Kinetic characterization of carboxypeptidase-Y-catalyzed peptide semisynthesis Prediction of yields

Summary Carboxypeptidase-Y-catalyzed peptide semisynthesis has been characterized at pH 7.5, 25°C from initial rate steady state kinetic and progress reaction studies of hydrolysis and aminolysis of-N-benzoyl-L-tyrosine 4-nitro-anilide using the natural L-amino acids and their amides as nucleophiles. The reaction mechanism previously shown to account for carboxypeptidase-Y-catalyzed aminolysis reactions (Christensen et al., 1992) was found also to account for all of the reactions studied here. It involves in addition to the classical serine proteinase mechanism: i) complex formation between the free enzyme and the nucleophile, an interaction characterized by the competitive inhibition constant,K _i, and ii) reaction of the nucleophile with the acylated enzyme forming a complex of enzyme and aminolysis product, characterized by the aminolysis kinetic parameter,K _N.A competitive inhibitory effect showing binding to the free enzyme is seen mainly with large hydrophobic amino acids and their amides i.e. the same residues as those preferred on either side of the scissile bond in carboxypeptidase-Y substrates. The stoichiometry of the inhibition is 1 : 1 and the actual binding position most likely is that of the leaving group of substrates,S ₁.Aminolysis effects are obtained with a wide range of amino acids and amino acid amides, exceptions are Pro and, probably due to their low solubility, Tyr, Trp, Asp and Glu. TheK _N-values show relatively little dependence on the chemical nature of the side groups, but a marked difference between the amino acid and its amide. The amides interact more strongly. The kinetic parameter,k _c/K_m, of the hydrolysis of the aminolysis products is another important factor in peptide semisynthesis. Thek _c/K_m-values obtained of the amidated aminolysis products are much less than those of the products formed with free amino acids. All in all this leads to rather efficient aminolysis with the L-amino acid amides and poor aminolysis with the L-amino acids.Abbreviations BzTyrNHPhNO₂ -N-benzoyl-L-tyrosinyl 4-nitro-aniline - Xaa L-amino acids - Xaaa L-amino acid amides - Z-Phe Carbobenzoxy-L-phenylalanine - Z-Met Carbobenzoxy-L-methionine - BzTyr -N-benzoyl-L-tyrosine - AlaVal L-alanyl-L-valine - ValAla L-valyl-L-alanine     

Enzyme peptide synthesis and semisynthesis: Kinetic and thermodynamic aspects

The hydrolysis/synthesis equilibrium of the peptide bond is governed by the relative magnitudes of the corresponding Gibbs' energies of hydrolysis to non-ionized products and of their ionization. The positive energy change in peptide hydrolysis to non-ionized products is the thermodynamic basis for the acyl and leaving group specificity of proteinases. With a proteinase of suitable specificity, some peptide bonds can be synthesized by a thermodynamically controlled enzyme aminolysis of specific acylamino or peptide acids; any peptide bond can be formed by a kinetically controlled enzyme aminolysis of the corresponding acylamino or peptide esters.     

Design and semisynthesis of spermine-sensitive Ribonuclease S'.

Spermine-sensitive stabilization of semisynthetic Ribonuclease S' was successfully carried out by sequence specific incorporation of a poly-anion domain into alpha-helix region of S-peptide.     

Enzyme-assisted semisynthesis of polypeptide active esters and their use.

A method is described for the preparation of polypeptides activated uniquely at the C-terminus. The polypeptide is incubated in a concentrated solution of an amino acid active ester, the latter having its amino group free but adequately protected by protonation. The amino acid ester is coupled via its amino group to the C-terminus of the polypeptide by enzymic catalysis (reverse proteolysis). The resulting polypeptide C-terminal active ester is then isolated and coupled to a suitable amino component (generally a polypeptide) in a subsequent chemical coupling. The method appears to be generally applicable; fragments of horse heart cytochrome c, and porcine insulin, are used as examples. Two new analogues of cytochrome c have been prepared by using this method, with yields of up to 60% in the final coupling. Scope and limitations of the method are discussed.     

Enhancing protein engineering capabilities by combining mutagenesis and semisynthesis.

If site-directed mutagenesis could be used to facilitate protein semisynthesis, then structural engineering goals should be achieved that are unattainable by either technique alone. We tested this possibility by mutating Ser65 of yeast cytochrome c to methionine, creating a new site for CNBr cleavage. Fragments obtained by cleaving there were found to refold cooperatively, bringing together the breakpoint termini and leading to efficient autocatalytic peptide bond synthesis. Structurally modified fragments may be substituted for natural ones. Generally, naturally occurring sites are unsuitable for autocatalytic religation, for reasons briefly discussed, and thus the power of this new approach lies in the freedom to choose sites, including enzymatic ones, that are appropriate to the semisynthetic goals.     

Combinatorial semisynthesis of biomarker-IgM complexes

Circulating immune complexes formed by tumor antigens and immunoglobulin M (IgM) represent a novel class of biomarkers with diagnostic value for early cancer detection. The quantitative analysis of these immune complexes is achieved by enzyme-linked immunosorbent assay (ELISA) methods using a purified calibrator from samples of patients with cancer. These complexes obtained from samples of human origin are not suitable for cost-effective production processes with high safety standards. Given the ill-defined biomarker/IgM ratio in these complexes, semisynthesis with retention of functional properties is difficult to achieve and may vary widely according to the batch-to-batch heterogeneity of starting biological preparations. Here the authors describe the development of a combinatorial method for defining the optimal reaction conditions for the reproducible semisynthesis of biomarker-IgM complexes by exploiting the biotin-avidin technology. The method relies on screening by ELISA the 3D composition space defined by the combinatorial variation of biotinylated-biomarker, biotinylated-IgM, and avidin concentrations aiming to select those conditions leading to biomarker-IgM complexes with the highest immunoreactivity. The method allows the reproducible synthesis of species with immunoreactivity comparable to that of natural immune complexes and endowed with sufficient stability to be used as calibrators in ELISA.     

The preparation of protected fragments of lysozyme for semisynthesis.

This paper reports the development of methods for preparing tryptic fragments of hen's-egg lysozyme in an appropriate state of protection for use in the chemical synthesis of modified polypeptides. 1. We describe the cleavage of the disulphide bridges of the enzyme and the simulatneous protection of the liberated thiol groups by S-sulphonation. Lysozyme resisted the usual conditions for this reaction. We have confirmed the stability of the S-sulphonyl group to the conditions met in peptide synthesis. 2. We describe the reversible protection of the amino groups of the enzyme by reaction with various anhydrides of 1,2-dicarboxylic acids. We conclude that 2-methylmaleic anhydride and exo-cis-3,6-endoxo-delta4-tetrahydrophthalic anhydride are unsuitable for our purpose but that maleic anhydride can, in spite of certain drawbacks, be used. 3. We describe the tryptic cleavage of the thiol- and amino-protected protein and the separation of the fragments. 4. We describe the reversible protection of the carboxylic acid groups (including the specific deprotection of the alpha-carboxyl group), the imidazolyl group and the aloph-amino groups of the fragments. Several alternative groups have been evaluated for most of these purposes. The side-chain amides did not present any serious problem of libility, 5. We describe experiments on the stability of the side chain of tryptophan, both protected by formylation and unprotected, to the acid conditions needed for the deprotection of the other functional groups in the peptide. We conclude that protection of tryptophan is unnecessary. We suggest that most of the methods described are of general application in peptide semisynthesis by fragment condensation. An Appendix is included to which points 6-ll appertain...     

The semisynthesis of portions of hen''s-egg lysozyme by fragment condensation.

1. We have evaluated several methods for coupling protected tryptic peptides and have selected one that is satisfactory in terms of efficiency and degree of racemization. 2. We report the use of the chosen method (which must be slightly modified for each application in the light of the result of micro-scale pilot experiments) for the preparation of five fragments of hen's-egg lysozyme ranging in length from 31 to 51 residues. 3. We report methods for the complete deprotection of these fragments. They have been characterized by end-group determination, amino acid analysis and tryptic digestion.     

Chemical synthesis and semisynthesis of membrane proteins

Total chemical synthesis and semisynthesis of proteins have become widely used tools to alter and control the chemical structure of soluble proteins, Thus, offering unique possibilities to understand protein function in vitro and in vivo. However, these approaches rely on our ability to produce and chemoselectively link peptide segments with each other or with recombinantly produced protein segments. Access to integral membrane and membrane-associated proteins via these approaches has been hampered by the fact that integral membrane peptides or lipid-modified peptides are difficult to obtain mostly due to incomplete amino acid coupling reactions and their poor handling properties. This article will highlight the advances in the total chemical synthesis and semisynthesis of small viral as well as bacterial ion channels. Recent synthesis approaches for membrane-associated proteins will be discussed as well.     

Enzymatic semisynthesis of [LeuB30] insulin

Experimental conditions for the preparation of [LeuB30] insulin by coupling of des-AlaB30 insulin with Leu-OBu(t) were determined using Achromobacter protease I and trypsin as catalysts. Successful coupling required a large excess of the amine component (0.8 M), a high concentration of organic cosolvent (35-50%) and neutral pH of the reaction mixture. The coupling yield of Achromobacter protease I after 24 h at 37 degrees C was almost the same or a little higher than that at 25 degrees C. With trypsin, the coupling yield at 37 degrees C after 24 h was considerably lower than at 25 degrees C. This was partly ascribed to the difference in concentration of organic cosolvent at 37 degrees C and 25 degrees C; 35% and 50%, respectively, or possibly of enzyme stability at these temperatures. The maximum product yield was about 90% with both enzymes under optimal conditions. A preparative scale experiment was performed with Achromobacter protease I; the yield of [LeuB30] insulin was 51% using porcine insulin as the starting material. This semisynthetic insulin was identified by HPLC and amino acid analysis. No difference was observed in CD spectra between [LeuB30] insulin and human insulin.     

Enzymatic semisynthesis of human insulin: an update

Peptide bond formation can be enzymatically catalysed by the reverse reaction of proteases. Application is seen in the industrial production of human insulin. Human insulin derivative can be enzymatically prepared using either porcine insulin or the single chain B(1-29)-A(1-21) insulin precursor as the starting material. This is accomplished by either (1) digesting the starting material at Lys29 with Achromobacter lyticus protease I (Ach) and then coupling with Thr-X (X = blocking residue) (two-step reaction) or (2) subjecting Ala-B30 of porcine insulin or Gly-A1 of the single chain insulin precursor to transpeptidation with Thr-X (one-step reaction). Trypsin and Ach can be used for either type of reaction and, in the immobilized form, for the two-step reaction. Since the single chain insulin precursor can be produced by gene technology (yeast), use of immobilized trypsin or Ach and the two-step reaction using the single chain insulin precursor as the starting material ensures the continuous production of human insulin making it a feasible method for industrial manufacture.     

The semisynthesis of analogues of cytochrome c. Modifications of arginine residues 38 and 91.

The arginine residues at positions 38 and 91 of horse cytochrome c are absolutely conserved throughout eukaryotic evolution. For studies of the functional roles of these residues, we have prepared, by semisynthetic techniques, analogues of cytochrome c in which one or the other of the arginine residues has been modified. The products of modification by adduct formation with pentane-2,4-dione were purified and extensively characterized. In biological tests, the arginine-91-modified cytochrome c showed little difference in behaviour from native horse cytochrome c. Modification of arginine-38, however, led to extensive changes in biological and chemical properties. We also prepared and tested adducts with cyclohexane-1,2-dione and camphorquinone-10-sulphonic acid. The same effects on biological properties were noted irrespective of the nature of the modifying group. We suggest reasons for the differences in sensitivity of the two sites.     

The preparation of tritiated insulin specifically labelled by semisynthesis at glycine-A1.

We have prepared and characterized semisynthetic [GlyA1-3H]insulin. The preparation was carried out at specific radioactivities ranging from 1Ci/mmol to 44Ci/mmol. The largest quantity prepared in any one synthesis was 3.5 mCi. Chemical degradation showed that the label was in its expected position in the molecule. The semisynthetic product behaved authentically on reversed-phase h.p.l.c. and radioimmunoassay. It gave the expected profiles of biological activity as regards depression of blood sugar concentration in rats and stimulation of conversion of glucose into lipid in isolated rat fat-cells. We discuss some applications for which this tracer would be particularly suited. An expanded version of this paper, containing full experimental details of the semisynthesis and characterization of [GlyA1-3H]insulin, has been deposited as Supplementary Publication SUP 50129 (30 pages) at the British Library (Lending Division), Boston Spa, Wetherby, West Yorkshire LS23 7BQ, U.K., from whom copies can be obtained on the terms indicated in Biochem. J. (1985) 225, 5.     

The curious case of protein splicing: mechanistic insights suggested by protein semisynthesis.

The gradual accumulation of examples of protein splicing, in which a nested intervening sequence is spliced out of the interior of a polyprotein precursor, suggests that this curious phenomenon might prove to have universal phylogenetic distribution and biological significance. The known examples are reviewed, with the aim of establishing underlying patterns, and a generalized mechanism of autocatalytic protein splicing is proposed. The testable consequences of such a proposal and the possible evolutionary origins of the phenomenon are discussed.     

Axial ligand replacement in horse heart cytochrome c by semisynthesis

Semisynthesis has been employed to replace the axial methionine in horse heart cytochrome c with histidine. The reduction potential of the His-80 protein (cyt c-His-80) is 41 mV vs NHE (0.1 M phosphate; pH 7.0; 25 degrees C). The absorption spectra of oxidized and reduced cyt c-His-80 are very similar to those of the native protein in the porphyrin region, but the 695 nm band is absent in the oxidized His-80 protein.     

The role of tyrosine 67 in the cytochrome c heme crevice structure studied by semisynthesis.

Tyr-67 of mitochondrial cytochrome c is thought to be involved in important hydrogen bonding interactions in the hydrophobic heme pocket of the protein (Takano, T., Dickerson, R. E. (1981) J. Mol. Biol. 153:95-115). The role of this highly conserved residue in heme pocket stability was studied by comparing properties of semisynthetic (Phe-67) and (p-F-Phe-67) analogs with those of native cytochrome c and a "control" analog, (Hse-65)cytochrome c. The (Phe-67) and (p-F-Phe-67) analogs have well-developed 695-nm visible absorption bands and are active in a cytochrome c oxidase assay. The reduction potentials of both analogs are lower than the native protein by approximately 50 mV. Although both analogs bind imidazole with higher affinity than the native protein, only the (p-F-Phe-67) analog has a 3- to 5-fold lower binding constant for cyanide. Only the (Phe-67) analog was significantly more stable toward alkaline isomerization. These results are not consistent with stabilization of the native protein heme pocket via hydrogen bonding of Tyr-67 to Met-80. An alternative steric role for Tyr-67 is proposed in which the residue controls the heme reduction potential by limiting the number of internal H2O molecules in the heme pocket.