Decisive structural determinants for the interaction of proline derivatives with the intestinal H+/peptide symporter.

To elucidate the decisive structural factors relevant for dipeptide-carrier interaction, the affinity of short amide and imide derivatives for the intestinal H+/peptide symporter (PEPT1) was investigated by measuring their ability to inhibit Gly-Sar transport in Caco-2 cells. Dipeptides with proline or alanine in the C-terminal position displayed affinity constants (Ki) of 0.15-1.2 mM and 0.08-9.5 mM, respectively. There was no clear relationship between hydrophobicity, size or ionization status of the N-terminal amino acid and the affinity of the dipeptides. However, analyzing the individual peptide bond conformations of Xaa-Pro dipeptides, a striking correlation between the cis/trans ratios (trans contents 24-70%) and the affinity constants was observed. After correcting the Ki values for the incompetent cis isomers, the Ki corr values of most dipeptides were in a small range of 0.1-0.16 mM. This result revealed the decisive role of peptide bond conformation even for a transport protein that is quite promiscuous in substrate translocation. When measuring affinity constants of Xaa-Pro and Xaa-Sar dipeptides, the cis/trans ratios cannot be ignored. Lower affinities of Lys-Pro, Arg-Pro and Pro-Pro indicate that additional molecular factors affect their binding at PEPT1. The Ki values obtained for the corresponding Xaa-Ala dipeptides support this conclusion. Potential substrates or inhibitors of peptide transport were found among Xaa-piperidides and Xaa-thiazolidides. Dipeptides with N-terminal proline displayed a very diverse affinity profile. However, in contrast to current knowledge, several Pro-Xaa dipeptides such as Pro-Leu, Pro-Tyr and Pro-Pro are recognized by PEPT1 with appreciable affinities. Binding seems mainly determined by the hydrophobicity of the C-terminal amino acid and the rigidity of the structure.     

Effects of secondary interactions on the kinetics of peptide and peptide ester hydrolysis by tissue kallikrein and trypsin

Kinetic constants for the hydrolysis by porcine tissue beta-kallikrein B and by bovine trypsin of a number of peptides related to the sequence of kininogen (also one containing a P2 glycine residue instead of phenylalanine) and of a series of corresponding arginyl peptide esters with various apolar P2 residues have been determined under strictly comparative conditions. kcat and kcat/Km values for the hydrolysis of the Arg-Ser bonds of the peptides by trypsin are conspicuously high. kcat for the best of the peptide substrates, Ac-Phe-Arg-Ser-Val-NH2, even reaches kcat for the corresponding methyl ester, indicating rate-limiting deacylation also in the hydrolysis of a peptide bond by this enzyme. kcat/Km for the hydrolysis of the peptide esters with different nonpolar L-amino acids in P2 is remarkably constant (range 1.7), as it is for the pair of the above pentapeptides with P2 glycine or phenylalanine. kcat for the ester substrates varies fivefold, however, being greatest for the P2 glycine compounds. Obviously, an increased potential of a P2 residue for interactions with the enzyme lowers the rate of deacylation. In contrast to results obtained with chymotrypsin and pancreatic elastase, trypsin is well able to tolerate a P3 proline residue. In the hydrolysis of peptide esters, tissue kallikrein is definitely superior to trypsin. Conversely, peptide bonds are hydrolyzed less efficiently by tissue kallikrein and the acylation reaction is rate-limiting. The influence of the length of peptide substrates is similar in both enzymes and indicates an extension of the substrate recognition site from subsite S3 to at least S'3 of tissue kallikrein and the importance of a hydrogen bond between the P3 carbonyl group and Gly-216 of the enzymes. Tissue kallikrein also tolerates a P3 proline residue well. In sharp contrast to the behaviour of trypsin is the very strong influence of the P2 residue in tissue-kallikrein-catalyzed reactions. kcat/Km varies 75-fold in the series of the dipeptide esters with nonpolar L-amino acid residues in P2, a P2 glycine residue furnishing the worst and phenylalanine the best substrate, whereas this exchange in the pentapeptides changes kcat/Km as much as 730-fold. This behaviour, together with the high value of kcat/Km for Ac-Phe-Arg-OMe of 3.75 X 10(7) M-1 s-1, suggests rate-limiting binding (k1) in the hydrolysis of the best ester substrates.(ABSTRACT TRUNCATED AT 400 WORDS)     

Involvement of prolines-114 and -117 in the slow refolding phase of ribonuclease A as determined by isomer-specific proteolysis

Using the method of isomer-specific proteolysis (ISP), the cis-trans nature of the peptide bonds involving prolines-114 and -117 in ribonuclease (RNase) has been investigated. These studies involve the pretreatment of RNase first with either a short pepsin pulse or a short mercaptoethanol pulse to irreversibly unfold the protein and then with a short chymotrypsin pulse to quickly cleave the Tyr115-Val116 bond so that the chain is suitably trimmed for the subsequent stereospecific cleavage either by aminopeptidase P, to investigate proline-117, or by a proline-specific endopeptidase, to investigate proline-114. The most reasonable interpretation of our results suggests that proline-117 is essentially 100% trans in both the native and unfolded states, so it apparently makes no direct contribution to the slow refolding kinetics of RNase. It is also determined that proline-114 is 100% cis in native RNase and ca. 95% cis in reversibly unfolded RNase so only 5% of the unfolded RNase can be rate limited by trans to cis isomerization of proline-114 during refolding. Careful spectroscopic studies of refolding show that the smallest and slowest of the refolding phases, the ct phase, has the proper amplitude (5%), relaxation time (400 s at 10 degrees C), and activation energy (17 kcal) for a phase that is rate limited by the trans to cis isomerization of proline-114. Measurements of the kinetics of binding of cytidine 2'-monophosphate during refolding further show that RNase does not become active until proline-114 has isomerized to the native cis configuration. It is concluded that none of the three prolines thus far examined (i.e., prolines-93, -114, and -117) by the ISP method is involved in the formation of a fully active, nativelike intermediate which has "incorrect" proline isomers. The specific structural process which is responsible for the largest of the three slow refolding phases, the XY phase, is still undetermined. Although ISP results on proline-42 are not yet available, it seems possible that this slow phase may be rate limited by a process other than proline isomerization. In unrelated studies, results from chymotrypsin hydrolyses of several short peptides containing the sequence -X-Y-Pro- show that cleavage of an active X-Y bond is very slow when it is immediately adjacent on the amino side of a proline peptide bond. Thus, chymotrypsin cleavage may not be generally useful as the analytical step in isomer-specific proteolysis.     

Evidence that the substrate backbone conformation is critical to phosphorylation by p42 MAP kinase

The effect of prolyl bond isomers on the substrate recognition capabilities of various endoproteases may be investigated in a reaction where both cis/trans isomers co-exist. Here we address the question of whether enzyme reactions at the side chain of an amino acid preceding proline proceed through an isomer specific pathway. The proline-directed p42 mitogen-activated protein kinase (ERK2) was used to phosphorylate the serine side chain in Pro-Arg-Ser-Pro-Phe-4-nitroanilide under conditions where different amounts of cis prolyl isomer of the substrate were present. Initial phosphorylation rates were calculated ranging between zero at 100% cis isomer and around 60 pM/min at the equilibrium content of 83.5% trans isomer. In the presence of the peptidyl-prolyl cis/trans isomerase human hFKBP12 (500 nM), cis/trans isomerization proceeds rapidly, permitting the maximal phosphorylation rate to be observed in the dead time of the experiment. Results show that correct signature sequences are not sufficient to render potential substrates reactive to proline-directed enzymatic phosphorylations, but that the conformational state of the peptide bond following serine (threonine) is a critical determinant. Therefore, catalysis by peptidyl-prolyl cis/trans isomerases may add a new level of control to intracellular protein phosphorylations.     

A conserved cis peptide bond is necessary for the activity of Bowman-Birk inhibitor protein

The Bowman-Birk inhibitor (BBI) family of protease inhibitors has an inhibitory region comprising a disulfide-linked nine-residue loop that adopts the characteristic canonical motif found in many serine protease inhibitors. A unique feature of the BBI loop is the presence of a cis peptide bond at the edge of the inhibitory loop. BBI-related protein fragments that encapsulate this loop retain the structure and inhibitory activity of the parent protein. The most common BBI loop sequence has a proline-proline element with a cis-trans geometry at P3'-P4'. We have examined this element by analysis of the inhibitory activity and structure for a series of synthetic fragments where each of these proline residues has been systematically replaced with alanine. The results show that only when a proline is present at P3' are potent inhibition and a cis peptide bond at that position in the solution structure observed, suggesting that this conformation is required for biological activity. Though a P4' proline is not essential for activity, it effectively stabilizes the cis conformation at P3' by suppressing alternative conformations. This is most evident from the Pro-Ala variant, which comprises a 1:1 mixture of slowly exchanging and structurally different cis and trans isomers. Monitoring the action of trypsin on this mixture by NMR shows that this protease interacts selectively with the cis P3' structure, providing direct evidence for the link between activity and the nativelike structure of the cis isomer. This is, to the best of our knowledge, the first example where cis isomer selectivity can be demonstrated for a proteinase.     

A functional proline switch in cytochrome P450cam

The two-protein complex between putidaredoxin (Pdx) and cytochrome P450(cam) (CYP101) is the catalytically competent species for camphor hydroxylation by CYP101. We detected a conformational change in CYP101 upon binding of Pdx that reorients bound camphor appropriately for hydroxylation. Experimental evidence shows that binding of Pdx converts a single X-proline amide bond in CYP101 from trans or distorted trans to cis. Mutation of proline 89 to isoleucine yields a mixture of both bound camphor orientations, that seen in Pdx-free and that seen in Pdx-bound CYP101. A mutation in CYP101 that destabilizes the cis conformer of the Ile 88-Pro 89 amide bond results in weaker binding of Pdx. This work provides direct experimental evidence for involvement of X-proline isomerization in enzyme function.     

Direct NMR evidence that prolidase is specific for the trans isomer of imidodipeptide substrates

The in vitro hydrolysis by porcine kidney prolidase of the imidodipeptide L-alanyl-L-proline was monitored by using 1H high-resolution NMR spectroscopy. The dipeptide exists as an equilibrium mixture of isomers with cis or trans conformation about the peptide bond. The 13C and 1H NMR spectra of the dipeptide displayed well-resolved resonances for each isomer. Inversion-transfer NMR spectroscopy, with a recently developed pulse sequence, was used with a range of temperatures to calculate the unitary rate constants for the exchange between isomers. A new analytical procedure was introduced for directly obtaining estimates of the unitary rate constants from inversion-transfer data. Arrhenius analysis yielded an activation energy for the isomerization of 87.0 +/- 4.1 kJ mol-1. 1H NMR time courses of the prolidase-catalyzed hydrolysis of L-alanyl-L-proline showed a faster removal of the trans isomer as the [enzyme]/[substrate] ratio was increased. The transient-kinetic information coupled with the steady-state kinetic parameters of the enzyme was used to develop two possible models of the overall hydrolytic reaction. Numerical integration of the relevant differential equations using the experimentally determined rate constants gave simulated progress curves that enabled selection of one of the proposed schemes as being the most likely; this proposal entailed absolute specificity of prolidase for the trans isomer of L-alanyl-L-proline. Finally, on the basis of the present work, and information from the literature, we have proposed a new model of the active site of the enzyme.     

On the biocatalytic cleavage of silicon–oxygen bonds: A substrate structural approach to investigating the cleavage of protecting group silyl ethers by serine-triad hydrolases

The biotransformation of compounds containing silicon has recently been a subject of much interest. In this study, a variety of commercially available serine hydrolases were tested for their ability to catalyse the hydrolysis of the silicon–ether bond in a variety of silyl ethers. The hydrolysis of trimethylethoxysilane in buffer was not found to be accelerated by the presence of trypsin, chymotrypsin, or a variety of other lipase and protease enzymes. Cleavage of a range of alternative silyl ether substrates, including a trimethylsilyl (TMS) ether, by these hydrolases was also not observed, but, interestingly, only two of the enzymes tested were able to cleave a t-butyl α,α,α-carboxylate that was approximately isosteric with the TMS-protected substrate. This suggests that the cleavage of Si–O bonds by serine hydrolases, such as the cathepsin homolog silicatein-α, may be in part limited by steric effects, as the reactive centre in the substrate is always, by analogy to C-centred substrates, tertiary, and thus inherently sterically demanding regardless of the putative catalytic competence of the enzymes.     

New class of sensitive and selective fluorogenic substrates for serine proteinases. Amino acid and dipeptide derivatives of rhodamine.

A series of dipeptide derivatives of Rhodamine, each containing an arginine residue in the P1 position and one of ten representative benzyloxycarbonyl (Cbz)-blocked amino acids in the P2 position, has been synthesized, purified and characterized as substrates for serine proteinases. These substrates are easily prepared with high yields. Cleavage of a single amide bond converts the non-fluorescent bisamide substrate into a highly fluorescent monoamide product. Macroscopic kinetic constants for the interaction of these substrates with bovine trypsin, human and dog plasmin, and human thrombin are reported. Certain of these substrates exhibit extremely large specificity constants. For example, the kcat./Km for bovine trypsin with bis-(N-benzyloxycarbonylglycyl-argininamido)-Rhodamine [(Cbz-Gly-Arg-NH)2-Rhodamine] is 1 670 000 M-1 X S-1. Certain of these substrates are also highly selective. For example, the most specific substrate for human plasmin, (Cbz-Phe-Arg-NH2)-Rhodamine, is not hydrolysed by human thrombin, and the most specific substrate for human thrombin, (Cbz-Pro-Arg-NH)2-Rhodamine, is one of the least specific substrates for human plasmin. Comparison of the kinetic constants for hydrolysis of the dipeptide substrates with that of the single amino acid derivative, (Cbz-Arg-NH)2-Rhodamine, indicates that selection of the proper amino acid residue in the P2 position can effect large increases in substrate specificity. This occurs primarily as a result of an increase in kcat. as opposed to a decrease in Km and, in certain cases, is accompanied by a large increase in selectivity. Because of their high degree of sensitivity and selectivity, these Rhodamine-based dipeptide compounds should be extremely useful substrates for studying serine proteinases.     

Substrate specificity and inhibition of human kallikrein-related peptidase 3 (KLK3 or PSA) activated with sodium citrate and glycosaminoglycans

We report the enzymatic properties and substrate specificity of human recombinant KLK3 in the presence of glycosaminoglycans (GAGs) and sodium citrate. This salt is highly concentrated in prostate and in its presence KLK3 had a similar hydrolytic efficiency as chymotrypsin. In contrast to the latter peptidase, KLK3 activated by sodium citrate efficiently hydrolyzed substrates containing R, H and P at the P1 position. Activated KLK3 also cleaved peptides derived from the bradykinin domain of human kininogen at the same sites as human kallikrein KLK1, but presented low kininogenase activity. Angiotensin I has several sites for hydrolysis by KLK3; however, it was cleaved only at the Y-I bond (DRVY↓IHPFHL). Sodium citrate modulated KLK3 conformation as observed by alterations to the intrinsic fluorescence of phenylalanines and tryptophans. Activated KLK3 was reversibly inhibited by Z-Pro-Prolinal and competitively inhibited by ortho-phenantroline. Together, these are noteworthy observations for the future design of specific non-peptide inhibitors of KLK3 and to find natural substrates.     

Kinetic and crystallographic analysis of mutant Escherichia coli aminopeptidase P: insights into substrate recognition and the mechanism of catalysis

Aminopeptidase P (APPro) is a manganese-dependent enzyme that cleaves the N-terminal amino acid from polypeptides where the second residue is proline. APPro shares a similar fold, substrate specificity, and catalytic mechanism with methionine aminopeptidase and prolidase. To investigate the roles of conserved residues at the active site, seven mutant forms of APPro were characterized kinetically and structurally. Mutation of individual metal ligands selectively abolished binding of either or both Mn(II) atoms at the active site, and none of these metal-ligand mutants had detectable catalytic activity. Mutation of the conserved active site residues His243 and His361 revealed that both are required for catalysis. We propose that His243 stabilizes substrate binding through an interaction with the carbonyl oxygen of the requisite proline residue of a substrate and that His361 stabilizes substrate binding and the gem-diol catalytic intermediate. Sequence, structural, and kinetic analyses reveal that His350, conserved in APPro and prolidase but not in methionine aminopeptidase, forms part of a hydrophobic binding pocket that gives APPro its proline specificity. Further, peptides in which the required proline residue is replaced by N-methylalanine or alanine are cleaved by APPro, but they are extremely poor substrates due to a loss of interactions between the prolidyl ring of the substrate and the hydrophobic proline-binding pocket.     

Synthesis and hydrolysis by cathepsin B of fluorogenic substrates with the general structure benzoyl-X-ARG-MCA containing non-natural basic amino acids at position X

We synthesized one series of fluorogenic substrates for cathepsin B derived from the peptide Bz-F-R-MCA (Bz=benzoyl, MCA=7-methyl-coumarin amide) substituting Phe at the P(2) position by non-natural basic amino acids that combine a positively charged group with aromatic or aliphatic radicals at the same side chain, namely, 4-aminomethyl-phenylalanine, 4-guanidine-phenylalanine, 4-aminomethyl-N-isopropyl-phenylalanine, 3-pyridyl-alanine, 4-piperidinyl-alanine, 4-aminomethyl-cyclohexyl-alanine, 4-aminocyclohexyl-alanine, and N(im)-dimethyl-histidine. Bz-F-R-MCA was the best substrate for cathepsin B but also hydrolyzed Bz-R-R-MCA with lower efficiency, since the protease accepts Arg at S(2) due to the presence of Glu(245) at the bottom of this subsite. The presence of the basic non-natural amino acids at the P(2) position of the substrate partially restored the catalytic efficiency of cathepsin B. All the kinetic parameters for hydrolysis of the peptides described in this paper are in accordance with the structures of the S(2) pocket previously described. In addition, the substrate with 4-aminocyclohexyl-alanine presented the highest affinity to cathepsin B although the peptide was obtained from a mixture of cis/trans isomers of the amino acid and we were not able to separate them. For comparison all the obtained substrates were assayed with cathepsin L and papain.     

Substrate-based design of reversible Pin1 inhibitors

Human Pin1, a peptidyl-prolyl cis/trans isomerase with high specificity to -Ser/Thr(PO(3)H(2))-Pro- motifs, is required for cell cycle progression. In an effort to design reversible Pin1 inhibitors by using a substrate structure based approach, a panel of peptides were applied to systematically analyze the minimal structural requirements for Pin1 substrate recognition. Pin1 catalysis (k(cat)/K(m) < 5 mM(-1) s(-1)) for Ala-Pro, Ser-Pro, and Ser(PO(3)H(2))-Pro was detected using direct UV-visible spectrophotometric detection of prolyl isomerization, while weak competitive inhibition of Pin1 by these dipeptides was observed (K(i) > 1 mM). Substrates with chain lengths extending from either the P2 to P1' or the P1 to P2' subsite gave k(cat)/K(m) values of 100 mM(-1) s(-1) for Ala-Ser(PO(3)H(2))-Pro and 38 mM(-1) s(-1) for Ser(PO(3)H(2))-Pro-Arg. For both Pin1 and its yeast homologue Ess1, the optimal subsite recognition elements comprise five amino acid residues with the essential Ser(PO(3)H(2)) in the middle position. The resulting substrate Ac-Ala-Ala-Ser(PO(3)H(2))-Pro-Arg-NH-4-nitroanilide possesses a very low cis/trans interconversion barrier in the presence of either Pin1 or Ess1, with k(cat)/K(m) = 9300 mM(-1) s(-1) and 12000 mM(-1) s(-1), respectively. The D-Ser(PO(3)H(2)) residue preceding proline could serve as a substrate-deactivating determinant without compromising ground state affinity. Similarly, substitution of the amide bond preceding proline with a thioxo amide bond produces a potent inhibitor. Pin1 is reversibly inhibited by such substrate analogue inhibitors with IC(50) values in the low micromolar range. The D-amino acid containing inhibitor also exhibits remarkable stability against phosphatase activity in cell lysate.     

A Novel Type of Substrate Specificity of Rice BAPAase (Benzoyl-L-arginine p-nitroanilide Hydrolase) with Mixed Endopeptidase and Carboxypeptidase

The substrate specificity of rice embryo benzoyl-L-argininep-nitroanilide hydrolase (BAPAase) was examined. No endopeptidaseactivity toward protein substrates was detectable. Small peptides(less than 8 residues) and amide, ester substrates, however,were hydrolyzed very well at the carboxyl side of the lysineor arginine residue. No other peptide bond was hydrolyzed. TheN-terminal arginine of the substrates was released very slowly.Peptides with lysine or arginine penultimate to the C-terminalposition were hydrolyzed well and released an amino acid. Theoxidized insulin B chain (30 residues) was cleaved very slowlyat the C-terminal Lys-Ala bond, whereas an Arg-Gly bond at aninner position was not cleaved. The hydrolytic rate increasedafter the chain length was shortened by chymotryptic digestion.These results show that the rice embryo BAPAase is a novel enzymewhich has mixed endopeptidase-carboxypeptidase activity towardthe Arg-X and Lys-X bonds of small peptides, a characteristicintermediate between trypsin and serine carboxypeptidase. Thisenzyme may act in the breakdown of small peptides that havephysiological functions. (Received May 26, 1984; Accepted August 29, 1984)     

Reactivity of bovine blood coagulation factor IXa beta, factor Xa beta, and factor XIa toward fluorogenic peptides containing the activation site sequences of bovine factor IX and factor X

The published activation site sequences of bovine factors IX and X have been utilized to synthesize a number of peptides specifically designed respectively as substrates for bovine factors XIa and IXa beta. The substrates contain a fluorophore (2-aminobenzoyl group, Abz) and a quenching group (4-nitrobenzylamide, Nba) that are separated upon enzymatic hydrolysis with a resultant increase in fluorescence that was utilized to measure hydrolysis rates. Factor XIa cleaved all of the peptides bearing factor IX activation site sequences with Abz-Glu-Phe-Ser-Arg-Val-Val-Gly-Nba having the highest kcat/KM value. The kinetic behavior of factor XIa toward the synthetic peptide substrate indicates that it has a minimal extended substrate recognition site at least five residues long spanning S4 to S1' and has favorable interactions over seven subsites. The hexapeptide Abz-Glu-Phe-Ser-Arg-Val-Val-Nba was the most specific factor XIa substrate and was not hydrolyzed by factors IXa beta or Xa beta or thrombin. Factor IXa beta failed to hydrolyze any of the synthetic peptides bearing the activation site sequence of factor X. This enzyme slowly cleaved four hexa- and heptapeptide substrates with factor IX activation site sequences extending from P4 or P3 to P3'. Factor Xa beta poorly hydrolyzed all but one of the factor XIa substrates and failed to cleave any of the factor IXa beta substrates. Thrombin failed to hydrolyze any of the peptides examined while trypsin, as expected, was highly reactive and not very specific. Phospholipids had no effect on the reactivity of either factors IXa beta or Xa beta toward synthetic substrates. Both factor IXa beta and Xa beta cleaved the peptide substrates at similar rates to their natural substrates under comparable conditions. However the rates were substantially lower than optimum activation rates observed in the presence of Ca2+, phospholipids, and protein cofactors. In the future, it may be useful to investigate synthetic substrates that can bind to phospholipid vesicles in the same manner as the natural substrates for factors IXa beta and Xa beta.     

Lack of evidence for a tetrahedral intermediate in the hydrolysis of nitroanilide substrates by serine proteinases. Subzero-temperature stopped-flow experiments

We have used a stopped-flow apparatus to reinvestigate reports, based on the observation of "burst" kinetics, of an intermediate prior to the acyl-enzyme complex in hydrolysis reactions of anilides catalyzed by trypsin and elastase [M. W. Hunkapiller, M. D. Forgac and J. H. Richards (1976) Biochemistry 15, 5581-5588; D. D. Petkov (1978) Biochim. Biophys. Acta, 523, 538-541; A. L. Fink and P. Meehan (1979) Proc. Natl Acad. Sci. USA, 76, 1566-1569; P. Compton and A. L. Fink (1980) Biochem. Biophys. Res. Commun. 93, 427-431]. We studied the hydrolysis of several anilide substrates by bovine and porcine trypsin and porcine elastase between -30 degrees C and 20 degrees C. In no case did we record true "burst" kinetics. We show that confusion spectral changes can arise from incomplete mixing, thermal gradients, or heterogeneity of the substrate. We conclude that there is no solid spectroscopic evidence at present for the existence of a tetrahedral intermediate in the hydrolysis of amides by serine proteinases. The substrate N-acetyl-L-alanyl-L-prolyl-L-alanine 4-nitroanilide is a mixture of two isomers trans and cis about the L-alanyl-L-propyl peptide bond. It appears that elastase hydrolysis the cis isomer more rapidly than the trans isomer and this could lead to false "burst" kinetics. We describe the construction of the stopped-flow apparatus designed for cryoenzymology used for this work that has novel features and is adaptable to a variety of spectrophotometers. Solutions can be handled under anaerobic conditions. A window allows the drive syringes to be observed or exposed to light for photochemical experiments. The apparatus operates over the temperature range -35 degrees C to + 25 degrees C. The dead time is under 5 ms. A recording system is described that permits one to follow reactions over a wide time scale covering half-time of the order of several milliseconds to hours.     

Effect of N-methylation on the modulation by synthetic peptides of the activity of the complement-factor-B-derived serine proteinase CVFBb.

Although they share the active-site catalytic triad of less-specific enzymes such as trypsin and chymotrypsin, the serine proteinases of the complement and coagulation cascades each cleave a highly restricted set of substrates. Peptides with sequences similar to that at which C3 is cleaved by the alternative-pathway complement proteinase CVFBb were synthesized by solid-phase methodology and examined for their effects on the activity of this enzyme as measured by three different types of assays. It was found that a peptide methylated at the scissile bond was a far more effective inhibitor of the cleavage of the protein substrate C5 and of the lysis of guinea-pig erythrocytes by the alternative pathway than was the equivalent unmethylated peptide. Whereas the unmethylated peptide inhibited cleavage of the peptide substrate, the methylated peptide actually stimulated cleavage in this assay. This stimulation was found to be due to a 2.8-fold increase in kcat; the dissociation constant for the substrate was not altered significantly. One model consistent with this behaviour is that the binding of the activator peptide in the extended substrate-recognition region stabilizes a catalytically more active conformation of the active site. A small peptide substrate may have access to such an activated active site, whereas the larger substrate, C5, may be excluded from the site. These results demonstrate that the observed effect of a given compound on activity of an enzyme with an extended substrate-recognition region may depend upon the substrate.     

Analogues of intermediates in the action of pig kidney prolidase

Dicarboxylic acids, resembling the collected substrates for the reverse peptide bond forming reaction, were bound several orders of magnitude more tightly than substrates, products, or previously known competitive inhibitors of reactions catalyzed by pig kidney prolidase (EC 3.4.13.9), a dipeptidase that cleaves peptide bonds to the nitrogen atom of proline. Other inhibitors containing a phosphoryl or phosphonyl group in addition to a carboxyl substituent were bound even more tightly, in a manner consistent with their possible resemblance to tetrahedral intermediates in substrate hydrolysis. These included several analogues of phosphoenol pyruvate, of which the most potent was (Z)-3-bromophosphoenolpyruvate (Ki = 4.6 x 10(-9) M). Ki values were found to vary with changing pH in a manner consistent with displacement of a hydroxide ion from the active site.     

Effects of i and i+3 residue identity on cis-trans isomerism of the aromatic(i+1)-prolyl(i+2) amide bond: implications for type VI beta-turn formation

Cis-trans isomerization of amide bonds plays critical roles in protein molecular recognition, protein folding, protein misfolding, and disease. Aromatic-proline sequences are particularly prone to exhibit cis amide bonds. The roles of residues adjacent to a tyrosine-proline residue pair on cis-trans isomerism were examined. A short series of peptides XYPZ was synthesized and cis-trans isomerism was analyzed. Based on these initial studies, a series of peptides XYPN, X = all 20 canonical amino acids, was synthesized and analyzed by NMR for i residue effects on cis-trans isomerization. The following effects were observed: (a) aromatic residues immediately preceding Tyr-Pro disfavor cis amide bonds, with K(trans/cis)= 5.7-8.0, W > Y > F; (b) proline residues preceding Tyr-Pro lead to multiple species, exhibiting cis-trans isomerization of either or both X-Pro amide bonds; and (c) other residues exhibit similar values of K(trans/cis) (= 2.9-4.2), with Thr and protonated His exhibiting the highest fraction cis. beta-Branched and short polar residues were somewhat more favorable in stabilizing the cis conformation. Phosphorylation of serine at the i position modestly increases the stability of the cis conformer. In addition, the effect of the i+3 residue was examined in a limited series of peptides TYPZ. NMR data indicated that aromatic residues, Pro, Asn, Ala, and Val at the i+3 residue all favor cis amide bonds, with aromatic residues and Asn favoring more compact phi at Tyr(cis) and Ala and Pro favoring more extended phi at Tyr(cis). D-Alanine at the i+3 position particularly disfavors cis amide bonds.