Semisynthetic peptides and proteins

Volume exclusion effect as a driving force for reverse proteolysis. Implications for polypeptide assemblage in a macromolecular crowded milieu

Macromolecular crowding, in principle, should affect any reaction that is accompanied by significant reduction in excluded volume. Here we have examined the influence of crowding on reverse proteolysis. We show that proteosynthesis of a polypeptide product with an interacting folding motif such as coiled coil is facilitated in crowded media as a consequence of the volume exclusion effect. Further, we demonstrate that crowding could also effect the conversion of a noncovalent protein complex (fragment complementing protein) obtained by limited proteolysis to the native covalent form, but only if the formation of the native protein results in large compaction leading to a substantial volume exclusion effect. Subtilisin-catalyzed reformation of native triosephosphate isomerase (TIM) from multiple fragments is facilitated by crowding. However, a single nick in ribonuclease S (RNase S) could not be ligated under similar conditions. The failure of generation of RNase A from RNase S is consistent with the fact that the crystal structure of the two forms are almost superimposable, and hence no significant difference of volume exclusion exists between reactant (RNase S) and product (RNase A). In contrast, considerable compaction, and consequently large reduction in excluded volume, is attained through the assembly of a TIM barrel structure. Taken together, these results have implications for both in vitro as well as in vivo polypeptide assemblage by reverse proteolysis.

Kinetic characterization of ribonuclease S mutants containing photoisomerizable phenylazophenylalanine residues

Incorporation of the photoisomerizable amino acid phenylazophenylalanine (PAP) into enzyme structures has been proposed as a strategy for photoswitching enzyme activity. To evaluate the strengths and limitations of this approach to enzyme photo-control, we performed a kinetic analysis of RNase S analogues containing PAP in positions 4, 7, 8, 10, 11 or 13. For an enzyme containing a single PAP group, the maximum extent of photoconversion (between approximately 96% trans/4% cis and 10% trans/90% cis under standard conditions) sets a limit on the maximum fold change in the initial rate of approximately 25-fold, if the cis form is the more active isomer, and approximately 10-fold if the trans form is more active. This extent of photoswitching was not realized in the present case because the effects of photoisomerization on kinetic constants were small and distributed among effects on S-peptide binding, substrate binding and the rate of the chemical step. These results suggest that photoisomerization could substantially alter enzyme kinetic constants but that a directed combinatorial approach might be required for realizing maximal photo-control in such systems. The limit set by the extent of photoconversion might be overcome by coupling multiple PAP groups to one enzyme or by altering the behaviour of a system that required oligomerization for activity.

An enigmatic peptide ligation reaction: protease-catalyzed oligomerization of a native protein segment in neat aqueous solution

We report an enigmatic peptide ligation reaction catalyzed by Glu-specific Staphylococcus aureus V8 protease that occurs in neat aqueous solution around neutral pH utilizing a totally unprotected peptide substrate containing free alpha-carboxyl and alpha-amino groups. V8 protease catalyzed a chain of ligation steps between pH 6 and 8 at 4 degrees C, producing a gamut of covalent oligomers (dimer through octamer or higher) of a native protein segment TAAAKFE (S39) derived from ribonuclease A (RNAse A). Size-exclusion chromatography suggested the absence of strong interaction between the reacting peptides. The circular dichroism spectra of monomer through pentamer showed length-dependent enhancement of secondary structure in the oligomers, suggesting that protease-catalyzed ligation of a monomer to an oligomer resulted in a product that was more structured than its precursor. The relative conformational stability of the oligomers was reflected in their ability to resist proteolysis, indicating that the oligomerization reaction was facilitated as a consequence of the "conformational trapping" of the product. The ligation reaction proceeded in two phases-slow formation and accumulation of the dimer followed by a fast phase of oligomerization, implying that the conformational trap encountered in the oligomerization reaction was a two-step process. The Gly substitution at any position of the TAAAKFE sequence was deleterious, suggesting that the first step of the conformational trap, namely the dimerization reaction, that proceeded very slowly even with the parent peptide, was quite sensitive to amino acid sequence. In contrast, the oligomerization reaction of an Ala analog, AAAAKFE, occurred in much the same way as S39, albeit with faster rate, suggesting that Ala substitution stabilized the overall conformational trapping process. The results suggest the viability of the product-directed "conformational trap" as a mechanism to achieve peptide ligation of totally unprotected peptide fragments in neat aqueous solution. Further, the study projects the presence of considerable innate synthetic potential in V8 protease, baring rich possibilities of protein engineering of this enzyme to generate a "V8 peptide ligase."

Role of the amino-terminal region of streptokinase in the generation of a fully functional plasminogen activator complex probed with synthetic peptides

The mechanism whereby fragments of streptokinase (SK) derived from its N terminus (e.g., SK1-59 or SK1-63) enhance the low plasminogen (PG)-activating ability of other fragments, namely SK64-386, SK60-414, SK60-387, and SK60-333 (reported previously), has been investigated using a synthetic peptide approach. The addition of either natural SK1-59, or chemically synthesized SK16-59, at saturation (about 500-fold molar excess) generated amidolytic and PG activation capabilities in equimolar mixtures of human plasminogen (HPG) and its complementary fragment (either SK60-414 or SK56-414, prepared by expression of truncated SK gene fragments in Escherichia coli) that were approximately 1.2- and 2.5-fold, respectively, of that generated by equimolar mixtures of native SK and HPG. Although in the absence of SK1-59 equimolar mixtures of SK56-414 and HPG could generate almost 80% of amidolytic activity, albeit slowly, less than 2% level of PG activation could be observed under the same conditions, indicating that the contribution of the N-terminal region lay mainly in imparting in SK56-414 an enhanced ability for PG activation. The ability of various synthetic peptides derived from the amino-terminal region (SK16-51, SK16-45, SK37-59, SK1-36, SK16-36, and SK37-51) to (1) complement equimolar mixtures of SK56-414 and HPG for the generation of amidolytic and PG activation functions, (2) inhibit the potentiation of SK56-414 and HPG by SK16-59, and (3) directly inhibit PG activation by the 1:1 SK-HPG activator complex was tested. Apart from SK16-59, SK16-51, and 16-45, the ability to rapidly generate amidolytic potential in HPG in the presence of SK56-414 survived even in the smaller SK-peptides, viz., SK37-59 and SK37-51. However, this ability was abolished upon specifically mutating the sequence -LTSRP-, present at position 42-46 in native SK. Although SK16-51 retained virtually complete ability for potentiation of PG activation in comparison to SK16-59 or SK1-59, this ability was reduced by approximately fourfold in the case of SK16-45, and completely abolished upon further truncation of the C-terminal residues to SK16-36 or SK1-36. Remarkably, however, these peptides not only displayed ability to bind PG, but also showed strong inhibition of PG activation by the native activator complex in the micromolar range of concentration; the observed inhibition, however, could be competitively relieved by increasing the concentration of substrate PG in the reaction, suggesting that this region in SK contains a site directed specifically toward interaction with substrate PG. This conclusion was substantiated by the observation that the potentiation of PG activating ability was found to be considerably reduced in a peptide (SK25-59) in which the sequence corresponding to this putative locus (residues 16-36) was truncated at the middle. On the other hand, fragments SK37-51 and SK37-59 did not show any inhibition of the PG activation by native activator complex. Taken together, these findings strongly support a model of SK action wherein the HPG binding site resident in the region 37-51 helps in anchoring the N-terminal domain to the strong intermolecular complex formed between HPG and the region 60-414. In contrast, the site located between residues 16 and 36 is qualitatively more similar to the previously reported PG interacting site (SK254-273) present in the core region of SK, in being involved in the relatively low-affinity enzyme-substrate interactions of the activator complex with PG during the catalytic cycle.

Conformationally driven protease-catalyzed splicing of peptide segments: V8 protease-mediated synthesis of fragments derived from thermolysin and ribonuclease A

We have studied the conformation as well as V8 protease-mediated synthesis of peptide fragments, namely amino acid residues 295-316 (TC-peptide) of thermolysin and residues 1-20 (S-peptide) of ribonuclease A, to examine whether "conformational trapping" of the product can facilitate reverse proteolysis. The circular dichroism study showed cosolvent-mediated cooperative helix formation in TC-peptide with attainment of about 30-35% helicity in the presence of 40% 1-propanol and 2-propanol solutions at pH 6 and 4 degrees C. The thermal melting profiles of TC-peptide in the above cosolvents were very similar. V8 protease catalyzed the synthesis of TC-peptide from a 1:1 mixture of the non-interacting complementary fragments (TC295-302 and TC303-316) in the presence of the above cosolvents at pH 6 and 4 degrees C. In contrast, V8 protease did not catalyze the ligation of S1-9 and S10-20, although S-peptide could assume helical conformation in the presence of the cosolvent used for the semisynthetic reaction. V8 protease was able to synthesize an analog of S-peptide (SA-peptide) in which residues 10-14 were substituted (RQHMD-->VAAAK). While S-peptide exhibited helical conformation in the presence of aqueous propanol solutions, SA-peptide displayed predominantly beta-sheet conformation. SA-peptide showed enhanced resistance to proteolysis as compared with S-peptide. Thus, failure of semisynthesis of S-peptide may be a consequence of high flexibility around the 9-10 peptide bond due to its proximity to the helix stop signal. The results suggest that protease-mediated ligations may be achieved by design and manipulation of the conformational aspects of the product.

Subtiligase: a tool for semisynthesis of proteins

A variant of subtilisin BPN', which we call subtiligase, has been used to ligate esterified peptides site-specifically onto the N termini of proteins or peptides in aqueous solution and in high yield. We have produced biotinylated or heavy-atom derivatives of methionyl-extended human growth hormone (Met-hGH) by ligating it onto synthetic peptides containing biotin or mercury. Polyethylene glycol (PEG)-modified atrial natriuretic peptide (ANP) was produced by ligating ANP onto peptides containing sites for PEG modification. We have established the N-terminal sequence requirements for efficient ligation onto proteins, using either synthetic substrates or pools of filamentous phage containing Met-hGH with random N-terminal sequences (substrate phage). To facilitate ligations involving proteins with highly structured or buried N termini, a more stable subtiligase was designed that effectively ligates peptides onto Met-hGH even in 4 M guanidine hydrochloride. The use of subtiligase should expand the possibilities for protein semisynthesis and rational protein design.

Site-specific incorporation of biophysical probes into proteins

Biophysical probes which can detect structural changes in proteins and the interaction of proteins with other macromolecules are important tools in studying protein function. Many difficulties remain, however, in introducing probes into proteins site-specifically. Here we report the successful site-specific incorporation of a spin-labeled, a fluorescent, and a photoactivatible amino acid into a variety of surface and internal sites in bacteriophage T4 lysozyme by using unnatural amino acid mutagenesis. In addition, we report the purification and spectral characterization of T4 lysozyme mutants containing the spin-labeled amino acid and the fluorescent amino acid. The ability to incorporate these probes site-specifically allows for novel studies of protein structure and dynamics. Moreover, this work demonstrates that the Escherichia coli protein biosynthetic machinery can tolerate unnatural amino acids with little resemblance to the natural amino acids.

Interaction of semisynthetic variants of RNase A with ribonuclease inhibitor

Derivatives of ribonuclease A (RNase A) with modifications in positions 1 and/or 7 were prepared by subtilisin-catalyzed semisynthesis starting from synthetic RNase 1-20 peptides and S-protein (RNase 21-124). The lysyl residue at position 1 was replaced by alanine, whereas Lys-7 was replaced by cysteine that was specifically modified prior to semisynthesis. The enzymes obtained were characterized by protein chemical methods and were active toward uridylyl-3',5'-adenosine and yeast RNA. When Lys-7 was replaced by S-methyl-cysteine or S-carboxamido-contrast, the catalytic properties were only slightly altered. The dissociation constant for the RNase A-RI complex increased from 74 fM (RNase A) to 4.5 pM (Lys-1, Cys-7-methyl RNase), corresponding to a decrease in binding energy of 10 kJ mol-1. Modifications that introduced a positive charge in position 7 (S-aminoethyl- or S-ethylpyridyl-cysteine) led to much smaller losses. The replacement of Lys-1 resulted in a 4-kJ mol-1 loss in binding energy. S-protein bound to RI with Ki = 63.4 pM, 800-fold weaker than RNase A. This corresponded to a 16-kJ mol-1 difference in binding energy. The results show that the N-terminal portion of RNase A contributes significantly to binding of ribonuclease inhibitor and that ionic interactions of Lys-7 and to a smaller extent of Lys-1 provide most of the binding energy.

Structure-function relationships for the EGF/TGF-alpha family of mitogens

Epidermal growth factor (EGF) and transforming growth factor alpha (TGF-alpha) are ligands for the EGF-receptor and act as mitogens for a variety of tissues. TGF-alpha, in particular, has been implicated as an autocrine growth factor for several cancer cell lines. Over the last 10 years many groups have examined the structure-function relationships in EGF/TGF-alpha in attempts to develop antagonists or agonists. In this review the results of these studies are summarised and related to the three-dimensional structure of EGF/TGF-alpha. The difficulties associated with the purification and characterisation of analogues of EGF/TGF-alpha and with the biological assays are discussed. It is clear that these difficulties have, in some cases, led to apparently contradicting results. The available binding data indicate that the receptor interaction surface for EGF/TGF-alpha might encompass one complete side of the molecule with a few strong binding determinants, in particular Arg41 and Leu47. The arginine at position 41 is the most critical residue and its full hydrogen-bonding capacity is needed for strong binding of EGF/TGF-alpha to the EGF-receptor. As this side of the molecule consists of residues from both the N- and C-terminal domain, it seems unlikely that agonists or antagonists can be developed on the basis of short peptides taken from the primary sequence. This concept is supported by the available binding and activity data.

Restriction in the conformational flexibility of apoproteins in the presence of organic cosolvents: a consequence of the formation of "native-like conformation"

The influence of n-propanol on the overall alpha-helical conformation of beta-globin, apocytochrome C, and the functional domain of streptococcal M49 protein (pepM49) and its consequence on the proteolysis of the respective proteins has been investigated. A significant amount of alpha-helical conformation is induced into these proteins at pH 6.0 and 4 degrees C in the presence of relatively low concentrations of n-propanol. The induction of alpha-helical conformation into the proteins increased as a function of the propanol concentration, the maximum induction occurring around 30% n-propanol. In the case of alpha-globin, the fluorescence of its tryptophyl residues also increased as a function of n-propanol concentration, the midpoint of this transition being around 20% n-propanol. Furthermore, concomitant with the induction of helical conformation into these proteins, the proteolysis of their polypeptide chain by V8 protease also gets restricted. The alpha-helical conformation induced into alpha- and beta-globin by n-propanol decreased as the temperature is raised from 4 to 24 degrees C. In contrast, the alpha-helical conformation of both alpha- and beta-chain (i.e., globin with noncovalently bound heme) did not exhibit such a sensitivity to this change in temperature. However, distinct differences exist between the n-propanol induced "alpha-helical conformation" of globins and the "alpha-helical conformation" of alpha- and beta-chains. A cross-correlation of the n-propanol induced increase in the fluorescence of beta-globin with the corresponding increase in the alpha-helical conformation of the polypeptide chain suggested that the fluorescence increase represents a structural change of the protein that is secondary to the induction of the alpha-helical conformation into the protein (i.e., an integration of the helical conformation induced to the segments of the polypeptide chain to influence the microenvironment of the tryptophyl residues). Presumably, the fluorescence increase is a consequence of the packing of the helical segments of globin to generate a "native-like structure." The induction of alpha-helical conformation into these proteins in the presence of n-propanol and the consequent generation of "native-like conformation" is not unique to n-propanol. Trifluoroethanol, another helix-inducing organic solvent, also behaves in the same fashion as n-propanol. However, in contrast to the proteins described above, n-propanol could neither induce an alpha-helical conformation into performic acid oxidized RNAse-A nor restrict its proteolysis by proteases.(ABSTRACT TRUNCATED AT 400 WORDS)

Proteosynthetic activity of immobilized Staphylococcus aureus V8 protease: application in the semisynthesis of molecular variants of alpha-globin

The proteosynthetic activity of Staphylococcus aureus V8 protease (endoproteinase Glu-C) immobilized onto cross-linked agarose beads by reductive alkylation procedure has been investigated. The overall substrate specificity of the enzyme, as judged by peptide mapping of performic acid oxidized RNase A, as well as the high propensity of the protease to slice selectively the alpha-chain of hemoglobin (Hb) A at the Glu(30)-Arg(31) peptide bond at pH 4.0 and 37 degrees C was essentially unperturbed by the immobilization process. This high susceptibility of Glu(30) of the alpha-chain for proteolysis appears to be a consequence of the conformational aspects of the polypeptide in this region. The proteolysis of two mutant forms of alpha-chain, namely, those of Hb I (K16E) and Hb Sealy (D47H) by immobilized V8 protease at the Glu(30)-Arg(31) peptide bond proceeds with the same selectivity. The immobilized protease also retained the proteosynthetic activity, i.e., the ability to ligate the unprotected alpha-globin fragments at the Glu(30)-Arg(31) peptide bond in the presence of 30% 1-propanol. The use of the insoluble enzyme simplifies the procedures for the construction of new semisynthetic, molecular variants of alpha-globin. The general applicability of the immobilized enzyme for protein semisynthesis has been demonstrated by the construction of a doubly mutated alpha-globin. The complementary fragments from two natural mutant forms of alpha-globin, viz., alpha 1-30 (K16E) from Hb I and alpha 31-141 (D47H) from Hb Sealy, are readily ligated to form the double mutant alpha 1-141 (K16E;D47H).

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.

High-efficiency transpeptidation catalysed by clostripain and electrostatic effects in substrate specificity

Clostripain catalyses the transpeptidation between benzoylarginin ethyl ester and amino acid amides, oligopeptides, insulin A- and B-chains and tryptic peptides of myoglobin at millimolar substrate concentrations. The reactions proceed with temporary accumulation of the products, followed by hydrolytic decomposition. The yield was not affected significantly by the type of N-terminal amino acid, but was diminished markedly by the negative charges of the amine components. The yields for natural peptides were linearly related to the charge density of the peptides.

Semisynthesis of carboxy-terminal fragments of thermolysin

Enzyme-catalyzed synthesis of two polypeptide fragments, one of which is obtained by chemical synthesis, in the presence of proteolytic enzymes and in aqueous organic solvents constitutes a convenient procedure for the synthesis of proteins and their analogs. This novel semisynthetic procedure was investigated for preparing COOH-terminal fragments of the metallo-protease thermolysin. Fragment 205-316, obtained by autolysis of the protein in the presence of EDTA, was first cleaved selectively with Staphylococcus aureus V8 protease at the level of the single Glu302 residue into fragments 205-302 and 303-316. Upon incubation for 2-5 days of fragment 205-302 with a 5-fold excess of peptide 303-316, prepared by solid phase synthesis, with V8-protease in 0.1 M ammonium acetate, pH 6.0, containing 50% glycerol as organic cosolvent, enzyme-catalyzed reformation of the peptide bond was achieved in yields up to approximately 90% (based on fragment 205-302). The same procedure was used to prepare also the thermolysin fragments 205-315 and 205-311 by enzymatic coupling of fragment 205-302 to peptide 303-315 or 303-311, these last prepared by proteolytic digestion of the synthetic peptide 303-316. This procedure of semisynthesis opens up an approach for the site-directed modification of the tetrahelical COOH-terminal fragment 205-316 of thermolysin at the level of its helical segment encompassing residues 301-312 in the native, intact protein. Such analogs will be useful for examining structure-folding-stability relationships in this folded fragment possessing domain-like characteristics.

Conformational studies of alpha-globin in 1-propanol: propensity of the alcohol to limit the sites of proteolytic cleavage

Selective condensation of the unprotected fragments of alpha-globin--namely, alpha 1-30 and alpha 31-141--is catalyzed by Staphylococcus aureus V8 protease in the presence of 25% 1-propanol. The propensity of 1-propanol to induce the alpha-helical conformation and to generate a "native-like" topology for the polypeptide chain has been now investigated in an attempt to understand the molecular basis of this enzyme-catalyzed stereospecific condensation. Removal of heme from the alpha-chain decreases the overall alpha-helical conformation of the protein considerably. A significant amount of the alpha-helical conformation is restored in the presence of 25% 1-propanol and the digestion of alpha-globin by V8 protease becomes more selective concomitant with the increase in helicity. V8 protease digestion of alpha-globin at pH 6.0 and 4 degrees C occurs at Glu-30, Asp-47, Glu-27, and Glu-23 in the absence of 1-propanol. In the presence of 25% 1-propanol, the digestion is selective to the peptide bond of Glu-30. This selectivity appears to be a characteristic feature of the native conformation of alpha-chain (polypeptide chain with bound heme). 1-Propanol induces the alpha-helical conformation into RNase S peptide also. However, this increased helical conformation did not protect the RNase S peptide from V8 protease digestion at the Glu-9-Arg-10 peptide bond. RNase S peptide is an alpha-helical conformation in RNase S, an interacting fragment-complementing system of S protein and S peptide. S peptide is resistant to V8 protease hydrolysis in this conformation. Thus, the resistance of a peptide bond in a segment of a protein to protease digestion appears to be a consequence of the secondary structure as well as the tertiary interactions of this segment with the rest of the molecule. The results suggest that the 1-propanol induces alpha-helical conformation into segments of alpha-globin as well as packing of these helices in a native-like topology.

Permissible discontinuity region of the alpha-chain of hemoglobin: noncovalent interaction of heme and the complementary fragments alpha 1-30 and alpha 31-141

Generation of a fragment-complementing system of the alpha-chain on limited proteolysis with Staphylococcus aureus V8 protease has been investigated. Digestion of the alpha-chain (0.4 mM) of hemoglobin with V8 protease in phosphate buffer at pH 6.0 and 37 degrees C is limited to the peptide bonds of Glu-23, Glu-27, Glu-30, and Asp-47. Gel filtration of a V8 protease digest of the alpha-chain on a Sephadex G-50 column did not release any heme to the low molecular weight region, though some peptides were released from the protein. The filtration studies revealed the presence of two heme-containing components in the digest, the major one eluting at the alpha-chain position and the minor one eluting slightly ahead of the alpha-chain position. Reversed-phase high-performance liquid chromatography and amino-terminal sequence analysis demonstrated that the component eluting at the alpha-chain position contains species generated by the noncovalent interactions of heme and the complementary fragments alpha 1-30 and alpha 31-141. In dilute solutions (0.04 mM) the V8 protease digestion occurred exclusively on the carboxyl side of Glu-30(alpha). This high selectivity was also observed at pH 4.0 and pH 7.8. The visible spectra and the ultraviolet circular dichroic spectra of the digest reflect the native-like structure of the noncovalent fragment system. The dissociation constant of alpha 1-30 appears to be in the range of 10(-8) M. In tetrameric hemoglobin A the peptide bond of Glu-30-Arg-31 of the alpha-chain is not accessible to V8 protease digestion.(ABSTRACT TRUNCATED AT 250 WORDS)

Synthetic potential of Staphylococcus aureus V8-protease: an approach toward semisynthesis of covalent analogs of alpha-chain of hemoglobin S

Enzyme-catalyzed reformation of peptide bonds in the noncovalent fragment systems of proteins has been emerging as a convenient procedure for the semisynthesis of covalent analogs of the respective proteins. Limited proteolysis of the alpha-chain of hemoglobin S with Staphylococcus aureus V8-protease converts the chain into a fragment-complementing system by hydrolyzing the peptide bond Glu(30)-Arg(31) of the chain. Therefore, it is conceivable that semisynthesis of covalent analogs of alpha-chain could be achieved if conditions for the V8-protease catalyzed formation of peptide bonds could be established. The synthetic potential of V8-protease has been now investigated by incubating V8-protease-derived fragments of alpha-chain, namely alpha 1-30 and alpha 31-47 with the enzyme at pH 6.0 in the presence of n-propanol as the organic cosolvent. RP high performance liquid chromatography analysis showed that a new chromatographically distinct component is generated on incubation, and this has been identified as alpha 1-47 by amino acid analysis, redigestion with V8-protease (in the absence of n-propanol), and tryptic peptide mapping. Optimal conditions for the synthesis of alpha 1-47 is at pH 6.0, 4 degrees C, and 24 hr of incubation with 25% n-propanol as organic cosolvent. This stereospecific condensation of the fragments proceeded to a high level of about 50% in 24 hr. Further incubation up to 72 hr did not increase the yield of alpha 1-47, suggesting that an equilibration of synthesis and hydrolysis reactions has been attained. The demonstration of the synthetic potential of V8-protease and the fact that alpha 1-30 and alpha 31-141 interact to form a native-like complex, opens up an approach for the semisynthesis of covalent analogs of alpha-chain of hemoglobin S.

Crystallographic structure of an active, sequence-engineered ribonuclease

X-ray diffraction methods were used to test a synthetic-modeling approach to the sequence engineering of bovine pancreatic ribonuclease. A model of RNase S-peptide (residues 1-20), having a simplified amino acid sequence but retaining elements deduced to be essential for conformation and function, was previously synthesized and found to form a catalytically active and stable complex with native S-protein (residues 21-24). We have now obtained a 3-A-resolution electron density map of this semisynthetic complex which reveals that the conformation of model peptide closely mimics that of native S-peptide, as intended by sequence design. Some small differences from the native structure are observed: Glu-2 and Arg-10 of the model complex are not close enough to form a salt bridge, the position of the His-12 imidazole ring is slightly shifted in the active site, and the peptide's amino terminus is reoriented. Nonetheless, the major structural features predicted to be essential by computer-aided peptide-design analysis are preserved in the model peptide portion of the complex. These include (i) the alpha-helical framework involving residues 3-13, (ii) the catalytically competent orientation of His-12, and (iii) complex-stabilizing non-bonding interactions involving Phe-8 and Met-13 of S-peptide and hydrophobic residues in the cleft region of S-protein. Further, sequence simplification has not introduced any non-native, potentially stabilizing contacts between the model peptide and S-protein. The results emphasize the usefulness, in redesigning native proteins, of categorizing sequence into residues providing conformational framework and those determining intra-and intermolecular surface recognition.

Limited proteolysis of thermolysin by subtilisin: isolation and characterization of a partially active enzyme derivative

Incubation of the neutral metalloendopeptidase thermolysin at pH 9-10 in the presence of 10 mM CaCl2 for 2 days at room temperature with subtilisin at a 50:1 molar ratio leads to a derivative possessing lower (approximately 3%) but intrinsic catalytic activity. This derivative, called thermolysin S, was isolated by gel filtration in approximately 80% yield and then separated from some residual intact thermolysin by an affinity chromatographic step on Sepharose-Gly-D-Phe. It was found that thermolysin S results from a tight association of two polypeptide fragments of apparent Mr of 24000 and 10000. Dissociation of the complex was achieved under strong denaturing conditions, such as gel filtration on a column equilibrated and eluted with 5 M guanidine hydrochloride. The positions of the clip sites were defined by amino acid analysis, end-group determination, and amino acid sequencing of the isolated fragments and shown to lie between Thr-4 and Ser-5, between Thr-224 and Gln-225, and also between Gln-225 and Asp-226. Thermolysin S, which is therefore a stable complex of fragments 5-224(225) and 225(226)-316, shows a shift in optimum pH of about 1 unit toward the acid range with respect to intact thermolysin and a Km essentially unchanged, with furylacryloyl-Gly-Leu-NH2 as substrate. Inhibitors of thermolysin such as ethoxyformic anhydride and Zn2+ ions inactivate also the nicked enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)

Synthesis and properties of an all-D model ribonuclease S-peptide

In order to examine the effect of a defined enantiomeric sequence on protein structure, the all-D model ribonuclease S-peptide, H-Ala-Glu-Ala4-Lys-Phe-Ala-Arg-Ala-His-Met-Ala2-OH, has been synthesized by the solid phase method. The all-L peptide has been synthesized previously and shown to possess 36% of ribonuclease S activity when added to ribonuclease S-protein (Komoriya, A. & Chaiken, I.M. (1982) J. Biol. Chem 257, 2599-2604). The synthetic D-peptide was purified by gel filtration and semipreparative reverse phase HPLC. Amino acid composition of the synthetic peptide was in agreement with theory and gas chromatographic analysis showed that no significant racemization had occurred during synthesis. Circular dichroism (CD) studies of the D-peptide showed a peak of positive ellipticity in the 220-230 nm region, whereas a negative ellipticity peak for the L-peptide was observed. The effects of temperature and trifluoroethanol on the far-ultraviolet CD spectra of D- and L-peptides were similar but of opposite sign, confirming the expectation that the D-peptide has the propensity to form an alpha-helical structure which is enantiomeric with respect to that formed by the L-peptide. In the presence of S-protein, the L-peptide showed hydrolytic activity against the substrate cytidine-2':3'-monophosphate, whereas the D-peptide was inactive. Addition of the D-peptide to mixtures of L-peptide and S-protein did not lead to inhibition of enzymatic activity. These results indicate lack of binding of D-peptide to S-protein to produce either an active or inactive species.

Single amino acid substitutions influencing the folding pathway of the phage P22 tail spike endorhamnosidase

Temperature-sensitive mutations in the gene for the thermostable tail spike of phage P22 interyFere with the folding and subunit association pathway at the restrictive temperature but not with the activity or stability of the protein once matured. The local sites of these mutations and the mutant amino acid substitutions have been determined by DNA sequencing. Of 11 temperature-sensitive folding mutations, 3 were replacements of glycine residues by polar residues, and three were replacements of threonine residues by residues unable to form a side-chain H-bond. There were no proline replacements. Two of the temperature-sensitive sites in which threonine residues were replaced by isoleucine residues were homologous. These sequences probably maintain the correct local folding pathway at higher temperatures. The temperature-sensitive amino acid substitutions appear to destabilize a thermolabile intermediate in the wild-type folding pathway or to increase the rate of a competing off-pathway reaction.

Minimum information content and formation of interacting ribonuclease fragment complexes

The degree to which amino acid sequence can be simplified with retention of conformational and functional properties has been investigated by semisynthesis using non-covalent fragment complexes of bovine pancreatic ribonuclease as test cases. Based on the ribonuclease S system, a set of synthetic model sequences was defined for the S-peptide (1-20) region which interacted productively with native S-protein (21-124). The most simple sequence, an eicosapeptide containing helix-favoring Ala residues at all positions except Glu 1 and 14, Phe 8, His 12, and Met 13, effected at least 15% of ribonuclease catalytic activity (versus native ribonuclease S) when added to S-protein in saturating amounts. The data for model S-peptides define an alpha-helical framework and specific side chains at positions 8, 12, and 13 as the core of sequence information necessary for S-peptide to effect a productive non-covalent complex with S-protein. Previous ribonuclease fragment studies also were used as a basis for making the productive, non-overlapping complex, (1-15):(21-111):(116-124). Addition of synthetic (1-15) and (116-124) to (21-111) led to a 3 degrees increase in Tm and 4% (versus ribonuclease A) catalytic activity. The three-fragment complex, with the beta-bend residues 112-115 deleted, exhibited significantly lower stability to thermal denaturation than did related two-fragment complexes. The potential use of three-fragment complexes related to the above is discussed for semi-synthetic sequence modeling concomitantly in the N- and C-terminal regions of ribonuclease.