©1995 by The American Society for Biochemistry and Molecular Biology, Inc.
Crystallographic Studies on the Binding Modes of P-P Butanediamide Renin Inhibitors (*)

(Received for publication, June 23, 1995; and in revised form, October 2, 1995)

Liang Tong (§) Susan Pav Daniel Lamarre (1) Bruno Simoneau (2) Pierre Lavallée (2) Grace Jung (2)(¶)

From the  (1)Department of Inflammatory Diseases, Boehringer Ingelheim Pharmaceuticals, Inc., Ridgefield, Connecticut 06877 and the Departments of Biochemistry and (2)Chemistry, Bio-Méga/Boehringer Ingelheim Research, Inc., 2100 rue Cunard, Laval, Québec, Canada H7S 2G5

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

The binding modes of three peptidomimetic P(2)-P(3) butanediamide renin inhibitors have been determined by x-ray crystallography. The inhibitors are bound with their backbones in an extended conformation, and their side chains occupying the S(5) to S(1)` pockets. A (2-amino-4-thiazolyl)methyl side chain at the P(2) position shows stronger hydrogen-bonding and van der Waals interactions with renin than the His side chain, which is present in the natural substrate. The ACHPA--lactam transition state analog has similar interactions with renin as the dihydroxyethylene transition state analog.


INTRODUCTION

The aspartic protease renin plays an important role in the regulation of blood pressure by catalyzing the release of the decapeptide angiotensin I from angiotensinogen(1) . Removal of the two C-terminal residues from angiotensin I, catalyzed by the angiotensin-converting enzyme, produces the physiologically active octapeptide angiotensin II. Inhibitors of ACE have become successful therapeutic antihypertensive agents(1) . However, the angiotensin-converting enzyme inhibitors produce unwanted side effects in treatment and have only a 50% response rate in monotherapy(2) , clearly indicating the need for other therapeutic agents. The inhibition of renin represents a possible alternative for developing successful antihypertensives.

The cleavage in human angiotensinogen catalyzed by renin occurs between residues 10 and 11 in the sequence His-Pro-Phe-His-Leu-Val-Ile. Compounds containing a butanediamide backbone at the P(2)-P(3) positions (3) are potent peptidomimetic inhibitors of human renin (Fig. 1). (^1)They contain either the dihydroxyethylene (4) (inhibitors 1 and 2) or the ACHPA(^2)--lactam (5) (inhibitor 3) as the transition state analog occupying the P(1) and P(1)` positions(3) . The His side chain in angiotensinogen at the P(2) position is replaced with a (2-amino-4-thiazolyl)methyl group.


Figure 1: Chemical structures and potencies of three P(2)-P(3) butanediamide renin inhibitors. IC values are measured at pH 6.0 using purified recombinant human renin.



Crystal structures of free and inhibited human renin have been reported previously at medium resolution(6, 7, 8) . We recently reported the crystal structure at 1.8-Å resolution of human renin in complex with a polyhydroxymonoamide inhibitor(9) . In this paper we describe the binding modes of the P(2)-P(3) butanediamide renin inhibitors as determined by x-ray crystallography and compare their binding interactions with those of other inhibitors (7, 9


MATERIALS AND METHODS

Data Collection

The purification (10) of recombinant human renin and crystallization (11, 12) of renin-inhibitor complexes has been described earlier. The crystals belong to space group P2(1)3 with a = b = c = 143 Å at 4 °C(11) . There are two renin molecules in the asymmetric unit. X-ray diffraction data to 2.4-Å resolution of renin in complex with inhibitor 1 were collected at 4 °C on the F-1 beamline at the Cornell High Energy Synchrotron Source (CHESS). The diffraction data for renin in complex with inhibitors 2 and 3 were collected, at cryotemperature (120 K) and 4 °C respectively, on an R-Axis imaging plate detector mounted on a Rigaku RU-200 x-ray generator operated at 50 kV and 100 milliamps. The data-processing statistics are summarized in Table 1.



Structure Determination

The crystal structure of renin in complex with inhibitor 1 was determined by the molecular replacement method, using as the search model a 2.8-Å structure of human renin(8) . The orientations of the two renin molecules were determined by rotation function calculations using reflection data between 10- and 3.5-Å resolution with the program GLRF(13) . The positions of the two molecules were then determined with the Patterson correlation translation function using the program TF(14) .

Structure Refinement

The atomic model for renin in complex with inhibitor 1 derived from the molecular replacement calculations was subjected to rigid body refinement against reflection data between 5- and 3-Å resolution. This was followed with slow cooling simulated annealing refinement of the atomic positions using the program X-Plor(15) . The atomic model was examined on an Evans & Sutherland workstation with the program Frodo(16) . The inhibitor molecules were clearly visible in the 2F(o) - F(c) electron density map and were included in further refinement. A parameter file containing the ideal bond lengths and bond angles for the inhibitor, estimated based on values for similar bond types in amino acid residues, was created manually.

At this point reflection data to 1.8-Å resolution became available for human renin in complex with a polyhydroxymonoamide inhibitor, in an isomorphous crystal form(9) . The refined model of renin in complex with 1 was used as the initial model for the refinement at 1.8-Å resolution. This produced a more accurate atomic model for renin (9) . Consequently, the structure refinement of the inhibitor 1 complex was restarted using the 1.8-Å renin model. This 1.8-Å structure of renin was also used as the starting model in the structure refinement of renin in complex with inhibitors 2 and 3. The final atomic models were obtained after one cycle of refinement with the program TNT (Fig. 2)(17) . The refinement statistics of the three structures are summarized in Table 1.


Figure 2: Final 2F-Felectron density map for inhibitor 1 in complex with renin in the closed conformation. Reflection data between 20- and 2.4-Å resolution were used in the calculation. The contour level is at 1 root mean square deviation above the mean of the electron density values.




RESULTS AND DISCUSSION

The crystal structures of recombinant human renin in complex with three different P(2)-P(3) butanediamide inhibitors are presented in this paper. The crystallographic data and the refinement statistics are summarized in Table 1. The structure of human renin in complex with inhibitor 1 is at the higher resolution of 2.4 Å, whereas the other two structures are at medium resolutions of 2.7 and 2.8 Å. The atomic coordinates have been deposited at the Brookhaven Protein Data Bank.

There are two independent renin complexes in each crystal. As has been observed in our earlier study(9) , these two renin inhibitor complexes adopt different conformations. One has a closed conformation in which residues in the C-terminal domain (198-204, 224-259, and 269-286; pepsin numbering) are closer to the N-terminal domain and the inhibitors, whereas the other renin molecule has an open conformation. Similar conformational differences have also been observed in other aspartic proteinases(18) .

For structural comparisons, the six renin complexes from the three crystal structures were superimposed. The renin molecule in complex with inhibitor 1 in the closed conformation was used as the reference in this superposition. The C positions of residues in the N-terminal domain of renin were used to calculate the transformation matrix. This superposition based on the renin portion of the complex also led to a general overlap of the inhibitors (Fig. 3). The observed variation in the position of the inhibitors (Fig. 3) is due partly to the differences among the inhibitors in their interactions with renin. This variation may also be attributable to the limited resolution of the current structures. Our earlier study of renin-inhibitor complexes at high resolution showed much closer overlap of the inhibitors for the P(2), P(1), and P(1)` residues(9) .


Figure 3: Stereo diagram showing the overlap of the three P(2)-P(3) butanediamide inhibitors as bound to renin. Inhibitors 1, 2, and 3 as bound to renin in the closed conformation are shown in white, green, and pink, respectively. The corresponding inhibitors as bound to renin in the open conformation are shown in cyan, brown, and purple, respectively.



The inhibitor molecules are bound in a groove between the N- and C-terminal domains of renin. The backbones of the inhibitors are in an extended conformation. The side chains occupy the S(5) to S(1)` substrate binding pockets. The pattern of hydrogen bonding between the polar atoms in the backbone of the inhibitors and renin is similar to that reported for other peptidomimetic renin inhibitors(7, 8, 9) . The absence of a P(2) amido nitrogen in the butanediamide backbone results in the loss of a hydrogen bond to the side chain of Thr(7) . The two carbonyl oxygen atoms of the butanediamide backbone are located at similar positions and maintain similar hydrogen bonding interactions to renin as the carbonyl oxygen atoms of the P(2) and P(3) residues in a peptide substrate (see below).

The pyridylethyl group in inhibitor 2 is exposed to solvent and has weak electron density, suggesting it may also be flexible. The pyridyl ring is folded close to the P(3) phenyl ring of the inhibitor and occupies the S(5) pocket (Fig. 3). The lack of additional interactions of this pyridyl group with renin is consistent with the observation that this compound is as potent as inhibitor 1 (Fig. 1). The pyridyl group of the inhibitor bound to the renin molecule in the open conformation is involved in crystal-packing interactions, which may explain its positional difference from that of the pyridyl ring in the inhibitor bound to the renin molecule in the closed conformation (Fig. 3).

The plane of the amide group of the P(4) residue is perpendicular to that of the P(3) residue in all three inhibitors (Fig. 3). The N-methyl group is pointed toward the side chain of Tyr in the S(4) pocket. In comparison with the structures of renin in complex with polyhydroxymonoamide inhibitors(9) , which lack a P(4) group, the side chain of Tyr rotates by about 20° and 60° across the (1) and (2) torsion angles to avoid steric contact with this methyl group (Fig. 4). This change in the conformation of the Tyr side chain is observed in both the open and the closed conformations of renin for all three inhibitors. The orthogonality of the amide planes of the P(4) and P(3) residues projects the methyl group deeper into the S(4) pocket as compared with the P(4) residue in the compound CGP 38`560 (Fig. 5)(7) . A smaller change in the position of the Tyr side chain is observed in the latter complex, which is in the closed conformation.


Figure 4: A, stereo diagram showing the overlap of residues 219-222 and 286-290 of renin in complex with inhibitor 1 (thin solid lines) and the polyhydroxymonoamide inhibitor 4 (thin gray lines)(9) . The corresponding inhibitors are shown in thick solid and gray lines, respectively. B, the chemical structures of inhibitor 4 and CGP 38`560(7) .




Figure 5: Stereo diagram showing the overlap of inhibitor 1 (thick lines), the polyhydroxymonoamide inhibitor 4 (thin lines)(9) , and the inhibitor CGP 38`560 (gray lines)(7) .



In contrast to earlier structure studies(7, 9) , which showed the phenyl group at the P(3) position having a common binding orientation (Fig. 5), the P(3) phenyl groups of the three inhibitors studied here assume a variety of orientations, due mostly to changes in the (2) torsion angle (Fig. 3). The methyl group on the benzylic carbon of the P(3) side chain is projected into the solvent. The side chains in these inhibitors are connected to a planar amido nitrogen atom rather than a tetrahedral carbon as in other peptidomimetic inhibitors(7, 9) . Consequently, the side chain enters the S(3) binding pocket from a different direction as compared with the inhibitors with a tetrahedral carbon (Fig. 5). The amino acid side chains of renin forming the S(3) pocket show no significant differences among the structures.

The P(2) group of the polyhydroxymonoamide inhibitors in our earlier study (9) is the smaller cyclopropylmethyl group. A water molecule was observed at the base of the S(2) pocket in those structures. In the current structures, the larger aminothiazole ring fills the S(2) pocket more fully. The amino group displaces the water molecule observed in the earlier structures (9) and is hydrogen-bonded to the side chain hydroxyl group of Ser and the main chain carbonyl group of Tyr (Fig. 4). The sulfur atom of the aminothiazole ring is surrounded mostly by side chains of hydrophobic residues (Ala, Ile, Met, and Leu). The higher polarizability of the sulfur atom may probably give rise to stronger van der Waals interactions with these side chains. The bulkier sulfur atom, and possibly the additional hydrogen-bonding interactions of the amino group, also cause a shift in the position of the P(2) (2-amino-4-thiazolyl)methyl residue as compared with the position of the P(2) His residue in the CGP 38`560 complex (Fig. 5).

The change in conformation of the Tyr side chain due to the P(4) residue of these inhibitors is coupled with a change in conformation of the His side chain, which was observed to be located close to the Tyr side chain and away from the S(2) pocket in the earlier structures(9) . In the renin molecule with the open conformation, a small movement is observed for the His side chain to avoid steric contact with the Tyr side chain. The His side chain in the new position still maintains interactions with the side chain of Asp. In the renin molecule with the closed conformation, due to the proximity of residues 243-245, the His residue undergoes a large conformational change (including a change in (1) of 140°). Its side chain is located close to the S(2) pocket in the new position, where it interacts with the ring nitrogen of the thiazolyl group through a water molecule at the opening of the S(2) pocket (Fig. 4). Two other polar atoms, the main chain amido nitrogen of Tyr and the carbonyl oxygen of the P(4) residue, complete the tetrahedral coordination of this water molecule (Fig. 4). A change in the position of the Met side chain is also observed (Fig. 4).

In the structure of renin in complex with the inhibitor CGP 38`560(7) , the His side chain was found to be close to the S(2) pocket, interacting with a water molecule at the opening of the S(2) pocket. The hydrogen bond between this water and the His side chain of the inhibitor, however, was not observed. A water molecule at the opening of the S(2) pocket was also observed in our earlier study, where the His is away from the S(2) pocket (Fig. 4)(9) .

The dihydroxyethylene transition state analog in the P(1) and P(1)` positions is bound in a conformation similar to that observed in the earlier study ( Fig. 3and Fig. 4)(9) . The first hydroxyl group of the diol is located between the catalytic aspartic acid residues 32 and 215. The ACHPA--lactam transition state analog in inhibitor 3 occupies similar spatial positions as the dihydroxyethylene analog (Fig. 3). As predicted from modeling studies(5) , the gem-dimethyl group on the lactam ring superimposes with the isopropyl group of the diol analog, mimicking the Val side chain in the natural substrate. The carbonyl oxygen atom of the lactam occupies a position similar to that of the second hydroxyl group of the dihydroxyethylene transition state analog (Fig. 3).

These P(2)-P(3) butanediamide inhibitors are about 40-fold more potent than the polyhydroxymonoamide inhibitors of renin(9) . The crystal structures show that the P(2)-P(3) butanediamide inhibitors have stronger interactions with renin at the P(2) position and additional interactions due to the P(4) residue. These may explain the increased potency of the inhibitors. The contribution of the P(3) residue is difficult to evaluate, and it is not clear whether the two different series of inhibitors have similar interactions with renin at this position.


FOOTNOTES

*
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

The atomic coordinates and structure factors (codes 1BIL and 1BIM) have been deposited in the Protein Data Bank, Brookhaven National Laboratory, Upton, NY.

§
To whom correspondence should be addressed. Dept. of Inflammatory Diseases, Boehringer Ingelheim Pharmaceuticals, Inc., 900 Ridgebury Road/P.O. Box 368, Ridgefield, CT 06877. Tel.: 203-798-5139; Fax: 203-791-6072 or 203-790-6815.

Present address: Bio-organic Chemistry Laboratory, The Clinical Research Institute of Montréal, 110 avenue des Pins Ouest, Montréal, Québec, Canada H2W 1R7

(^1)
P. C. Anderson, M. Bailey, G. Bantle, S. Berthiaume, C. Chabot, G. Fazal, T. Halmos, G. Jung, P. Lavallée, W. W. Ogilvie, M. J. Panzenbeck, M.-A. Poupart, B. Simoneau, B. Thavonekham, D. Thibeault, and R. J. Winquist, manuscript in preparation.

(^2)
The abbreviation used is: ACHPA, 4(S)-amino-5-cyclohexyl-3(S)-hydroxypentanoic acid.


ACKNOWLEDGEMENTS

We thank Thomas Warren and Dr. Karl Hargrave for help with the data collection at CHESS. We thank Louise Pilote for the production and purification of recombinant human renin; Diane Thibeault for the measurement of enzyme inhibition by compounds 1-3; and Sylvie Berthiaume, Bounkham Thavonehkam, and Dr. Murray Bailey for the preparation of inhibitors 1-3. We thank Drs. C. Pargellis, Peter Grob, Peter Farina, Paul Anderson, and Yvan Guindon for enthusiasm and encouragement in this project.


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©1995 by The American Society for Biochemistry and Molecular Biology, Inc.