfocysteine, cystine oxide, cysteic acid, lanthionine and lysinoalanine are presented. The methods relate to intact hair or partial and total hydrolysates and comprise chromatography, titration, colorimetry, polarography and spectroscopy. For the analysis of cysteine, cystine and cystine oxides, polarography and spectroscopy are the methods of choice. Cysteic acid, lanthionine and lysinoalanine are analysed by means of ion-exchange chromatography (Spackman et al., 1958) after total hydrolysis.

The role of the C-terminus of the insulin B-chain in modulating structural and functional properties of the hormone.

Within the scope of structure-function studies on the proteohormone insulin, the role of the C-terminal segment B26-B30 for self-association and receptor interaction was analyzed. Insulin derivatives with modifications in the region B26-B30 were synthesized by trypsin-catalyzed coupling reactions of des-(B23-B30)-insulin with synthetic peptides. The peptides were obtained by Fmoc solid-phase peptide synthesis. Insulins with multiple amino acid-->glycine substitutions were examined to distinguish between the influence of the side chains and the influence of the main chain in positions B27-B30 on the self-association of the hormone. The analogues [GlyB27,B28,B29,B30]insulin and [GlyB27,B28,B30]insulin exhibit relative receptor affinities of 80% and self-associate. The successive extension of [AlaB26]des-(B27-B30)-insulin-B26-amide (relative receptor binding 273%) with amino acids corresponding to the native sequence B27-B30 showed the influence of the length of the B-chain on receptor affinity: the extension by B27-threonine amide reduces receptor binding to 71%, all further prolongations have only small effects on the binding. The effect of the B28-side chain on main-chain conformation, self-association and receptor binding was examined with [XB28]des-(B29-B30)-insulin-B28-amides (X = Phe, Gly, D-Pro). While the glycine and D-proline analogues (relative binding 104 and 143%, respectively) retain the self-association properties typical of insulin, [PheB28]des-(B29-B30)-insulin-B28-amide (relative binding 50%) shows diminished self-association. The backbone-modified insulin derivative [SarB26]des-(B27-B30)-insulin-B26-amide (sarcosine = N-methylglycine) exhibits an unexpectedly high receptor affinity of 1100% which demonstrates that the B26-amide hydrogen of the native hormone is not important for receptor binding.

Structure-function relationships of des-(B26-B30)-insulin.

In order to study the role of the amino acid in position B25 and its environment in shortened insulins, a series of analogues was prepared with the following modifications: 1, Stepwise shortening of the B-chain including replacements of TyrB26 and ThrB27 by glycine; 2, substitutions at the carboxamide nitrogen of des-(B26-B30)-insulin-B25-amide by apolar, polar or charged residues of various chain lengths; 3, replacement of PheB25 by asparagine-amide, phenylalaninol or a series of alkyl and aralkyl residues. Trypsin-catalyzed semisyntheses were performed with Boc-protected or unprotected des-octapeptide-(B23-B30)-insulin and synthetic peptides. Relative receptor binding and in vitro bioactivity of [AsnB25]-des-(B26-B30)-insulin-B25-amide was 227 and 292% (on insulin), other activities ranged between 1 and ca. 200%. We make the following conclusions. An L-amino acid is essential in position B25. The B25-carbonyl and NH groups favour high binding and "superpotency", but are not indispensible for receptor contacts. For high affinity receptor interaction, the planarity at the C gamma-atom and the distance of B25-side-chain branching in position B25 are important, but an aromatic ring is not necessary.

Structure and rotational dynamics of fluorescently labeled insulin in aqueous solution and at the amphiphile-water interface of reversed micelles.

Insulin is a proteohormone with amphipathic three-dimensional structure and the ligand of a receptor, which itself spans the plasma membrane of glucose-metabolizing cells. In this study, the possible impact of amphiphiles on structural and dynamic properties of the hormone was investigated in reversed micelles mimicking the amphipathic nature of biological membranes. To make insulin susceptible to fluorescence measurements, two derivatives labeled with 2-aminobenzoic acid (Abz), N epsilon B29-Abz-insulin and [AbzB1]insulin, were prepared. First, the Abz-labeled insulins were shown by CD spectroscopy to exhibit conformational properties and self-association as well as the T-->R transition similar to the native hormone. By means of time-resolved fluorescence measurements, not only metal-ion induced hexamerization was observable in aqueous solution: The T-->R allosteric transition of the hexamer was shown to be accompanied by a diminution of its hydrodynamic radius. Second, structure and rotational dynamics of the labeled insulins were investigated in reversed micelles. In sodium bis(2-ethylhexyl)sulfosuccinate (AOT) reversed micelles, the main-chain conformation is similar to that in aqueous solution according to CD spectroscopy in the far-UV, whereas the weak circular dichroism in the near-UV is indicative of reduced aromatic contacts as well as of the absence of quaternary structure, and the CD spectra show the same shape as found for proteins in an intermediate state of folding referred to as the "molten globule". Fluorescence anisotropy decay measurements of N epsilon B29-Abz-insulin in reversed micelles of AOT, cetyltrimethylammonium bromide, and alpha-L-1,2-dioctanoylphosphatidylcholine showed that the internal mobility of the solubilizate is reduced compared to that in aqueous solution and that the rotational mobility of the labeled insulin decreases with decreasing micellar size. With respect to the immobilization, insulin interacts in a stronger way with the anionic than with the cationic or zwitterionic amphiphile; an integration into the amphiphile monolayer, however, could be ruled out in all cases. In conclusion, the results reveal an evident influence of amphiphiles on the structure and rotational dynamics of insulin. Further investigations should be focused on this finding also with regard to the possible importance of lipid-insulin interactions in vivo.

Proteolyses of a fluorogenic insulin derivative and native insulin in reversed micelles monitored by fluorescence emission, reversed-phase high-performance liquid chromatography, and capillary zone electrophoresis.

The preparation and substrate properties of the fluorogenic insulin derivative N alpha A1-aminobenzoyl-N epilson B29-Tyr(NO2)- insulin are described. This semisynthetic protein intramolecularly quenched by long-range resonance energy transfer between the donor/acceptor pair 2-aminobenzoic acid and 3-nitrotyrosine was used to prove the activity of serine proteases toward substrates of high molecular weight after incorporation in reversed micelles. The proteases investigated, trypsin and alpha-chymotrypsin, were shown to be hydrolytically active in reversed micellar solvent systems stabilized by cetyltrimethylammonium bromide or sodium-1,2-bis(2-ethylhexylcarbonyl)-1- ethane sulfonate. Apart from fluorometric enzyme assays, methods for monitoring proteolyses in reversed micelles were elaborated using either reversed-phase high-performance liquid chromatography or capillary zone electrophoresis. Enzymatic digestions of native insulin by the specific protease trypsin and the less specific protease alpha-chymotrypsin were performed. In contrast to aqueous solution, high but still variable specificity of alpha-chymotrypsin which was dependent on the micellar environment was observed. The results promise further insight into the influence of interfacial environments on enzyme action and a novel approach to enzyme-mediated protein modifications by the use of microstructured solvent systems.

Semisynthetic insulin analogues modified in positions B24, B25 and B29.

New semisynthetic analogues of human insulin, modified in the C-terminal region of the B-chain, were prepared to refine our understanding of the importance of particular amino acid residues in the expression of hormone biological properties. The following insulin analogues were synthesized by trypsin-catalyzed peptide-bond formation between the C-terminal arginineB22 of des-octapeptide(B23-B30)-insulin and synthetic octapeptides with the epsilon-amino group of lysineB29 protected by a phenylacetyl group: [L-Lys(Pac)B29]insulin, [D-PheB24,B25,L-Lys(Pac)B29]insulin and [D-Phe(p-Et)B24, L-Lys(Pac)B29]insulin. Enzymatic deprotection using immobilized penicillin amidohydrolase yielded: human insulin, [D-PheB24,B25]insulin and [DPhe(p-Et)B24]-insulin. Biological in vitro potencies (specific binding to cultured human lymphocytes IM-9 and lipogenic potency in isolated rat adipocytes) of the semisynthetic analogues were estimated, ranging from 0.2 to 100% relative to porcine insulin.

An insulin with the native sequence but virtually no activity.

The B24-B25 peptide bond of insulin was replaced by an ester bond. To our knowledge this is the first replacement of a main chain atom reported for the hormone. It is meant to eliminate a structurally important H-bond between the imino group of B25 and the carbonyl oxygen of A19, and consequently to enhance detachment of the C-terminal B chain from the underlying A chain. On the basis of independent experimental evidence this very conformational change is believed to be a prerequisite for receptor binding. It was thus anticipated that increased flexibility would increase receptor binding and activity. Intriguingly, porcine [B24-B25 CO-O]insulin (depsi-insulin) and likewise [B24-B25 CO-O]des-(B26-B30)insulin-B25-amide (depsi-DPI-amide) were found to be only 3-4% potent.

Semisynthetic des-(B27-B30)-insulins with modified B26-tyrosine.

Semisynthetic des-(B27-B30)-insulins containing modified B26-tyrosine residues were prepared to refine the understanding of the importance of position B26 with regard to biological and structural properties of the hormone. The following shortened insulin analogues were synthesized by trypsin-catalysed peptide-bond formation between the C-terminal amino acid ArgB22 of des-(B23-B30)-insulin and synthetic tetrapeptides as amino components: des-(B27-B30)-insulin, des-(B27-B30)-insulin-B26-methyl ester, -B26-carboxamide with varying C-terminal hydrophobicity of the B-chain, and [Tyr(NH2)B26]-, [Tyr(NO2)B26]-, [Tyr(I2)B26]-, [D-TyrB26]des-(B27-B30)-insulin-B26-carboxamide containing non-proteinogenic amino acids in position B26. Starting from insulin and an excess of synthetic Gly-Phe-Phe-Tyr-OMe as nucleophile, des-(B27-B30)-insulin-B26-methyl ester--the formal transpeptidation product at ArgB22--was formed in one step. Biological in vitro properties (binding to cultured human IM-9 lymphocytes, relative lipogenic potency in isolated rat adipocytes) of all semisynthetic analogues are reported, ranging from slightly decreased to two-fold receptor affinity and nearly three-fold biopotency relative to insulin. If the C-terminal tetrapeptide B27-B30 is removed, full relative insulin activity is still preserved, while the shortening results in the loss of ability to associate in solution. Only after carboxamidation or methyl esterification of TyrB26 the self-association typical of native insulin can be observed, and the CD-spectral effects in the near UV spectrum related to association and hexamerization of the native hormone are qualitatively reestablished. The results of this investigation underline the importance of position B26 to the modulation of hormonal properties and solution structure of the shortened insulins.

Presentation of insulin and insulin A chain peptides to mouse T cells: involvement of cysteine residues.

The requirements for insulin presentation and recognition by A alpha b A beta b- and A alpha b A beta k-restricted mouse T cells were studied using a variety of derivatives of the insulin A chain. It was found that A chain peptides with irreversibly blocked Cys residues are non-stimulatory for the T cells. This suggests that at least one of the Cys residues is essential for recognition. On the other hand, all A chain peptides containing Cys residues modified in a way reversible by reaction with thiols are stimulatory yet differ in antigenic potency. All these A chain derivatives including a 14 amino acid fragment require uptake by antigen presenting cells (APC) for efficient presentation. Differences in stimulatory potency between the A chain peptides derived from the same insulin appear to be mainly due to the efficiency of uptake and/or processing by APC. Based on these findings we propose that processing in the case of insulin and its A chain derivatives involves the reductive deblocking of Cys residues or the rearrangement of disulfide bonds apart from a possible proteolytic cleavage. The same may apply to other proteins if Cys residues in the presented peptides are important for the interaction with Ia or the T cell receptor.

Enzyme-assisted semisynthesis of shortened B26-modified insulins.

The role of the invariant residue B26-tyrosine in determining the structural and biological properties of insulin has been extensively investigated by the use of semisynthetic des-(B27-B30)-insulins with modifications of position B26. Apart from the conventional trypsin-catalyzed peptide bond formation between the C-terminal amino acid ArgB22 of des-(B23-B30)-insulin and synthetic tetrapeptides we elaborated a new approach using des-(B26-B30)-insulin as substrate in alpha-chymotrypsin-mediated syntheses. Results obtained from bioassays and CD-spectroscopy underline the importance of position B26 to the association of the native molecule and to the modulation of structural and hormonal properties of shortened insulins.

Use of Z-amino acid-glyceryl esters in protease catalyzed peptide synthesis.

The alpha-glyceryl esters of Z-Gly, Z-Phe and Z-Tyr were synthesized and their use for protease catalyzed peptide synthesis was studied. Three enzymes isolated from crude papain were compared in their catalytic potency. Syntheses with alpha-chymotrypsin were performed in a biphasic system.

Studies on the total synthesis of an A7,B7-dicarbainsulin. III. Assembly of segments and generation of biological activity.

As a further contribution to the synthesis of an insulin analogue with a stable A7-B7 interchain bond, the synthesis of A(8-21) by solution methods, and of B(9-25) as well as [7-(2,7-diaminosuberic acid)]B(1-8) by solid phase methods is described. In the latter compound, the amino group of the diaminosuberic acid residue was acylated with A(1-6), and the resulting "U-peptide" sequentially elongated with the C-terminal A- and finally B-chain sequences. The conversion of the product into the disulfide moiety gave a mixture which could not be resolved by currently available methods. However, the low biological activity of the crude product indicates that the A7-B7 disulfide bond is not crucially important for the activity of insulin.

Synthesis and properties of [A19-(p-fluorophenylalanine)] insulin.

The synthesis of [Phe(F)A19]insulin (porcine) is described. First the protected [Phe(F)19]A-chain was assembled by segment condensation of [1-12] and [13-21] using the dicyclohexyldiimide/1-hydroxybenzotriazole procedure. [Phe(F)19]A-chain was purified by ion exchange chromatography after removal of all the protecting groups (Boc, But, OBut and S-Trt) and its conversion into the tetra-S-sulfonated derivative. [Phe(F)A19]insulin was prepared by combination with porcine B-chain and purified by gel filtration and ion-exchange chromatography. The in vitro biological activity of this analogue was 60%. CD spectra in the near and far UV are qualitatively very similar to those of insulin.

Negative and positive site-site interactions, and their modulation by pH, insulin analogs, and monoclonal antibodies, are preserved in the purified insulin receptor.

The kinetic properties of the insulin receptor were studied in solution after its purification to homogeneity. Dissociation of 125I-labeled insulin at a 1:50 dilution was not first order; unlabeled insulin at physiological concentrations accelerated the dissociation rate with a maximal effect at approximately 17 nM. At higher concentrations, the unlabeled insulin slowed the dissociation rate. Maximal acceleration was seen at pH 8.0. The ability to accelerate the dissociation rate was diminished with [LeuB24]insulin and suppressed with desoctapeptide, [LeuB25], [LeuB24,B25], desalanine-desasparagine, and desheptapeptide insulins, all of which slowed the dissociation at high concentrations. Monoclonal antibodies to the insulin receptor alpha subunit (MA-5, MA-10, MA-20, and MA-51) all competed for insulin binding to the purified receptor. MA-10 and MA-51 accelerated the dissociation of 125I-labeled insulin, while MA-5 and MA-20 slowed the off rate. Thus, all the aspects of both negatively and positively cooperative site-site interactions previously described in whole cells are present in solubilized purified receptors, demonstrating that these interactions represent intrinsic properties of the receptor molecule, most likely as a result of ligand-induced conformational changes.

Shortened insulin with enhanced in vitro potency.

After it has been shown that removal of residues B26-B30 leaves insulin with full biological activity, provided the new C-terminus is amidated (Fischer et al. (1985) Biol. Chem. Hoppe-Seyler 366, 521-525), it is demonstrated here that it does not even preclude enhancement of potency. 7 analogues of des-(B26-B30)-insulin-B25-amide were prepared by trypsin-mediated semisynthesis, the replacements being D-PheB24; HisB25, D-PheB25, TrpB25, TyrB25; D-PheB24,B25 and D-PheB24, TyrB25. Mere conversion of the configuration of B25-phenylalanine reduces in vitro potency to 0.5%. If B25-phenylalanine is, however, substituted by histidine or tyrosine activity is increased to 310 or 230, respectively. According to the features common to these two side chains, the favourable effect should be due to their ring structure with balanced aromatic and polar or H-bonding properties, respectively. The results indicate that in the complete insulin molecule the C-terminal pentapeptide modulates the subtle role that residues B24 and/or B25 play in receptor binding and activity; its presence may have a positive or negative effect. The drastic differences in activity between the shortened analogues are in no ways reflected in the CD spectra which are very similar, though clearly different from that of native insulin.