A ligand-based approach to investigate the expression and function of angiotensin converting enzyme in intact human umbilical vein endothelial cells

Angiotensin converting enzyme (ACE) is a drug target and an effective bradykinin (BK)-inactivating ectopeptidase. We exploited a recently described [(3)H]enalaprilat binding assay to quantify the full dynamic range of ACE expression in intact human umbilical vein endothelial cells (HUVECs) stimulated with known or novel modulators of ACE expression. Further, the affinities for ACE of a set of physiological substrates were determined using the same assay. BK has the highest affinity (K(i) 525 nM) among known substrates to displace [(3)H]enalaprilat binding from ACE. Tumor necrosis factor (TNF)-alpha repressed the expression of ACE in HUVECs while phorbol 12-myristate 13-acetate (PMA) upregulated it in 24h (approximately 12-fold dynamic range by [(3)H]enalaprilat binding, corroborated by ACE immunoblotting). Intermediate levels of ACE expression were seen in cells stimulated with both PMA and a cytokine. In contrast, high glucose, insulin or EGF failed to affect ACE expression. The effect of TNF-alpha was abated by etanercept, the IKK2 inhibitor TPCA-1, or a p38 inhibitor while that of PMA was reduced by inhibitors of PKC isoforms sensitive to phorbol esters and calcium. The short-term PKC- and MEK1-dependent increase of c-Fos expression was best correlated to PMA-induced ACE upregulation. The [(3)H]enalaprilat binding assay applied to HUVECs supports that ACE is a particularly active kininase and that endothelial ACE expression is dynamically and specifically regulated. This has potential importance in inflammatory diseases and diabetes.

Lack of direct interaction between enalaprilat and the kinin B1 receptors

It has been recently proposed that the second extracellular loop of the human bradykinin (BK) B1 receptor (B1R) contains a conserved HExxH motif also present in peptidases possessing a Zn2+ prosthetic group, such as angiotensin converting enzyme (ACE), and that ACE inhibitors directly activate B1R signaling in endothelial cells. However, the binding of ACE inhibitors to the B1Rs has never been directly evaluated. Information about binding of a radiolabeled inhibitor to natural or recombinant ACE in intact cells (physiologic ionic composition) was also collected. We used the tritiated form of an ACE inhibitor previously proposed to activate the B1R, enalaprilat, to address these questions using recombinant human B1Rs and naturally expressed or recombinant ACE. [3H]Lys-des-Arg9-BK bound to the human recombinant B1Rs with high affinity (KD 0.35 nM) in HEK 293a cells. [3H]Enalaprilat (0.25-10 nM) did not bind to cells expressing recombinant human B1R, but bound with a subnanomolar affinity to recombinant ACE or to naturally expressed ACE in human umbilical vein endothelial cells. The radioligand was further validated using a binding competition assay that involved unlabeled ACE inhibitors or their prodrug forms in endothelial cells. Membranes of HEK 293a cells that expressed B1Rs did not hydrolyze hippuryl-glycylglycine (an ACE substrate). Enalaprilat did not stimulate calcium signaling in HEK 293a cells that expressed B1Rs. A typical ACE inhibitor did not bind to nor stimulate the human B1Rs; nevertheless, several other indirect mechanisms could connect ACE inhibition to B1R stimulation in vivo.

PHARMACOKINETICS AND PHARMACODYNAMICS OF A NITRIC OXIDE-RELEASING DERIVATIVE OF ENALAPRIL IN MALE BEAGLES

1. Pharmacological compounds that release nitric oxide (NO) have been useful tools in the evaluation of the broad role of NO in physiopathology and therapeutics. The present study compared the pharmacokinetics and pharmacodynamics of enalapril and an NO-releasing enalapril molecule (NCX899) in conscious male beagles. The effects of both enalapril and NCX899 in the arterial hypertension and bradycardia induced by acute NO inhibition in anaesthetized dogs were also investigated. 2. Dogs received either NCX899 (4 micromol/kg, i.v.) or enalapril (4 micromol/kg, i.v.), after which plasma concentrations of the analytes and metabolites were quantified by liquid chromatography coupled to tandem mass spectrometry (LC-MS/MS). 3. In the NCX899 group, the area under the time-course curve (AUC(0-24h)) was 29.18 +/- 4.72, 229.37 +/- 51.32 and 5159.23 +/- 514.88 microg.h/L for the analytes nitro-enalapril, enalapril and enalaprilat, respectively. In the enalapril group, the AUC(0-24h) was 704.53 +/- 158.86 and 4149.27 +/- 847.30 microg.h/L for the analytes enalapril and enalaprilat, respectively. Statistical analysis of data from both groups showed a significant difference for the analyte enalapril, but not for enalaprilat. Moreover, NCX899 and enalapril were equally effective in inhibiting the activity of serum angiotensin-converting enzyme. 4. In anaesthetized dogs, i.v. administration of the NO synthase (NOS) inhibitor N(G)-nitro-l-arginine methyl ester (l-NAME; 0.1-10 mg/kg) significantly elevated arterial blood pressure, with concomitant bradycardia. The compound NCX899 significantly attenuated both arterial hypertension and bradycardia, whereas enalapril had no significant effect. 5. In conclusion, the present results showed that the NO-releasing derivative of enalapril NCX899 presents a pharmacokinetic/pharmacodynamic relationship similar to its parent compound enalapril. Moreover, NCX899 (but not enalapril) was effective in protecting against the cardiovascular changes induced by acute NOS inhibition.

Role of PGI2 and effects of ACE inhibition on the bradykinin potentiation by angiotensin-(1-7) in resistance vessels of SHR

The present study determined the participation of PGI2 in the angiotensin-(1-7) [Ang-(1-7)]/bradykinin (BK) interaction, in the presence and absence of Angiotensin Converting Enzyme (ACE) inhibition, trying to correlate it with tissue levels of both peptides. The isolated mesenteric arteriolar bed of Spontaneously Hypertensive Rats (SHR) was perfused with Krebs or Krebs plus enalaprilat (10 nM), and drugs were injected alone or in association. BK (10 ng)-induced relaxation was potentiated by Ang-(1-7) (2.2 microg) in the presence or absence of enalaprilat. Ang-(1-7) receptor blockade [A-779 (4.8 microg)] did not interfere with the BK effect in preparations perfused with normal Krebs, but reversed the increased BK relaxation observed after ACE inhibition. PGI2 release by mesenteric vessels was not altered by BK or Ang-(1-7) alone, but was increased when both peptides were injected in association, in the absence or in the presence of enalaprilat. ACE inhibition caused a 2-fold increase in the BK tissue levels, and a significant decrease in the Ang-(1-7) values. We conclude that endogenous Ang-(1-7) has an important contribution to the effect of ACE inhibitors participating in the enhancement of BK response. The mechanism of Ang-(1-7) potentiating effect probably involves an increased production of PGI2. Our results suggest that a different enzymatic pathway (non-related to ACE) is involved in the local Ang-(1-7) metabolism.

A calorimetric study of the binding of lisinopril, enalaprilat and captopril to angiotensin-converting enzyme

The angiotensin I-converting enzyme (ACE; EC.3.4.15.1) is a dipeptidyl carboxypeptidase that plays a central role in blood pressure regulation. The somatic form of the enzyme is composed of two highly similar domains, usually referred to as N and C domains, each containing one active site. Nevertheless, a 1:1 stoichiometry for the binding of lisinopril, captopril or enalaprilat to somatic pig lung ACE is shown by isothermal titration calorimetry (ITC) and enzymatic assays. The binding of the three inhibitors at neutral pH is very tight and the enthalpy changes are positive, indicating that the binding is entropically driven. The origin of this thermodynamic signature is discussed under the new structural information available.

Structural Details on the Binding of Antihypertensive Drugs Captopril and Enalaprilat to Human Testicular Angiotensin I-Converting Enzyme†,‡

Angiotensin converting enzyme (ACE) plays a critical role in the circulating or endocrine renin-angiotensin system (RAS) as well as the local regulation that exists in tissues such as the myocardium and skeletal muscle. Here we report the high-resolution crystal structures of testis ACE (tACE) in complex with the first successfully designed ACE inhibitor captopril and enalaprilat, the Phe-Ala-Pro analogue. We have compared these structures with the recently reported structure of a tACE-lisinopril complex [Natesh et al. (2003) Nature 421, 551-554]. The analyses reveal that all three inhibitors make direct interactions with the catalytic Zn(2+) ion at the active site of the enzyme: the thiol group of captopril and the carboxylate group of enalaprilat and lisinopril. Subtle differences are also observed at other regions of the binding pocket. These are compared with N-domain models and discussed with reference to published biochemical data. The chloride coordination geometries of the three structures are discussed and compared with other ACE analogues. It is anticipated that the molecular details provided by these structures will be used to improve the binding and/or the design of new, more potent domain-specific inhibitors of ACE that could serve as new generation antihypertensive drugs.

Inhibition of esterolysis of enalapril by paraoxon increases the urinary clearance in isolated perfused rat kidney

The effect of competing elimination pathways on the metabolic and excretory clearance estimates was examined with tracer concentrations of [(3)H]enalapril, which was both metabolized and excreted by the rat kidney. Perturbation was achieved with use of the carboxylesterase inhibitor paraoxon, which inhibited [(3)H]enalapril metabolism to [(3)H]enalaprilat in rat renal S9 fraction. At 0.1, 0.5, 1, and 10 microM paraoxon, esterolysis of enalapril was inhibited by 76 +/- 7, 93 +/- 5, 96 +/- 5, and 93 +/- 6%, respectively. The lowest concentration (0.1 microM) of paraoxon was chosen for single-pass isolated perfused kidney (IPK) studies because viability was least compromised, and the sodium and glucose reabsorptive functions of the IPK remained constant. After an equilibration period (15-20 min at constant pressure, 90-100 mm Hg), perfusion of the rat kidney with [(3)H]enalapril was carried out under constant flow (8 ml/min) for 30 min in the absence and presence of paraoxon (0.1 microM). The metabolic (from 1.83 +/- 0.52 to 1.48 +/- 0.47 ml/min/g) and total renal (from 1.87 +/- 0.46 to 1. 57 +/- 0.41 ml/min/g) clearances of [(3)H]enalapril in the IPKs were decreased significantly (p <.05) in the presence of paraoxon when compared with controls. Concomitantly, the urinary clearance (from 0. 04 +/- 0.07 to 0.09 +/- 0.09 ml/min/g) and the fractional excretion (from 0.23 +/- 0.18 to 0.52 +/- 0.25) of [(3)H]enalapril doubled (p <.05). The study illustrates that a reduction in cellular metabolism of the kidney brings forth a rise in the estimate of clearance of its complimentary pathway, estimate of the excretory (urinary) clearance.

Affinity of angiotensin I-converting enzyme (ACE) inhibitors for N- and C-binding sites of human ACE is different in heart, lung, arteries, and veins

Angiotensin-converting enzyme (ACE) has two enzymatically active domains: a C-domain in the carboxy terminal region and an N-domain in the amino terminal region. We based the pharmacologic characterization of these sites on the rat testis-lung model. In testis, only a truncate form of ACE is present (C-site), whereas both N- and C-sites are present in lung. In this model, captopril was shown to be N-selective and delaprilat to be C-selective. Ro 31-8472, a cilazapril derivative, and enalaprilat proved to be not site selective. We used these drugs to evaluate the affinity of C and N sites in various human tissues involved in the cardiovascular actions of ACE and used [125I]Ro31-8472 as ligand. The number and affinity of ACE binding sites were 17,680 +/- 2,345 fmol/mg protein (Kd = 0.32 +/- 0.04 nM) in lung, 560 +/- 65 (Kd = 0.36 +/- 0.05 nM) in heart, 237 +/- 51 (Kd = 0.37 +/- 0.06 nM) in coronary artery, 236 +/- 63 (Kd = 0.14 +/- 0.05 nM) in saphenous vein, and 603 +/- 121 (Kd = 0.50 +/- 0.06 nM) in mammary artery. The affinity (pKi) of captopril for the N sites ranged from 9.40 +/- 0.14 (lung) to 8.41 +/- 0.10 (coronary artery). The affinity for the C-site by delaprilat ranged from 9.97 +/- 0.15 (coronary artery) to 9.10 +/- 0.14 (mammary artery). Therefore, the affinity of C- and N-sites of ACE for ACE inhibitor (ACEI) drugs is different according to the organ involved. Because ACE is a glycosylated enzyme and glycosylation is organ dependent, we suggest that organ-specific glycosylation affects the binding characteristics of ACE inhibitors to N- or C-site of human tissular ACE.

Molecular mechanism for the relative binding affinity to the intestinal peptide carrier. Comparison of three ACE-inhibitors: enalapril, enalaprilat, and lisinopril

The affinity of three substrates for the intestinal peptide carrier is explained based on their three-dimensional (3D) structural data. The kinetic transport parameters of three ACE-inhibitors, enalapril, enalaprilat, and lisinopril, have been determined in an in vivo system using rat intestine. The observed kinetic transport parameters (+/- asymptotic standard error) of enalapril are: 0.81 (+/- 0.23) mM, 0.58 (+/- 0.37) mumol/h per cm2, and 0.56 (+/- 0.04) cm/h for the half-maximal transport concentration (KT), the maximal transport flux (Jmax) and the passive permeability constant (Pm). Enalaprilat was transported by passive diffusional with a Pm of 0.51 (+/- 0.04) cm/h. For lisinopril the kinetic transport parameters were 0.38 (+/- 0.19) mM, 0.12 (+/- 0.07) mumol/h per cm2, and 0.18 (+/- 0.02) cm/h for KT, Jmax, and Pm, respectively. The affinity of the ACE-inhibitors for the intestinal peptide carrier has been evaluated based on their ability to inhibit the transport rate of cephalexin. The inhibition constants (Ki) of enalapril, enalaprilat and lisinopril were 0.15, 0.28 and 0.39 mM, respectively. 3D structural analysis of lisinopril using molecular modelling techniques reveals that intramolecular hydrogen bond formation is responsible for decreased carrier affinity.

The interaction between enalaprilat and selected alpha-adrenoceptor antagonists in isolated rat tail arteries

1. Isolated perfused rat tail artery preparations were used to investigate the effects of the angiotensin converting enzyme inhibitor enalaprilat on the actions of a series of alpha-adrenoceptor antagonists. The agonist used was phenylephrine. 2. Enalaprilat (1 mumol/L) potentiated the competitive alpha 1-adrenoceptor antagonist actions of phentolamine (10-100 nmol/L) and yohimbine (0.3-3.0 mumol/L) as well as the non-competitive antagonist action of phenoxybenzamine (50-100 pmol/L). 3. The competitive alpha 1-adrenoceptor antagonist action of prazosin (1-10 nmol/L) was not affected by enalaprilat. 4. For the competitive alpha 1-adrenoceptor antagonists, including prazosin, there appeared to be an inverse relationship between antagonist potency and the extent of potentiation by enalaprilat. 5. The results support the hypothesis and angiotensin II modulates vascular smooth muscle alpha 1-adrenoceptor function.

Combined recirculation of the rat liver and kidney: studies with enalapril and enalaprilat

Combined recirculation of the rat liver (L) and kidney (IPK) at 10 ml min-1 per organ (LK) was developed to examine the hepatorenal handling of the precursor-metabolite pair: [14C]-enalapril and [3H]enalaprilat. Loading doses followed by constant infusion of [14C]enalapril and preformed [3H]enalaprilat to the reservoirs of the IPK or the LK preparation was used to achieve steady state conditions. In both organs, enalapril was mostly metabolized to its dicarboxylic acid metabolite, enalaprilat, which was excreted unchanged. At steady state, the fractional excretion for [14C]enalapril (FE = 0.45 to 0.48) and preformed [3H]enalaprilat (FE[pmi] = 1.1) were constant and similar for both the IPK and LK. The additivity of clearance was demonstrated in the LK preparation, namely, the total clearance of enalapril was the sum of its hepatic and renal clearances. However, the apparent fractional excretion for formed [14C]enalaprilat, FE(mi) and the apparent urinary clearance were time-dependent and higher than the corresponding values for preformed [3H]enalaprilat in both the IPK and LK. The FE(mi) and urinary clearance values further differed between the IPK and LK. Biliary clearance of formed vs. preformed enalaprilat displayed the same discrepant trends as observed for FE(mi) vs. FE(pmi) for the LK. These observations on the time-dependent and variable excretory clearance (urinary or biliary) of the formed metabolite vs. the constant, and much reduced, excretory clearance of the preformed metabolite are due to dual contributions to formed metabolite excretion: the nascently formed, intracellular metabolite which immediately underwent excretion and the formed metabolite which reentered the circulation, behaved as a preformed species. When data for the IPK and LK preparations were modeled with a physiological model with parameters previously reported for the L and IPK, all data, including metabolite excretory clearances, were well predicted. Model simulations revealed that the apparent FE(mi) differed between the LK and IPK preparations when the liver was present as an additional metabolite formation organ; the apparent excretory (urinary or biliary) clearance of the formed metabolite was further modulated by the volume of distribution of the metabolite, which altered levels of the formed, circulating metabolite.

Formed and preformed metabolite excretion clearances in liver, a metabolite formation organ: studies on enalapril and enalaprilat in the single-pass and recirculating perfused rat liver

Single-pass and recirculating rat liver perfusion studies were conducted with [14C]enalapril and [3H]enalaprilat, a precursor-product pair, and the data were modeled according to a physiological model to compare the different biliary clearances for the solely formed metabolite, [14C]enalaprilat, with that of preformed [3H]enalaprilat. With single-pass perfusion, the apparent extraction ratio (or biliary clearance) of formed [14C]enalaprilat was 15-fold the extraction ratio of preformed [3H]enalaprilat, an observation attributed to the presence of a barrier for cellular entry of the metabolite. Upon recirculation of bolus doses of [14C]enalapril and [3H]enalaprilat, the biliary clearance, estimated conventionally as metabolite excretion rate/midtime metabolite concentration, for formed [14C]enalaprilat was again 10- to 15-fold higher than the biliary clearance for preformed [3H]enalaprilat, but this decayed with perfusion time and gradually approached values for preformed [3H]enalaprilat. The decreasing biliary clearance of formed enalaprilat with recirculation was explained by the dual contribution of the circulating and intrahepatic metabolite (formed from circulating drug) to excretion. Physiological modeling predicted (i) an influx barrier (from blood to cell) at the sinusoidal membrane as the rate-limiting process in the overall removal of enalaprilat, (ii) a 15-fold greater extraction ratio or biliary clearance for formed [14C]enalaprilat over [3H]enalaprilat during single-pass perfusion, and (iii) the time-dependent and declining behaviour of the biliary clearance for formed [14C]enalaprilat during recirculation of the medium. In the absence of a direct knowledge of eliminating organs in vivo, this variable pattern for excretory clearance of the formed metabolite within the organ is indicative of a metabolite formation organ.

Measurement of angiotensin I converting enzyme inhibition in the heart

Angiotensin (Ang) I converting enzyme (ACE) inhibitors represent a major advance in the treatment of congestive heart failure, and tissue, rather than circulating ACE, may be their major site of action. However, assessments of tissue ACE inhibition in treated patients has not always supported this contention. In these studies, ACE activity was measured in homogenates of sampled tissue by biochemical methods. In the present study, using a model system, we have examined the validity of these tissue-sampling methods. Functional ACE activity was determined by comparing positive inotropic responses to [Pro10]Ang I in either vehicle-pretreated or ACE inhibitor-pretreated papillary muscles. [Pro10]Ang I elicits a response, which is entirely dependent on ACE-mediated conversion to Ang II. The ACE inhibitors studied were captopril, enalaprilat, lisinopril, and quinaprilat. In a parallel study, papillary muscle ACE activity was also measured in homogenates using [125I]MK-351A (a radiolabeled ACE inhibitor) binding. The studies indicate that the tissue-sampling method significantly underestimated functional ACE inhibition in hamster papillary muscles (p < 0.001). Kinetic studies indicated that the half-time for the dissociation of [3H]enalaprilat and [3H]lisinopril from hamster ventricular ACE was 4.5 and 6.2 minutes, respectively. The dissociation of [3H]quinaprilat was biphasic (half-time, 47 and 90 minutes), indicating that the two active sites of somatic ACE differ in their ability to bind to this inhibitor. The rapid rate of ACE inhibitor dissociation suggests that, during the time taken to assay ACE activity biochemically, the enzyme becomes "disinhibited," leading to an underestimation of functional ACE inhibition. ACE inhibitor dissociation rates were partially predictive of the duration of functional ACE inhibition in papillary muscles; other factors that appeared to contribute were "tissue trapping" of the inhibitor and de novo synthesis of ACE in papillary muscles. Quantification of tissue ACE inhibition and its relation to drug efficacy must, therefore, involve a careful consideration of these factors to avoid artifacts in clinical decision making and in assessments of pathogenic mechanisms involved in congestive heart failure.

The two homologous domains of human angiotensin I-converting enzyme interact differently with competitive inhibitors

The endothelial angiotensin I-converting enzyme (ACE; EC 3.4.15.1) has recently been shown to contain two large homologous domains (called here the N and C domains), each being a zinc-dependent dipeptidyl carboxypeptidase. To further characterize the two active sites of ACE, we have investigated their interaction with four competitive ACE inhibitors, which are all potent antihypertensive drugs. The binding of [3H] trandolaprilat to the two active sites was examined using the wild-type ACE and four ACE mutants each containing only one intact domain, the other domain being either deleted or inactivated by point mutation of the zinc-coordinating histidines. In contrast with all the previous studies, which suggested the presence of a single high affinity inhibitor binding site in ACE, the present study shows that both the N and C domains of ACE contain a high affinity inhibitor binding site (KD = 3 and 1 X 10(-10) M, respectively, at pH 7.5, 4 degrees C, and 100 mM NaCl). Chloride stabilizes the enzyme-inhibitor complex for each domain primarily by slowing its dissociation rate, as the k-1 values of the N and C domains are markedly decreased (about 30- and 1100-fold, respectively) by 300 mM NaCl. At high chloride concentrations, the chloride effect is much greater for the C domain than for the N domain resulting in a higher affinity of this inhibitor for the C domain. In addition, the inhibitory potency of captopril (C), enalaprilat (E), and lisinopril (L) for each domain was assayed by hydrolysis of Hip-His-Leu. Their Ki values for the two domains are all within the nanomolar range, indicating that they are all highly potent inhibitors for both domains. However, their relative potencies are different for the C domain (L greater than E greater than C) and the N domain (C greater than E greater than L). The different inhibitor binding properties of the two domains observed in the present study provide strong evidence for the presence of structural differences between the two active sites of ACE.

Determination of enalapril and its active metabolite enalaprilat in plasma and urine by gas chromatography/mass spectrometry

The method for the simultaneous determination of angiotensin-converting enzyme (ACE) inhibitor enalapril and its active metabolite enalaprilat in plasma and urine was developed by gas chromatography/mass spectrometry. Enalapril and enalaprilat in plasma and urine were extracted and cleaned up by using Sep-Pak C18 and silica cartridges. Derivatization was carried out using diazomethane and trifluoroacetic anhydride. Detection by selected ion monitoring was selected to m/z 288 (enalaprilat) and 302 (enalapril). The detection limit of enalapril and enalaprilat was 200 pg/mL in plasma and 2 ng/mL in urine. This method was applied to the pharmacokinetic analysis of enalapril and enalaprilat in body fluids.

Esterases for enalapril hydrolysis are concentrated in the perihepatic venous region of the rat liver

Perfusion of substrate via only the hepatic artery with simultaneous substrate-free perfusion of portal vein or hepatic vein [hepatic artery portal vein-hepatic artery hepatic vein] was used to examine the enzymic distribution of carboxylesterases towards the hydrolysis of enalapril to enalaprilat in the perfused rat liver preparation. In this single-pass method, [14C]enalapril was delivered by the hepatic artery at 2 ml/min into the liver, whereas drug-free perfusate entered the portal vein or hepatic vein at 10 ml/min for HAPV and HAHV perfusions, respectively. During steady state, a multiple indicator dose of 51Cr-labeled red blood cells (vascular marker), [58Co]EDTA (interstitial space marker, which behaves similarly to labeled tracer sucrose), and 3H2O was given into the hepatic artery. Labeled enalapril and the reference indicators entering via the hepatic artery will reach virtually all sinusoidal spaces during HAPV, and will be confined to the peripheral region during HAHV. By defining the steady-state extraction ratios of enalapril (Etot) and segregating the components of biliary excretion and metabolism, and by assessing the intracellular water spaces and the corresponding transit times during HPAV and HAHV, the metabolic sequestration rate constant (metabolic intrinsic clearance per unit accessible cell water space) for the periportal region/whole liver (HAHV/HAPV) was 0.344. The data suggest that the carboxylesterase activity for enalapril conversion to enalaprilat is primarily localized in the perihepatic venous region of the rat liver.

A physiological model for renal drug metabolism: enalapril esterolysis to enalaprilat in the isolated perfused rat kidney

A physiologically based kidney model was developed to describe the metabolism of enalapril and explain the observed discrepancies between generated and preformed enalaprilat (metabolite) elimination in the constant flow single-pass and recirculating isolated perfused rat kidney preparations (IPKs) as a result of the differing points of origin of the metabolite within the kidney, subsequent to the simultaneous delivery of 14C-enalapril and 3H-enalaprilat. The model incorporated clearances for diffusion/transport of drug and metabolite across the basolateral and luminal membranes of the renal cells, an intrinsic clearance for renal drug metabolism, in addition to physiological variables such as perfusate flow rate, glomerular filtration rate, and urine flow rate. Nonlinear curve fitting of single-pass and recirculating data was performed to estimate the rate-limiting step in the renal elimination of enalaprilat. Through fitting and simulation procedures, we were able to predict metabolic and excretory events for enalapril (renal extraction ratio approximately equal to 0.25-0.3; fractional excretion, FE, was less than unity) and the relatively constant pattern of urinary excretion of preformed enalaprilat (extraction ratio approximately equal to 0.07; FE approximately equal to 1). The extraction ratio of the intrarenally formed enalaprilat in single-pass IPK was about twofold that for the preformed metabolite, whereas the FEs of generated enalaprilat in recirculating IPKs were greater than 1, and tended to increase, then decrease with perfusion time. These observations were explained by the optimized parameters which indicated that efflux from cell to lumen was rate-controlling in the excretion of enalaprilat, and another small transport barrier also existed at the basolateral membrane; the lower extraction ratio of preformed enalaprilat was due to its poor transmembrane clearance at the basolateral membrane. The variable FEs for generated enalaprilat vs. the relatively constant FE for preformed metabolite in the recirculating IPK was explained by the changing contributions of both circulating and intrarenal metabolite to metabolite excretion.

Rapid conversion of the new angiotensin converting enzyme inhibitor ramipril to its active metabolite in rats

The rate of conversion of ramipril (Hoe 498), a new angiotensin converting enzyme (ACE) inhibitor, to its active metabolite was compared with that of enalapril. After intravenous administration to rats, ramipril was very rapidly deesterified to its active moiety, ramiprilat. The ratio of the active metabolite level to the prodrug level in plasma at 5 min after administration was 10.7 for ramipril, which was about 5 times the ratio for enalapril. The in vitro conversion rates of ramipril were higher than those of enalapril in all rat tissue homogenates examined, including the liver, a main site of metabolism. The apparent Km values of ramipril and enalapril in the liver were 190 and 710 mumol/l, respectively, suggesting that ramipril has a higher affinity for esterase than enalapril. In conclusion, ramipril was superior to enalapril in efficiency of conversion to the active metabolite.

Transfer of enalaprilat across rat liver cell membranes is barrier limited

The liver cell entry of enalaprilat, the polar, pharmacologically active dicarboxylic acid metabolite arising from esterolysis of enalapril, a new angiotensin-converting enzyme inhibitor, was examined in the perfused rat liver by use of the multiple-indicator dilution technique. [Phenylpropyl-2,3-3H]enalaprilat was injected into the portal vein in a bolus of blood containing 51Cr-labeled red blood cells (a vascular reference) and 125I-labeled albumin and [14C]sucrose (interstitial references that do not enter cells), with observation of the time courses of their outflow into the hepatic venous blood. A quantitative evaluation of the data was carried out by use of the barrier-limited, space-distributed variable transit time model (C.A. Goresky, G.G. Bach, and B. E. Nadeau, J. Clin. Invest. 52:991-1009, 1973). For data up to 60 s after injection, the transfer coefficients for influx, efflux, and sequestration were 0.018 +/- 0.004 (means +/- SD), 0.044 +/- 0.017, and 0.033 +/- 0.007 s-1, respectively. The influx permeability surface area product (influx clearance) per gram was 0.0057 +/- 0.0013 ml.min-1.g-1, and the rapidly accessible cellular equilibrium distribution space for enalaprilat was 0.137 +/- 0.022 ml water/g wet wt. At times beyond 60 s, the fitted data deviated systematically from the experimental data, suggesting the presence of an additional intracellular pool. With this addition, the coefficients for transfer between the intracellular pools were 0.0150 +/- 0.0045 s-1 for the direction cytoplasmic pool (pool 1)----additional pool (pool 2) and 0.0234 +/- 0.0069 s-1 for the opposite direction, and the fitted volumes of pools 1 and 2 became 0.126 +/- 0.021 and 0.082 +/- 0.018 ml/g, the total accessible cellular distribution space became 0.208 +/- 0.036 ml/g wet wt, and the sequestration transfer coefficient became 0.027 +/- 0.007 s-1. The data indicate that, as previously postulated (I. A. M. de Lannoy and K. S. Pang, Drug Metab. Dispos. 14: 513-520, 1986), the enalaprilat flux across liver cell membranes is retarded by a diffusional barrier. The results also indicate that enalaprilat is excluded from part of the volume of hepatocytes, as expected for an anionic compound crossing the membrane in charged rather than protonated form, given the negative electrical potential of the cytosol vs. the extracellular space.