Reversible inactivation of AT(2) angiotensin II receptor from cysteine-disulfide bond exchange.

Dithiothreitol (DTT) treatment of angiotensin II (Ang II) type 2 (AT(2)) receptor potentiates ligand binding, but the underlying mechanism is not known. Two disulfide bonds proposed in the extracellular domain were examined in this report. Based on the analysis of ligand affinity of cysteine (Cys, C) to alanine (Ala, A) substitution mutants, we provide evidence that Cys(35)-Cys(290) and Cys(117)-Cys(195) disulfide bonds are formed in the wild-type AT(2) receptor. Disruption of the highly conserved Cys(117)-Cys(195) disulfide bond linking the second and third extracellular segments leads to inactivation of the receptor. The Cys(35)-Cys(290) bond is highly sensitive to DTT. Its breakage results in an increased binding affinity for both Ang II and the AT(2) receptor-specific antagonist PD123319. Surprisingly, in the single Cys mutants, C35A and C290A, a labile population of receptors is produced which can be re-folded to high-affinity state by DTT treatment. These results suggest that the free -SH group of Cys(35) or Cys(290) competes with the disulfide bond formation between Cys(117) and Cys(195). This Cys-disulfide bond exchange results in production of the inactive population of the mutant receptors through formation of a non-native disulfide bond.

Ligand-independent signals from angiotensin II type 2 receptor induce apoptosis.

Conventional models of ligand-receptor regulation predict that agonists enhance the tone of signals generated by the receptor in the absence of ligand. Contrary to this paradigm, stimulation of the type 2 (AT(2)) receptor by angiotensin II (Ang II) is not required for induction of apoptosis but the level of receptor protein expression is critical. We compared Ang II-dependent and -independent AT(2) receptor signals involved in regulating apoptosis of cultured fibroblasts, epithelial cells and vascular smooth muscle cells. We found that induction of apoptosis-blocked by pharmacological inhibition of p38 mitogen-activated protein kinase and caspase 3-is a constitutive function of the AT(2) receptor. Biochemical and genetic studies suggest that the level of AT(2) receptor expression is critical for physiological ontogenesis and its expression is restricted postnatally, coinciding with cessation of developmental apoptosis. Re-expression of the AT(2) receptor in remodeling tissues in the adult is linked to control of tissue growth and regeneration. Therefore, we propose that overexpression of the AT(2) receptor itself is a signal for apoptosis that does not require the renin-angiotensin system hormone Ang II.

Angiotensin II type 1 receptor-function affected by mutations in cytoplasmic loop CD.

To explore peptide hormone-induced conformational changes, we attempted to engineer a metal-ion binding site between the cytoplasmic loops CD and EF in the angiotensin II type 1 (AT(1)) receptor. We constructed 12 double and six triple histidine mutant receptors, and tested the ability of each mutant and the wild-type to activate inositol phosphate (IP) production with and without ZnCl(2). Inhibition by ZnCl(2) in the double and triple His mutant receptors was not significant, but these mutations directly decreased the IP production. Systematic analysis of single His mutants demonstrated that the loop CD-mutants displayed 52-74% inhibition of IP production, whereas the loop EF-mutants did not affect IP production. These results indicate that the cytoplasmic loop CD-segment from Tyr(127) to Ile(130) is important for G(q/11) activation by the AT(1) receptor.

Role of transmembrane helix IV in G-protein specificity of the angiotensin II type 1 receptor.

G-protein activation by G-protein coupled receptors (GPCRs) is accomplished through proper interaction with the cytoplasmic loops rather than through sequence-specific interactions. However, the mechanism by which a specific G-protein is selected by a GPCR is not known. In the current model of GPCR activation, agonist binding modulates helix-helix interactions, which is necessary for fully determining G-protein specificity and stimulation of GDP/GTP exchange. In this study, we report that a single-residue deletion in transmembrane helix IV leads the angiotensin II type 1 (AT(1)) receptor chimera CR17 to retain GTP-sensitive high affinity for the agonist angiotensin II but results in complete inactivation of intracellular inositol phosphate production. The agonist dissociation profile of CR17 in the presence of guanosine 5'-3-O-(thio)triphosphate suggests that the activation-induced conformational changes of the chimeric receptor itself remain intact. Insertion of an alanine at position 149 (CR17triangle down149A) in this chimera rescued the inactive phenotype, restoring intracellular inositol phosphate production by the chimera. This finding suggests that in the wild-type AT(1) receptor the orientation of transmembrane helix IV-residues following Cys(149) is a key determinant for effectively distinguishing among various structurally similar G-proteins. The results emphasize that the contacts within the membrane-embedded portion of transmembrane helix IV in the AT(1) receptor is important for specific G-protein selection.

Angiotensin II type 1 and type 2 receptors bind angiotensin II through different types of epitope recognition.

OBJECTIVE: This study was designed to demonstrate that the principle of molecular recognition underlying high-affinity binding of angiotensin II to the type 2 (AT2) receptor is distinct from that of the type 1 (AT1) receptor. In general, the same functional pharmacophores in hormones are used to bind and activate different subtypes of cell surface receptors. However, the binding of angiotensin II to the AT2 receptor is distinct from that of the AT1 receptor. DESIGN AND METHODS: To systematically evaluate the effect of modification of angiotensin II side chains on binding to both the receptors, several analogs of angiotensin II were synthesized. Rat AT1 or AT2 receptors expressed in COS1 cell membranes were used to determine the affinity of analogs using radioligand competition binding experiments under equilibrium conditions. RESULTS: Modifications of all angiotensin II side chains affected binding to the AT2 receptor to nearly similar extents. In contrast, binding to the AT1 receptor was significantly affected by modifications at side chain positions 2, 4, 6 and 7. In accordance with previous observations that Tyr4- or Phe8-modified angiotensin II analogs antagonized vasoconstriction mediated exclusively by the AT1 receptor, binding to the AT1 receptor was significantly dependent on Tyr4 or Phe8 of angiotensin II whereas binding to the AT2 receptor was not. Rather surprisingly, the affinity profile of several angiotensin II analogs towards the AT2 receptor was similar to the measured affinity of the constitutively active N111G mutant AT1 receptor. CONCLUSIONS: These results suggest that the AT2-receptor pharmacophore is very distinct from that of the AT1 receptor. The AT1 receptor is in a constrained conformation and is activated only when bound to angiotensin II. In contrast, the AT2 receptor is 'relaxed' in that no single interaction is critical for binding, like the N111G mutant AT1 receptor, which is constitutively active.

Role of aromaticity of agonist switches of angiotensin II in the activation of the AT1 receptor.

We have shown previously that the octapeptide angiotensin II (Ang II) activates the AT1 receptor through an induced-fit mechanism (Noda, K., Feng, Y. H., Liu, X. P., Saad, Y., Husain, A., and Karnik, S. S. (1996) Biochemistry 35, 16435-16442). In this activation process, interactions between Tyr4 and Phe8 of Ang II with Asn111 and His256 of the AT1 receptor, respectively, are essential for agonism. Here we show that aromaticity, primarily, and size, secondarily, of the Tyr4 side chain are important in activating the receptor. Activation analysis of AT1 receptor position 111 mutants by various Ang II position 4 analogues suggests that an amino-aromatic bonding interaction operates between the residue Asn111 of the AT1 receptor and Tyr4 of Ang II. Degree and potency of AT1 receptor activation by Ang II can be recreated by a reciprocal exchange of aromatic and amide groups between positions 4 and 111 of Ang II and the AT1 receptor, respectively. In several other bonding combinations, set up between Ang II position 4 analogues and receptor mutants, the gain of affinity is not accompanied by gain of function. Activation analysis of position 256 receptor mutants by Ang II position 8 analogues suggests that aromaticity of Phe8 and His256 side chains is crucial for receptor activation; however, a stacked rather than an amino-aromatic interaction appears to operate at this switch locus. Interaction between these residues, unlike the Tyr4:Asn111 interaction, plays an insignificant role in ligand docking.

Mechanism of constitutive activation of the AT1 receptor: influence of the size of the agonist switch binding residue Asn(111).

The AT1 receptor is a G-protein-coupled receptor (GPCR); its activation from the basal state (R) requires an interaction between Asn111 in transmembrane helix III (TM-III) of the receptor and the Tyr4 residue of angiotensin II (Ang II). Asn111 to Gly111 mutation (N111G) results in constitutive activation of the AT1 receptor (Noda et al. (1996) Biochemistry, 35, 16435-16442). We show here that replacement of the AT1 receptors TM-III with a topologically identical 16-residue segment (Cys101-Val116) from the AT2 receptor induces constitutive activity, although Asn111 is preserved in the resulting chimera, CR18. Effects of CR18 and N111G mutations are neither additive nor synergistic. The conformation(s) induced in either mutant mimics the partially activated state (R'), and transition to the fully activated R conformation in both no longer requires the Tyr4 of Ang II. Both the R state of the receptor and the Tyr4 Ang II dependence of receptor activation can be reinstated by introduction of a larger sized Phe side chain at the 111 position in CR18, suggesting that the CR18 mutation generated an effect similar to the reduction of side chain size in the N111G mutation. Consistently in the native AT1 receptor, R' conformation is generated by replacement with residues smaller but not larger than the Asn111. However, size substitution of several other TM-III residues in both receptors did not affect transitions between R, R', and R states. Thus, the property responsible for Asn111 function as a conformational switch is neither polarity nor hydrogen bonding potential but the side chain size. We conclude that the fundamental mechanism responsible for constitutive activation of the AT1 receptor is to increase the entropy of the key agonist-switch binding residue, Asn111. As a result, the normally agonist-dependent R --> R' transition occurs spontaneously. This mechanism may be applicable to many other GPCRs.

Transducin-alpha C-terminal peptide binding site consists of C-D and E-F loops of rhodopsin.

The binding of heterotrimeric GTP-binding proteins (G-proteins) to serpentine receptors involves several independent contacts. We have deduced the points of interaction between mutant bovine rhodopsins and alphat-(340-350), a peptide corresponding to the C terminus of the alpha subunit (alphat) of bovine retinal G-protein, transducin. Direct binding of alphat-(340-350) to rhodopsin stabilizes the activated metarhodopsin II state (M II), consequently uncoupling the rhodopsin-transducin interaction. This peptide action requires two segments on the cytoplasmic domain of rhodopsin: the Tyr136-Val137-Val138-Val139 sequence on the C-D loop and the Glu247-Lys248-Glu249-Val250-Thr251 sequence on the E-F loop. We propose that a tertiary interaction of these two loop regions forms a pocket for binding the alphat C terminus of the transducin during light transduction in vivo. In most G-proteins, the C termini of alpha subunits are important for interaction with receptors, and, in several serpentine receptors, regions similar to those in rhodopsin are essential for G-protein activation, indicating that the interaction described here may be a generally applicable mode of G-protein binding in signal transduction.

Distinct multisite synergistic interactions determine substrate specificities of human chymase and rat chymase-1 for angiotensin II formation and degradation.

Human chymase and rat chymase-1 are mast cell serine proteases involved in angiotensin II (Ang II) formation and degradation, respectively. Previous studies indicate that both these enzymes have similar P1 and P2 preferences, which are the major determinants of specificity. Surprisingly, despite the occurrence of optimal P2 and P1 residues at the Phe8 downward arrow and Tyr4 downward arrow bonds (where downward arrow, indicates the scissile bond in peptide substrates) in Ang I (DRVYIHPFHL), human chymase cleaves the Phe8 downward arrow bond with an approximately 750-fold higher catalytic efficiency (kcat/Km) than the Tyr4 downward arrow bond in Ang II (DRVYIHPF), whereas rat chymase-1 cleaves the Tyr4 downward arrow bond with an approximately 20-fold higher catalytic efficiency than the Phe8 downward arrow bond. Differences in the acyl groups IHPF and DRVY at the Phe8 downward arrow and Tyr4 downward arrow bonds, respectively, are chiefly responsible for the preference of human chymase for the Phe8 downward arrow bond. We show that the IHPF sequence forms an optimal acyl group, primarily through synergistic interactions between neighboring acyl group residues. In contrast to human chymase, rat chymase-1 shows a preference for the Tyr4 downward arrow bond, mainly because of a catalytically productive interaction between the enzyme and the P'1 Ile5. The overall effect of this P'1 Ile interaction on catalytic efficiency, however, is influenced by the structure of the acyl group and that of the other leaving group residues. For human chymase, the P'1 Ile interaction is not productive. Thus, specificity for Ang II formation versus Ang II degradation by these chymases is produced through synergistic interactions between acyl or leaving group residues as well as between the acyl and leaving groups. These observations indicate that nonadditive interactions between the extended substrate binding site of human chymase or rat chymase-1 and the substrate are best explained if the entire binding site is taken as an entity rather than as a collection of distinct subsites.

Selective reporter expression in mast cells using a chymase promoter.

Primate alpha-chymases are mast cell neutral proteases that are involved in regulating several regulatory peptides including angiotensin II. Because of significant substrate specificity differences among the chymase group of enzymes, animal models that overexpress primate chymases are crucial for delineating the in vivo function of these enzymes. Activation of alpha-prochymase requires processing enzymes and proteoglycans found in mast cell secretory granules. Thus, the development of models overexpressing active primate chymase requires a mast cell-specific promoter. We show that the 571-base pair (bp) 5'-upstream sequence of the baboon chymase gene, which encodes an alpha-chymase, coupled to the prokaryotic lacZ gene allows the targeting of beta-galactosidase to mast cells in transgenic mice. Tissue expression of the transgene is similar to the expression of the endogenous mouse alpha-chymase mouse mast cell protease-5. A mouse mast cell line that endogenously expresses mouse mast cell protease-5 (JKras mast cells) also selectively supports the expression of this transgene. In vitro transcription studies in JKras mast cells shows the critical role of a GATA cis-regulatory motif in baboon chymase promoter, located approximately 430-bp upstream of the transcription start site. These results suggest that the 571-bp domain of the baboon chymase promoter contains most, if not all, of the mast cell-specific region of the promoter. We describe here for the first time a promoter that directs expression of transgenes specifically to mouse mast cells. This promoter should be generally applicable for dominant expression of mast cell regulatory proteins.

Preparation of lyophilised lipid rich quality control serum by isolating lipids using large scale chromatography technology.

The plasma fractionation is a technology to separate therapeutic plasma proteins. The fractionation is carried out either by solvent precipitation (ethanol) or recently by chromatography. During the process of chromatography lipids were found in waste fraction. A new lipid rich lyophilised quality control (Q.C.) sera was prepared inexpensively using this waste plasma fraction. This is probably the first attempt to prepare the Q.C. sera by large scale chromatographic method in India.

The active state of the AT1 angiotensin receptor is generated by angiotensin II induction.

In the current model of receptor activation, the given hormone is not involved in the conversion of the inactive receptor (R) to the fully active state (R*). Rather, it preferentially selects the activated receptor conformation, thereby shifting the equilibrium toward R*. The hormone angiotensin II (Ang II) contains two residues, Tyr4 and Phe8, that are essential for agonism. We show that the conserved Asn111 in transmembrane helix III of the AT1 angiotensin receptor directly interacts with the Tyr4 side chain. A decrease in the size of the Asn111 side chain induces an intermediate activated receptor conformation (R'). The Ang II analogue [Sar1,Ile4,Ile8]Ang II fully activates the N111G mutant, indicating that either the transition from R' to R* or the stabilization of the R* state requires binding by Ang II but not its Tyr4 and Phe8 side chains. In contrast, [Sar1,Ile4,Ile8]Ang II binds to but does not activate the wild-type AT1 receptor (R), suggesting that in the wild-type receptor spontaneous occurrence of R' and R* states is rare. Thus, Ang II through interactions involving Tyr4 and Phe8 induces a transition from R to R' and through unspecified interactions induces transition from R' to R* states rather than stabilizing the spontaneously generated R* state by "conformational, selection".

Modulation of GDP release from transducin by the conserved Glu134-Arg135 sequence in rhodopsin.

A superfamily of seven-transmembrane helix receptors catalyzes GDP release from heterotrimeric guanine nucleotide-binding proteins (G proteins) to initiate the intracellular signaling cascade. The photoreceptor rhodopsin is a prototypical member of the superfamily that activates the retinal G protein transducin (Gt). The cytoplasmic domain of rhodopsin binds and activates Gt, but residues that stimulate GDP release from Gt have not been identified until now. We show here that the abnormal signal transduction phenotypes of several different mutations affecting the highly conserved Glu134-Arg135 charge pair result from alteration of the GDP release step in the Gt activation cascade. We propose that Glu134 and Arg135 constitute the site that directly provides the signal from rhodopsin to activate GDP release from Gt. Because the Glu/Asp-Arg sequence occurs at a topologically identical location in most of the seven-transmembrane helix receptors, we propose that these residues constitute a switch for signal transfer.

Angiotensin II-forming activity in a reconstructed ancestral chymase.

The current model of serine protease diversity theorizes that the earliest protease molecules were simple digestive enzymes that gained complex regulatory functions and restricted substrate specificities through evolution. Among the chymase group of serine proteases are enzymes that convert angiotensin I to angiotensin II, as well as others that simply degrade angiotensins. An ancestral chymase reconstructed with the use of phylogenetic inference, total gene synthesis, and protein expression had efficient and specific angiotensin II-forming activity (turnover number, about 700 per second). Thus, angiotensin II-forming activity is the more primitive state for chymases, and the loss of such activity occurred later in the evolution of some of these serine proteases.

Molecular determinants of peptide and non-peptide binding to the AT1 receptor.

1. Several residues critically involved in AT1 receptor ligand-binding and activation have now been identified based on mutational and biochemical studies. 2. Asp281 and Lys199 of the rat AT1 receptor ion-pair with Arg2 and the Phe3 alpha-COOH of angiotensin II (AngII), respectively, and the Asp281/Arg2 interaction is critical for full agonist activity. 3. Agonist activity of AngII also requires an interaction of the Phe8 side chain with His256, which is achieved by docking of the alpha-COOH with Lys199. Non-peptide agonists interact with Lys199 and His256 in a similar fashion. 4. The crucial acid pharmacophores of AngII and the non-peptide antagonist, losartan, appear to occupy the same space within the receptor pocket. Binding of the tetrazole anion moiety of losartan involves multiple contacts, such as Lys199 and His256. However, this interaction does not involve a conventional salt bridge, but rather an unusual lysine-aromatic interaction. 5. Asp1 of AngII forms an ion-pair with His183, which stabilizes the receptor-bound conformation of AngII but is not critical for receptor activation. 6. These interactions and the involvement of other residues in stabilizing the wild-type receptor conformation or in receptor/G-protein coupling are considered here. 7. Despite these insights, considerable effort is still needed to elucidate how ligand binding induces receptor activation, what determines the specificity of AT1 receptor coupling to multiple G-proteins and the in vivo role of receptor down-regulation.

Molecular determinants of peptide and non-peptide binding to the AT1 receptor.

1. Several residues critically involved in AT(1) receptor ligand-binding and activation have now been identified based on mutational and biochemical studies. 2. Asp(281) and Lys(199) of the rat AT(1) receptor ion-pair with Arg(2) and the Phe(3) α-COOH of angiotensin II (AngII), respectively, and the Asp(281) /Arg(2) interaction is critical for full agonist activity. 3. Agonist activity of AngII also requires an interaction of the Phe(2) side chain with His(256), which is achieved by docking of the α-COOH with Lys(199). Non-peptide agonists interact with Lys(199) and His(256) in a similar fashion. 4. The crucial acid pharmacophores of AngII and the non-peptide antagonist, Iosartan, appear to occupy the same space within the receptor pocket. Binding of the tetrazole anion moiety of losartan involves multiple contacts, such as Lys(199) and His(256). However, this interaction does not involve a conventional salt bridge, but rather an unusual lysine-aromatic interaction. 5. Asp(1) of AngII forms an ion-pair with His(183), which stabilizes the receptor-bound conformation of AngII but is not critical for receptor activation. 6. These interactions and the involvement of other residues in stabilizing the wild-type receptor conformation or in receptor/G-protein coupling are considered here. 7. Despite these insights, considerable effort is still needed to elucidate how ligand binding induces receptor activation, what determines the specificity of AT(1) receptor coupling to multiple G-proteins and the in vivo role of receptor down-regulation.

Interaction of Phe8 of angiotensin II with Lys199 and His256 of AT1 receptor in agonist activation.

The acidic pharmacophores of selective ligands bind to Lys199 and His256 of the AT1 receptor (Noda, K., Saad, Y., Kinoshita, A., Boyle, T. P., Graham, R. M., Husain, A., and Karnik, S. (1995) J. Biol. Chem. 270, 2284-2289). In this report we examine how interactions between these residues and agonists activate inositol phosphate production in transiently transfected COS-1 cells. [Sar1] angiotensin (Ang II) II and [Sar1]Ang II-amide stimulated a 5-fold inositol phosphate response from wild-type AT1 receptor. The peptide antagonist [Sar1,Ile8]Ang II and the non-peptide agonist L-162,313 produced a partial but saturating response. Stimulation of wild-type receptor by [Sar1]Ang II-amide and the mutant K199Q and K199A receptors by [Sar1]Ang II demonstrates that AT1 receptor activation is not critically dependent on the ion-pairing of the alpha-COOH group of Ang II with Lys199. The mutation of His256 produced diminished inositol phosphate response without commensurate change in binding affinity of ligands. The His256 side chain is critical for maximal activation of the AT1 receptor, although isosteric Gln substitution is sufficient for preserving the affinity for Phe8-substituted analogues of [Sar1]Ang II. Therefore, AT1 receptor activation requires interaction of Phe8 side chain of Ang II with His256, which is achieved by docking the alpha-COOH group of Phe8 to Lys199. Furthermore, non-peptide agonists interact with Lys199 and His256 in a similar fashion.

The docking of Arg2 of angiotensin II with Asp281 of AT1 receptor is essential for full agonism.

The structural model of AT1 angiotensin receptor contains seven-transmembrane alpha-helices with three interhelical loops on either side of the membrane. The angiotensin II binding pocket within the receptor is not clearly defined. We showed earlier that Lys199 in transmembrane-helix-5 of the AT1 receptor binds the COOH-terminal alpha-carboxyl group of angiotensin II (Noda, K., Saad, Y., Kinoshita, A., Boyle, T. P., Graham, R. M., Husain, A., and Karnik, S. S. (1995) J. Biol. Chem. 270, 2284-2289). We now show that His183 and Asp281, both located in the extracellular domain of the AT1 receptor, are involved in binding the NH2-terminal Asp1 and Arg2 residues of angiotensin II, respectively. The Asp1/His183 interaction appears to be weak and is unlikely to be important for agonism. But the loss of Arg2/Asp281 interaction leads to partial agonism of the receptor. The action of non-peptide agonists is not affected by Asp281 mutations. These results suggest that several independent interactions between angiotensin II and AT1 receptor are necessary for full agonism. Since L-162,313 the non-peptide agonist of the AT1 receptor is a partial agonist that does not make contact with Asp281, we speculate that the degree of agonism may be increased if it is redesigned to make contacts with Asp281.

Tetrazole and carboxylate groups of angiotensin receptor antagonists bind to the same subsite by different mechanisms.

To identify specific interactions between either the tetrazole or carboxylate pharmacophores of non-peptide antagonists and the rat AT1 receptor, 6 basic residues were examined by site-directed mutagenesis. Three of the mutants (H183Q, H256Q, and H272Q) appeared to be like wild type. Lys102 and Arg167 mutants displayed reduced binding of the non-peptide antagonist losartan. Examination of their properties employing group-specific angiotensin II analogues indicated that their effects on binding were indirect. Interestingly, the affinity of losartan was not altered by a K199Q mutation, but the same mutation reduced the affinity of angiotensin II, the antagonist [Sar1,Ile8]angiotensin II, and several carboxylate analogues of losartan. An Ala199 substitution reduced the affinity of peptide analogues to a larger extent as compared to the affinity of losartan. Thus, the crucial acidic pharmacophores of angiotensin and losartan appear to occupy the same space within the receptor pocket, but the protonated amino group of Lys199 is not essential for binding the tetrazole anion. The binding of the tetrazole moiety with the AT1 receptor involves multiple contacts with residues such as Lys199 and His256 that constitute the same subsite of the ligand binding pocket. However, this interaction does not involve a conventional salt bridge, but rather an unusual lysine-aromatic interaction.

Human prochymase activation. A novel role for heparin in zymogen processing.

Human prochymase is packaged with heparin in mast cell granules and appears to be activated by dipeptidylpeptidase I. We show that a high affinity interaction between heparin and prochymase allows the 2-residue propeptide to be cleaved by dipeptidylpeptidase I. A conserved Glu in the propeptide is necessary for this heparin effect. Following propeptide cleavage, capture of the newly generated NH2 terminus by an "activation groove" on the enzyme activates the enzyme and concurrently prevents a progressive degradation of the NH2 terminus by dipeptidylpeptidase I. Surrogate peptide studies show that the activation groove is unoccupied in prochymase and is specific for the chymase NH2 terminus. These observations indicate that heparin is an important cofactor in the prochymase activation process and explain how dipeptidylpeptidase I, a nonspecific processing enzyme, can effect a specific cleavage of the zymogen propeptide.