Spontaneous peptide bond cleavage in aging alpha-crystallin through a succinimide intermediate

Cleavage of specific peptide bonds occurs with aging in the alpha A subunit of bovine alpha-crystallin. One of the breaks occurs at residue Asn-101. This same residue undergoes in vivo deamidation, isomerization, and racemization. Deamidation and isomerization are known to occur via succinimide ring formation of labile asparagine residues. Model studies on peptides have shown that imide formation can also lead to peptide bond cleavage (Geiger, T., and Clarke, S. (1987) J. Biol. Chem. 262, 785-794). In that case, both asparagine and aspartic acid amide would be expected as C termini of the truncated polypeptide, and this is indeed the case in the alpha A-(1-101)-chain. This thus represents a first example of nonenzymatic in vivo peptide bond cleavage in an aging protein through the formation of a succinimide intermediate. In addition, we found that in bovine lens no detectable conversion (through the action of protein-carboxyl methyltransferase) of isoaspartyl to normal aspartyl residues occurs in vivo after deamidation of Asn-101.     

Enzymatic protein carboxyl methylation at physiological pH: cyclic imide formation explains rapid methyl turnover

At pH 7.4, 37 degrees C, bovine brain protein carboxyl methyltransferase transiently methylates deamidated adrenocorticotropin. The methylation occurs at the alpha-carboxyl group of an atypical beta-carboxyl-linked isoaspartyl residue (position 25). Several lines of evidence indicate that the immediate product of demethylation is an aspartyl cyclic imide involving positions 25 and 26. The evidence includes (1) the rapid rate of methyl ester hydrolysis, which is consistent with intramolecular catalysis, (2) the inability of the demethylated product to be remethylated, (3) the charge of this product, and (4) its rate of breakdown. The eventual hydrolysis of the cyclic imide produces a 30/70 mixture of peptides containing either alpha- or beta-carboxyl-linked aspartyl residues, respectively. Cyclic imide formation is nonenzymatic and can explain the unusual lability of mammalian protein methyl esters in general. These findings suggest that protein carboxyl methylation in mammalian tissues is not a simple on/off reversible modification as it apparently is in chemotactic bacteria. Carboxyl methylation may serve to activate selected protein carboxyl groups for subsequent longer lasting modifications, possibly subserving a role in protein repair, degradation, cross-linking, or some other as yet undiscovered alteration of protein structure.     

Analysis of isoaspartate in peptides by electrospray tandem mass spectrometry

In view of the significance of Asn deamidation and Asp isomerization to isoAsp at certain sites for protein aging and turnover, it was desirable to challenge the extreme analytical power of electrospray tandem mass spectrometry (ESI-MS/MS) for the possibility of a site-specific detection of this posttranslational modification. For this purpose, synthetic L-Asp/L-isoAsp containing oligopeptide pairs were investigated by ESI-MS/MS and low-energy collision-induced dissociation (CID). Replacement of L-Asp by L-isoAsp resulted in the same kind of shifts for all 15 peptide pairs investigated: (1) the b/y intensity ratio of complementary b and y ions generated by cleavage of the (L-Asp/L-isoAsp)-X bond and of the X-(L-Asp/L-isoAsp) bond was decreased, and (2) the Asp immonium ion abundance at m/z 88 was also decreased. It is proposed that the isoAsp structure hampers the accepted mechanism of b-ion formation on both its N- and C-terminal side. The b/y ion intensity ratio and the relative immonium ion intensity vary considerably, depending on the peptide sequence, but the corresponding values are reproducible when recorded on the same instrument under identical instrumental settings. Thus, once the reference product ion spectra have been documented for a pair of synthetic peptides containing either L-Asp or L-isoAsp, these identify one or the other form. Characterization and relative quantification of L-Asp/L-isoAsp peptide mixtures are also possible as demonstrated for two sequences for which isoAsp formation has been described, namely myrG-D/isoD-AAAAK (deamidated peptide 1-7 of protein kinase A catalytic subunit) and VQ-D/isoD-GLR (deamidated peptide 41-46 of human procollagen alpha 1). Thus, the analytical procedures described may be helpful for the identification of suspected Asn deamidation and Asp isomerization sites in proteolytic digests of proteins.     

Formation of cyclic imide-like structures upon the treatment of calmodulin and a calmodulin peptide with heat

Protein cyclic imide is the putative intermediate in the formation of sites of carboxyl-methylation in eukaryotic proteins. Conditions known to induce the formation of a cyclic imide in model peptides have been applied to a protein, calmodulin. Heating of calmodulin in the dry state at 100 degrees C for 24 h after lyophilization from a pH 2.0 or pH 6.0 solution produces derivatives with altered chromatographic properties in anion-exchange HPLC. At pH 6.0, complete activity of calmodulin was retained. Analysis with Fourier transform infrared (FTIR)-photoacoustic spectroscopy demonstrated the presence of a new structure in the calmodulin molecule consistent with modification of carboxylic acid groups. The conversion of calmodulin is dependent upon the absence of Ca2+ (the presence of 1 mM ethylene glycol bis(beta-aminoethyl ether) N,N'-tetraacetic acid). A peptide analogous to the calcium binding regions of calmodulin, Asp-Lys-Asp-Gly-Asn-Gly-Thr-Ile-Thr-Thr-Lys-Glu, is also converted, upon heating, to chromatographically different forms in reversed-phase chromatography. This process is also dependent upon the absence of calcium. Sequence analysis of the peptide derivatives reveals a second amino terminus, implicating peptide bond hydrolysis in the product. A dipeptide, Asp-Gly, known to form a cyclic imide structure under similar conditions is also hydrolyzed during sequence analysis consistent with cleavage occurring at the position of the cyclic imide structure. Asp3 is suggested to be the site of cyclic imide formation in the calmodulin peptide. The presence of a cyclic imide structure is also confirmed by the application of FTIR-photoacoustic spectroscopy. These data suggest that cyclic imide formation in calmodulin has been induced, possibly at one, or more, of the calcium binding loops of the protein. These modification reactions may provide a basis for future investigations of cyclic imide formation in proteins.     

Chemical conversion of aspartyl peptides to isoaspartyl peptides. A method for generating new methyl-accepting substrates for the erythrocyte D-aspartyl/L-isoaspartyl protein methyltransferase

Mammalian protein carboxyl methyltransferases have recently been proposed to recognize atypical configurations of aspartic acid and may possibly function in the metabolism of covalently altered cellular proteins. Consistent with this proposal, the tetrapeptide tetragastrin, containing a single "normal" L-aspartyl residue (L-Trp-L-Met-L-Asp-L-Phe-NH2) was found here not to be an in vitro substrate for erythrocyte carboxyl methyltransferase activity. However, chemical treatment of tetragastrin by methyl esterification and then de-esterification of the aspartic acid residue yielded a mixture of peptide products, the major one of which could now be enzymatically methylated. We show here that this new peptide species is the isomeric beta-aspartyl form of tetragastrin (L-iso-tetragastrin; L-Trp-L-Met-L-Asp-L-Phe-NH2), and it appears that isomerization proceeds via an intramolecular succinimide intermediate during the de-esterification procedure. L-iso-Tetragastrin is stoichiometrically methylated (up to 90% in these experiments) with a Km for the enzyme of 5.0 microM. Similar chemical treatment of several other L-aspartyl peptides also resulted in the formation of new methyltransferase substrates. This general method for converting normal aspartyl peptides to isoaspartyl peptides may have application in the reverse process as well.     

Modification of synthetic peptides related to lactate dehydrogenase (231-242) by protein carboxyl methyltransferase and tyrosine protein kinase: effects of introducing an isopeptide bond between aspartic acid-235 and serine-236

The possibility that isoaspartyl residues contribute to the substrate specificity of eucaryotic protein carboxyl methyltransferases and/or tyrosine protein kinases has been investigated with two synthetic oligopeptides, Lys-Gln-Val-Val-Asp/isoAsp-Ser-Ala-Tyr-Glu-Val-Ile-Lys, which correspond to amino acids 231-242 of lactate dehydrogenase. One version of the peptide contains the normal amino acid sequence of the chicken muscle M4 isozyme. The other version contains an isoaspartyl residue in position 235 in place of the normal aspartyl residue; i.e., Asp-235 is linked to Ser-236 via its side-chain beta-carboxyl group, rather than via the usual alpha-carboxyl linkage. The normal peptide corresponds to the sequence around Tyr-238 that is phosphorylated in Rous sarcoma virus infected chick embryo fibroblasts [Cooper, J. A., Esch, F. S., Taylor, S. S., & Hunter, T. (1984) J. Biol Chem. 259, 7835]. Using protein carboxyl methyltransferase purified from bovine brain, we found that the normal peptide did not serve as a methyl-accepting substrate but that the isopeptide served as an excellent substrate, exhibiting a stoichiometry of one methyl group per peptide and Km of 0.54 microM. With tyrosine protein kinase partially purified from normal rat spleen both peptides were found to serve as phosphate acceptors at Tyr-238, exhibiting Km values of 4.7 and 8.9 mM for the normal and isopeptide versions, respectively. These results support the idea that protein carboxyl methyltransferase selectively methylates the alpha-carboxyl group of atypical isoaspartyl residues. In contrast, the presence of isoaspartate had a modest negative effect on substrate activity for a tyrosine protein kinase from rat spleen.     

Effect of conformation on the conversion of cyclo-(1,7)-Gly-Arg-Gly-Asp-Ser-Pro-Asp-Gly-OH to its cyclic imide degradation product.

The objective of this study was to explain the increased propensity for the conversion of cyclo-(1,7)-Gly-Arg-Gly-Asp-Ser-Pro-Asp-Gly-OH (1), a vitronectin-selective inhibitor, to its cyclic imide counterpart cyclo-(1,7)-Gly-Arg-Gly-Asu-Ser-Pro-Asp-Gly-OH (2). Therefore, we present the conformational analysis of peptides 1 and 2 by NMR and molecular dynamic simulations (MD). Several different NMR experiments, including COSY, COSY-Relay, HOHAHA, NOESY, ROESY, DQF-COSY and HMQC, were used to: (a) identify each proton in the peptides; (b) determine the sequential assignments; (c) determine the cis-trans isomerization of X-Pro peptide bond; and (d) measure the NH-HCalpha coupling constants. NOE- or ROE-constraints were used in the MD simulations and energy minimizations to determine the preferred conformations of cyclic peptides 1 and 2. Both cyclic peptides 1 and 2 have a stable solution conformation; MD simulations suggest that cyclic peptide 1 has a distorted type I beta-turn at Arg2-Gly3-Asp4-Ser5 and cyclic peptide 2 has a pseudo-type I beta-turn at Ser5-Pro6-Asp7-Gly1. A shift in position of the type I beta-turn at Arg2-Gly3-Asp4-Ser5 in peptide 1 to Ser5-Pro6-Asp7-Gly1 in peptide 2 occurs upon formation of the cyclic imide at the Asp4 residue. Although the secondary structure of cyclic peptide 1 is not conducive to succinimide formation, the reaction proceeds via neighbouring group catalysis by the Ser5 side chain. This mechanism is also supported by the intramolecular hydrogen bond network between the hydroxyl side chain and the backbone nitrogen of Ser5. Based on these results, the stability of Asp-containing peptides cannot be predicted by conformational analysis alone; the influence of anchimeric assistance by surrounding residues must also be considered.     

Replacement of a labile aspartyl residue increases the stability of human epidermal growth factor

Long-term storage of recombinant human epidermal growth factor (EGF), an important promoter of cell division, results in its conversion to a new species that elutes later than native EGF on a reverse-phase column. This new species, called EGF-X, has only 20% of the biological activity of native EGF. Peptide mapping indicated that the primary structure of EGF-X differs from that of native EGF solely within the first 13 residues. N-Terminal sequencing of EGF-X revealed that about 30% of the polypeptides have been cleaved at the Asp-3/Ser-4 bond. In addition, the yields after the His residue at position 10 were extremely low, indicating that a chemical modification occurs at residue 11 that is incompatible with Edman degradation. We hypothesized that aspartic acid 11 had been converted to an isoaspartyl residue, and this was confirmed with L-isoaspartyl/D-aspartyl methyltransferase, an enzyme that methylates the side-chain carboxyl group of L-isoaspartyl residues but does not recognize normal L-aspartyl residues. EGF-X, but not EGF, was found to be a substrate of this enzyme, and proteolytic digestion of EGF-X with thermolysin localized the site of methylation to a nine-residue peptide containing position 11. We did not observe formation of the isoaspartyl derivative in EGF that had been denatured by reduction of its disulfide bonds. In addition, replacement of the aspartyl residue at position 11 with glutamic acid resulted in a fully active EGF derivative that does not form detectable amounts of EGF-X. We propose that conversion of this aspartyl residue to isoaspartate is a significant nonenzymatic degradation reaction affecting this growth factor.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structural consequences of D-amino acids in collagen triple-helical peptides

The effects of racemization of aspartic acid on triple-helical formation have been studied using a "host-guest" peptide approach where selected guest Gly-Xaa-Yaa triplets were included within a common acetyl-(Gly-Pro-Hyp)3-Gly-Xaa-Yaa-(Gly-Pro-Hyp)4-Gly-Gly-amide frame-work. Four guest triplets, Gly-Asp-Hyp and Gly-Asp-Ala where Asp is either L-Asp or D-Asp were studied. Thermal stability data indicated that incorporation of D-Asp residues prevented triple-helix formation in phosphate buffered saline, although triple-helical structures were formed in a stabilizing solvent, 67% aqueous ethylene glycol. In this solvent the melting temperatures of D-Asp containing peptides were more than 30 degrees C lower than the corresponding peptides containing L-Asp. For Gly-Asp-Ala peptides, but not Gly-Asp-Hyp, peptides, melting profiles indicated that a mixture of the D- and L-Asp containing peptides were able to form heterotrimer triple-helical molecules. These studies illustrate the dramatic destabilizing effect of D-amino acids on the triple-helix stability, but indicate that they can be accommodated in this conformation.     

Enzymatic methylation of L-isoaspartyl residues derived from aspartyl residues in affinity-purified calmodulin. The role of conformational flexibility in spontaneous isoaspartyl formation

We have investigated the formation of D-aspartyl and L-isoaspartyl (beta-aspartyl) residues and their subsequent methylation in bovine brain calmodulin by the type II protein carboxyl methyltransferase. Based on the results of studies with unstructured peptides and denatured proteins, it has been proposed that the major sites of carboxyl methylation in calmodulin are at L-isoaspartyl residues that originate from two Asn-Gly sequences. To test this hypothesis, we directly identified the sites of methylation in affinity-purified preparations of calmodulin by peptide mapping using the proteases trypsin, endoproteinase Lys-C, clostripain, chymotrypsin, and Staphylococcus aureus V8 protease. We found, however, that the major high-affinity sites of methylation originate from aspartyl residues at position 2 and at positions 78 and/or 80. The methylatable residue in the first case was shown to be L-isoaspartate by comparison of the properties of a synthetic peptide corresponding to the N-terminal 13 residues substituted with an L-iso-Asp residue at position 2. The second methylatable residue, probably derived from Asp78, also appears to be an L-isoaspartyl residue. These sites appear to be readily accessible to the methyltransferase and are present in relatively flexible regions of calmodulin that may allow the spontaneous degradation reactions to occur that generate L-isoaspartyl residues via succinimide intermediates. Interestingly, the four calcium binding regions, each containing 3-4 aspartyl and asparaginyl residues (including the two Asn-Gly sequences), do not appear to contribute to the high-affinity methyl acceptor sites, even when calcium is removed prior to the methylation reaction. We propose that methylatable residues do not form at these sites because of the inflexibility of these regions when calcium is bound.     

Synthetic peptide substrates for the erythrocyte protein carboxyl methyltransferase. Detection of a new site of methylation at isomerized L-aspartyl residues

Four hexapeptides of sequence L-Val-L-Tyr-L-Pro-(Asp)-Gly-L-Ala containing D- or L-aspartyl residues in normal or isopeptide linkages have been synthesized by the Merrifield solid-phase method as potential substrates of the erythrocyte protein carboxyl methyltransferase. This enzyme has been shown to catalyze the methylation of D-aspartyl residues in proteins in red blood cell membranes and cytosol. Using a new vapor-phase methanol diffusion assay, we have found that the normal hexapeptides containing either D- or L-aspartyl residues were not substrates for the human erythrocyte methyltransferase. On the other hand, the L-aspartyl isopeptide, in which the glycyl residue was linked in a peptide bond to the beta-carboxyl group of the aspartyl residue, was a substrate for the enzyme with a Km of 6.3 microM and was methylated with a maximal velocity equal to that observed when ovalbumin was used as a methyl acceptor. The enzyme catalyzed the transfer of up to 0.8 mol of methyl groups/mol of this peptide. Of the four synthetic peptides, only the L-isohexapeptide competitively inhibits the methylation of ovalbumin by the erythrocyte enzyme. This peptide also acts as a substrate for both of the purified protein carboxyl methyltransferases I and II which have been previously isolated from bovine brain (Aswad, D. W., and Deight, E. A. (1983) J. Neurochem. 40, 1718-1726). The L-isoaspartyl hexapeptide represents the first defined synthetic substrate for a eucaryotic protein carboxyl methyltransferase. These results demonstrate that these enzymes can not only catalyze the formation of methyl esters at the beta-carboxyl groups of D-aspartyl residues but can also form esters at the alpha-carboxyl groups of isomerized L-aspartyl residues. The implications of these findings for the metabolism of modified proteins are discussed.     

Stoichiometric methylation of porcine adrenocorticotropin by protein carboxyl methyltransferase requires deamidation of asparagine 25. Evidence for methylation at the alpha-carboxyl group of atypical L-isoaspartyl residues

The enzymatic methylation of porcine adrenocorticotropin (ACTH) in both its native form and a form which is deamidated at asparagine 25 has been compared using purified protein carboxyl methyltransferase from bovine brain. Incubation of deamidated ACTH with high concentrations of methyltransferase resulted in near stoichiometric levels of methyl incorporation (78 mol %), while the methylation of native ACTH was highly substoichiometric (3-12 mol %). The Km and Vmax for deamidated ACTH were 1.9 microM and 11,200 pmol/min/mg, respectively, making this peptide the most specific substrate known for the mammalian methyltransferase. Deamidation of asparagine 25 leads to the formation of an atypical isopeptide bond in which the resulting aspartyl residue is linked to the adjacent glycine 26 via its side-chain beta-carboxyl group rather than the usual alpha-carboxyl linkage (Gráf, L., Bajusz, S., Patthy A., Barát, E., and Cseh, G. (1971) Acta Biochim. Biophys. Acad. Sci. Hung. 6, 415-418; Bornstein, P., and Balian, G. (1977) Methods Enzymol. 47, 132-145). A synthetic isopeptide (beta-linked) analog of deamidated ACTH serves as a highly effective substrate for the methyltransferase, but the corresponding normal (alpha-linked) peptide does not, indicating that this enzyme selectively recognizes the alpha-carboxyl group of atypical beta-linked L-aspartyl residues (see also accompanying paper (Murray, E.D., Jr., and Clarke, S. (1984) J. Biol. Chem. 259, 10722-10732]. Methylation of atypical beta-linked L-aspartyl residues resulting from deamidation can account for previous observations that in vitro protein carboxyl methylation in mammalian systems almost always occurs with a low stoichiometry and that these protein methyl esters are considerably less stable than most chemically formed protein methyl esters.     

Fragmentation of isoaspartyl peptides and proteins by carboxypeptidase Y: release of isoaspartyl dipeptides as a result of internal and external cleavage

Isoaspartate-containing versions of sea urchin sperm-activating peptide, delta sleep-inducing peptide, and lactate dehydrogenase (231-242) were cleaved at internal sites by carboxypeptidase Y. Cleavage occurred between the isoaspartate and the preceding amino acid, and it was accompanied by sequential digestion of amino acids from the two resulting carboxyl termini. Because the isoaspartyl bonds were not cleaved, isoaspartyl dipeptides were among the final products. The rate of release of isoaspartyl dipeptides was different for the three peptides, a 24-h digestion yielding 0.32 mol of isoaspartylglycine/mol of isoaspartyl sperm-activating peptide, 0.50 mol of isoaspartylalanine/mol of isoaspartyl delta sleep-inducing peptide, and 1.15 mol of isoaspartylserine/mol of isoaspartyl lactate dehydrogenase (231-242). The different rates could be explained by the slow cleavage of amino acids preceded by glycine. Isoaspartyl dipeptides were not detected in digests of the corresponding aspartate- or asparagine-containing forms of the peptides. Release of isoaspartyl dipeptides by carboxypeptidase Y was used to demonstrate the presence of isoaspartylglycine sequences in deamidated adrenocorticotropin (0.54 mol/mol), in a mixture of trypic fragments of base-treated calmodulin (0.20 mol/mol), and in a mixture of tryptic fragments of base-treated triosephosphate isomerase (0.08 mol/mol). These results confirm earlier work suggesting that isoaspartylglycine formation is prevalent in proteins exposed to alkaline conditions. They also provide a methodology that should prove useful in the characterization of natural substrates for protein L-isoaspartyl methyltransferase.     

Repair of isopeptide bonds by protein carboxyl O-methyltransferase: seminal ribonuclease as a model system

Previous work has shown that in the peptide segment 62-76 of naturally deamidated alpha subunit of bovine seminal ribonuclease (BS-RNase) the alpha-carboxyl group of iso-Asp67 is selectively methylated by S-adenosylmethionine:protein carboxyl O-methyltransferase [Di Donato, A., Galletti, P., & D'Alessio, G. (1986) Biochemistry 25, 8361-8368]. In the present study this reaction has been characterized, by using the tryptic segment 62-76 of the protein chain (peptide alpha 16). The peptide is stoichiometrically methyl esterified with a Km of 6.17 microM and a Vmax of 19.56 nmol min-1 mg-1, and the product of demethylation has been identified as the cyclic succinimidyl derivative of iso-Asp67-Gly68. The cleavage of the succinimidyl ring yields two isomeric peptides containing an aspartyl residue (peptide alpha 17) and an isoaspartyl residue (peptide alpha 16). On the basis of these results conditions were defined in which repeated cycles of methylation-demethylation led to an effective conversion of peptide alpha 16 into peptide alpha 17, a process that can be interpreted as the repair of an altered isopeptide bond. When the methyl esterification reaction was studied on the native dimeric isoenzymes of seminal RNase and on catalytically active monomeric derivatives, including a stabilized alpha-type subunit, the results of these experiments showed that none of the protein forms were substrates for the methyltransferase. Only the unfolded alpha-type subunit was methylated to a stoichiometric extent. These results indicate that the repair of altered isopeptide bonds is chemically feasible in peptides but is hindered in the case of seminal RNase by its three-dimensional structure.     

Detection and control of aspartimide formation in the synthesis of cyclic peptides

Extensive two-dimensional NMR analysis was employed to characterize the structural identity of the macrocyclic peptide lactam and the imide analog, a major side reaction product when allyl ester was used to protect the side chain of aspartic acid. A straightforward protocol modification was developed to minimize aspartimide formation during the synthesis of cyclic peptides.     

Specific recognition of altered polypeptides by widely distributed methyltransferases

Protein carboxyl methyltransferase activity has been detected in extracts prepared from bacterial cells (Salmonella typhimurium), amphibian (Xenopus laevis) oocytes, and transformed mammalian cell lines. This activity appears to specifically recognize altered aspartyl residues based on the observation that the synthetic peptide L-Val-L-Tyr-L-Pro-L-isoAsp-Gly-L-Ala is a good methyl-accepting substrate for the methyltransferase activity, but that the corresponding peptide containing a normal L-aspartyl residue is not. These activities are similar to those of the previously described human erythrocyte and bovine brain enzymes which catalyze the formation of polypeptide D-aspartyl beta-methyl esters and L-isoaspartyl alpha-methyl esters. The wide distribution of these enzymatic activites suggest that the methylation of atypical proteins is an essential function in cells.     

Synthesis of cyclic peptides on solid support. Application to analogs of hemagglutinin of influenza virus

In order to mimic a well-known loop structure (site A) of the hemagglutinin of influenza virus, a series of cyclic peptides derived from the region 139-147 were synthesized. The lactam analogs cyclised between the N-terminus Cys 139 and the beta-carboxyl of aspartic acid 148 (small loop) or the epsilon-NH2 of lysine 148 via succinimidyl linker (large loop) were synthesized by the solid phase method. Cyclisation was directly performed on the solid support prior to final cleavage of the peptide. We describe two protection schemes which allow us to obtain different loop sizes derived from the same sequence. Eight of the analogs contained relatively large ring structures (up to 38 membered). For protection of the side chain of aspartic acid in combination with N-alpha-Fmoc protection, the cyclohexyl ester was more satisfactory than the benzyl ester with respect to imide formation. When the rate of cyclodimerisation, as a function of resin substitution, was compared to the rate of cyclic monomer formation, it was found that dimerisation was proportional to the charge of the resin. Furthermore, a comparison of the recently reported BOP reagent over the classical DIPC/HOBt method for the cyclisation reaction shows that in our case the reaction proceeded more rapidly by the BOP procedure although it gave a less pure crude product.     

Cyclic peptides. XXVI. Synthesis of AM-toxin II analogs by cyclization through ester bond formation

In order to explore the route for the preparation of cyclodepsipeptide by cyclization through an ester bond formation, two analogs of AM-toxin II, cyclotetradepsipeptide, were synthesized. As a preliminary experiment, synthesis of [L-Phe3, L-Ser(Bzl)4]-AM-toxin II, containing L-Phe and L-Ser(Bzl) in place of L-App (2-amino-5-phenyl-pentanoic acid) and delta Ala (alpha, beta-dehydroalanine), respectively, was attempted. Cyclization of H-L-Hmb-L-Phe-L-Ser(Bzl)-L-Ala-OH in CH2Cl2 at 10 mM concentration using water-soluble carbodiimide (EDC) and 4-dimethylaminopyridine (DMAP) successfully gave a cyclic monomer in 16% yield. Cyclization of H-L-Hmb-L-App-L-Ser(Bzl)-L-Ala-OH under the same conditions also afforded a cyclic monomer, [L-Ser(Bzl)4]AM-toxin II, in 19% yield. Analytical parameters of these cyclic monomers obtained were identical to those of the authentic samples obtained by cyclization through a peptide bond formation.     

Identification of isoaspartyl-containing sequences in peptides and proteins that are usually poor substrates for the class II protein carboxyl methyltransferase

We have found that a chicken egg lysozyme derivative (beta-101-lysozyme) containing an L-isoaspartyl residue at position 101 has a Km for methylation by the human erythrocyte L-isoaspartyl/D-aspartyl protein methyltransferase (EC 2.1.1.77) of 183 microM, about 30 times higher than that expected from previous studies with isoaspartyl-containing peptides. In the course of investigating the reasons for this poor enzyme recognition, we found that charged residues on the carboxyl side of isoaspartyl residues had a large effect on the affinity of the enzyme for synthetic peptides. This is best illustrated by the lysozyme-related peptide YVSisoDGDG, which has a Km for methylation of 469 microM. When the penultimate aspartyl residue is replaced by a cysteinyl residue, the Km drops to 4.6 microM, comparable to other peptides of similar size. Furthermore, replacing it with a cysteic acid residue results in a Km of 104 microM, suggesting that a negative charge at this position may lead to a weaker affinity of the peptide substrate for the methyltransferase. Assays with additional synthetic peptides indicate that moving the negative charge to the first or third residue on the carboxyl side of the isoaspartyl residue has a similar but less severe effect in reducing its affinity for the methyltransferase. Enzymatic methylation has recently been proposed to be the first step in the conversion of abnormal isoaspartyl residues to aspartyl residues. The results reported here, however, along with previous evidence that protein tertiary structure can inhibit isoaspartyl methylation, suggest that only a subclass of damaged sites are capable of efficiently entering a putative repair pathway; the sites not recognized by the methyltransferase may accumulate in vivo.     

Origin of bombesin-like peptides in human fetal lung

Four different forms of bombesin-like immunoreactive peaks were detected in extracts of human fetal lung by the use of reversed-phase high performance liquid chromatography (HPLC). Peaks I, II, III and IV, (increasing retention time), were eluted using a 14-38% of acetonitrile gradient containing 0.1% trifluoroacetic acid (TFA). Peak II was the major material found in the extract of human fetal lung obtained at 16-20 weeks gestation. None of the four compounds contained in the eluted peaks had the same retention time as amphibian bombesin or porcine gastrin releasing peptide (GRP). On reversed-phase HPLC using two different solvent systems TFA or heptafluorobutyric acid (HFBA) as a hydrophobic counter ion, and in gel filtration chromatography, the chromatographic behavior of the main peak (peak II) was the same as that of the carboxyl terminal fragments of GRP, GRP18-27 or GRP19-27. This suggested that the peptide(s) in peak II resembled in composition the carboxy terminal 9 or 10 amino acids of porcine GRP. Following tryptic digestion the material in peak IV was converted to the more polar compound present in peak II. Two other peptide peaks were eluted close to peak II and these were presumed to be a modification of this main peak. One of the possible biosynthetic steps in the formation of bombesin-like peptides in human fetal lung could be a tryptic conversion of a less polar peptide to a more polar form (peak IV to II).