Reduced immunotoxicity and preservation of antibacterial activity in a releasable side-chain carbapenem antibiotic.

A carbapenem antibiotic, L-786,392, was designed so that the side chain that provides high-affinity binding to the penicillin-binding proteins responsible for bacterial resistance was also the structural basis for ameliorating immunopathology. Expulsion of the side chain upon opening of the beta-lactam ring retained antibacterial activity while safely expelling the immunodominant epitope. L-786,392 was well tolerated in animal safety studies and had significant in vitro and in vivo activities against methicillin- and vancomycin-resistant Staphylococci and vancomycin-resistant Enterococci.

Imipenem cross-reactivity with penicillin in humans.

We examined the potential for IgE-mediated cross-reactivity between the carbepenems, a new class of beta-lactam antibiotics, represented by imipenem, and penicillins. In vivo skin testing with the relevant imipenem and penicillin determinants was undertaken. Having determined the concentrations of imipenem materials that did not induce false positive skin tests in nonpenicillin-allergic control subjects, we tested 40 subjects with a history of penicillin-allergic reactions. Twenty of these subjects were found to be nonallergic to penicillin on skin testing, and none of these subjects reacted to the imipendem determinants. In contrast, half the 20 subjects who were positive to one or more penicillin determinants also reacted to imipenem reagents. There was a good correlation between the penicillin and imipenem reagents to which the patients reacted. Imipenem should only be administered to penicillin-allergic subjects with similar precautions of penicillin administration to such patients.

Pharmacokinetics of L-671,329 in rhesus monkeys and DBA/2 mice.

The time course of plasma drug levels and urinary recovery for two lipopeptide antifungal antibiotics, L-671,329 and cilofungin, were measured in male rhesus monkeys (Macaca mulatta) and in female DBA/2 mice. The antibiotics were administered intravenously at 10 mg/kg of body weight in phosphate-buffered saline-26% polyethylene glycol for the rhesus monkeys and in 5% dimethyl sulfoxide for the mice. Plasma and urine drug concentrations were determined by high-pressure liquid chromatography and/or a microbiological assay versus Aspergillus niger, and pharmacokinetic parameters were determined for both species. In each of the two rhesus crossover tests as well as in the mouse studies, the pharmacokinetics of the two compounds were similar; however, a marked difference was evident between species. The half-lives of L-671,329 and cilofungin in plasma were 39 and 34 min in the mice and averaged 1.8 and 2 h in the rhesus monkeys, respectively. In mice and rhesus monkeys, urinary recovery was less than 4% for both compounds.

Quantification of imipenem's primary metabolite in plasma by postcolumn chemical rearrangement and UV detection.

Imipenem (thienamycin formamidine) is an antibiotic active against a broad spectrum of bacteria. Its primary metabolite arises from cleavage of the lactam ring. The metabolite can be formed in-vitro by acid-catalyzed or enzymatic hydrolysis. In animals and man, this metabolite can be generated systemically as well as in the kidneys following the excretion of imipenem into the urine. In man, this dehydropeptidase-catalyzed renal metabolism is minimized by the coadministration of cilastatin, a competitive inhibitor. A specific HPLC assay has been developed to evaluate the disposition of this metabolite in humans having normal or end-stage renal function. The assay employs ion-pair, reversed-phase chromatography, and post-column acid treatment of the analyte for ultraviolet detection.

Pharmacokinetics of L-749,345, a long-acting carbapenem antibiotic, in primates.

L-749,345 is a carbapenem antibiotic, currently in phase II clinical trials, which possesses a broad antibacterial spectrum and extended half-life. The time courses of levels of the drugs in plasma and urinary recovery were evaluated for L-749,345, imipenem-cilastatin (IPM), and ceftriaxone (CTX) in male rhesus monkeys (Macaca mulatta) and a chimpanzee (Pan troglodytes). The chimpanzee pharmacokinetics was predictive of human results and indicated a compound that was superior to IPM and approached CTX in its ability to persist in the circulation. Levels of binding to protein, in the range of clinically relevant concentrations in serum, are virtually equivalent for L-749,345 and CTX in humans. Results of a crossover bioassay versus those of a high-pressure liquid chromatography assay of 1-g human samples showed that there were no bioactive metabolites of L-749,345. The extended half-life at elimination phase of L-749,345 allows consideration of single daily dosing. In contrast to results with IPM, the improved stability of L-749,345 with respect to hydrolysis by the renal dehydropeptidase I (0.25 times the rate of IPM) results in urinary recovery sufficient for the drug's use as a single agent.

Metabolism of thienamycin and related carbapenem antibiotics by the renal dipeptidase, dehydropeptidase.

Thienamycin (THM), the N-formimidoyl thienamycin derivative MK0787, and related carbapenem antibiotics were metabolized extensively in mice, rats, rabbits, dogs, rhesus monkeys, and chimpanzees. Urinary recovery of THM ranged from a low of 5% in dogs to 58% in rhesus monkeys. Renal clearance rates in dogs and chimpanzees were unusually low, less than glomerular filtration rates. The reduction in clearance of THM and MK0787 from plasma of rats and rabbits after ligation of renal arteries indicate that the kidneys are responsible for 35 and 92%, respectively, of metabolic drug clearance. Degradation was detected only in kidney homogenates. The enzyme activity was membrane bound and sensitive to inhibitors of Zn-metalloenzymes such as EDTA. A renal dipeptidase, dehydropeptidase-I (DHP-I), EC 3.4.13.11, was found to be responsible for the metabolism of the THM-class antibiotics, which exhibit a structural homology to dehydropeptides. A parallel increase in specific activity against THM and the substrate of DHP-I, glycyldehydrophenylalanine, was observed during solubilization and purification of the enzyme from porcine and human renal cortex. DHP-I was found to catalyze the hydrolysis of the beta-lactam ring in THM and MK0787. The products of the enzyme reaction were identical by high-powered liquid chromatography to their respective metabolites found in the urine. Nonbasic N-acylated THM and natural N-acylated carbapenems (epithienamycins and olivanic acids) were degraded 4- to 50-fold faster than THM when exposed to the enzymatic hydrolysis of DHP-I. Good correlations were obtained between the increased susceptibility of the carbapenem antibiotics to DHP-I as measured in the in vitro enzyme assay and the generally lower recoveries of active antibiotic in the urine of test animals. Despite this unusual degree of metabolism localized in the kidney, the plasma half-life of MK0787 and its efficacy against experimental systemic infections in animals remain satisfactory.

Oxidative and defluorinative metabolism of fludalanine, 2-2H-3-fluoro-D-alanine.

The antibacterial agent fludalanine [2-2H-3-fluoro-D-alanine (DFA)] is a potent inhibitor of bacterial alanine racemase, an enzyme required for the generation of D-alanine, an essential component of the bacterial cell wall. Primary metabolism of DFA involves its oxidation to fluoropyruvate (FP); this organic fluoride is then rapidly reduced to fluorolactate (FL) which is the major organic metabolite in laboratory animals. Gas-liquid chromatographic chemical ionization mass spectrometric assays were developed for these two metabolites. FL is the predominant organofluoride metabolite of DFA in the circulation. FP was detected in the urine although recovery was very low. The rapid conversion of FP to FL precludes assay of the former in serum. Maximum serum FL concentrations in the rat appear about 1 hr after the dose of DFA and are relatively constant for several hours thereafter. The peak FL concentration is proportional to the dose of DFA; repeated daily dosing of DFA appears to cause neither saturation nor induction of metabolic pathways. Comparison of FL concentrations determined using the GC/MS assay with those based on an enzymic method specific for L-(+)-FL demonstrated that only the latter isomer is found in the plasma of monkeys dosed with DFA. In vivo exchange studies involving the alpha-proton of FL indicate that a small FP pool exists and is in equilibrium with FL. A crude pyruvate dehydrogenase complex isolated from beef heart mitochondria was shown to produce equimolar quantities of acetate, CO2, and fluoride from FP.

A new class of potent, slowly reversible dehydropeptidase inhibitors.

Dehydrodipeptide analogs whose scissile carboxamide has been replaced with a PO(OH)CH2 group have been found to be potent inhibitors of the zinc protease dehydrodipeptidase 1 (DHP-1, renal dipeptidase, EC 3.4.13.11). The best of these inhibitors, compound 25 (Ki = 0.52 nM), is two hundred times more potent than cilastatin 2 which is used clinically as a component of the broad-spectrum antibiotic combination Primaxin. Compound 25 is a tight binding inhibitor exhibiting slow binding kinetics with a remarkably slow off rate from DHP-1 (half life greater than 8 hours). The kinetics of its binding are consistent with a simple on-off mechanism whereas the less active D-enantiomer 26 appears to bind in an initial loose complex with the enzyme which slowly rearranges to a tighter complex (Ki = 83 nM).

Preliminary animal pharmacokinetics of the parenteral antifungal agent MK-0991 (L-743,872).

MK-0991 (L-743,872) is a potent antifungal agent featuring long half-life pharmacokinetics. The pharmacokinetics of MK-0991 administered intravenously to mice, rats, rhesus monkeys, and chimpanzees is presented. Unique to MK-0991 is its consistent cross-species performance. The range of values for the pharmacokinetic parameters were as follows: clearance, 0.26 to 0.51 ml/min/kg; half-life, 5.2 to 7.6 h; and distributive volume, 0.11 to 0.27 liters/kg. The level of protein binding of MK-0991 was determined to be 96% in mouse and human serum. The compound exhibited high affinities for human serum albumin and at least two lipid components. The rationale for the selection of MK-0991 as a drug development candidate was based on its two- to threefold superior pharmacokinetic performance in chimpanzees over the performance of an otherwise equivalent analog, L-733,560. Once-daily dosing for MK-0991 is indicated by a graphical comparison of levels in the circulations of chimpanzees and mice. In a study of the pharmacokinetics of MK-0991 in mouse tissue, the organs were assayed following intraperitoneal administration. The area under the concentration-versus-time curves (AUC) segregated the tissues into three exposure categories relative to plasma. The tissues with greater exposure than that for plasma were liver (16 times), kidney (3 times), and large intestine (2 times). The exposure for small intestine, lung, and spleen were equivalent to that for plasma. Organs with lower levels of exposure were the heart (0.3 times that for plasma), thigh (0.2 times), and brain (0.06 times). Kinetically, drug was cleared more slowly from all tissues than from plasma, indicating that terminal-phase equilibrium had not been achieved by 24 h. Thus, some measure of accumulation is predicted for all tissues. Single daily doses of MK-0991 should provide adequate systemic levels of fungicidal activity as a result of its long half-life pharmacokinetics, wide distribution, and slowly accumulating concentrations in tissue.

Immune cell regulation and cardiovascular effects of sphingosine 1-phosphate receptor agonists in rodents are mediated via distinct receptor subtypes.

Sphingosine 1-phosphate (S1P) is a bioactive lysolipid with pleiotropic functions mediated through a family of G protein-coupled receptors, S1P(1,2,3,4,5). Physiological effects of S1P receptor agonists include regulation of cardiovascular function and immunosuppression via redistribution of lymphocytes from blood to secondary lymphoid organs. The phosphorylated metabolite of the immunosuppressant agent FTY720 (2-amino-2-(2-[4-octylphenyl]ethyl)-1,3-propanediol) and other phosphonate analogs with differential receptor selectivity were investigated. No significant species differences in compound potency or rank order of activity on receptors cloned from human, murine, and rat sources were observed. All synthetic analogs were high-affinity agonists on S1P(1), with IC(50) values for ligand binding between 0.3 and 14 nM. The correlation between S1P(1) receptor activation and the ED(50) for lymphocyte reduction was highly significant (p < 0.001) and lower for the other receptors. In contrast to S1P(1)-mediated effects on lymphocyte recirculation, three lines of evidence link S1P(3) receptor activity with acute toxicity and cardiovascular regulation: compound potency on S1P(3) correlated with toxicity and bradycardia; the shift in potency of phosphorylated-FTY720 for inducing lymphopenia versus bradycardia and hypertension was consistent with affinity for S1P(1) relative to S1P(3); and toxicity, bradycardia, and hypertension were absent in S1P(3)(-/-) mice. Blood pressure effects of agonists in anesthetized rats were complex, whereas hypertension was the predominant effect in conscious rats and mice. Immunolocalization of S1P(3) in rodent heart revealed abundant expression on myocytes and perivascular smooth muscle cells consistent with regulation of bradycardia and hypertension, whereas S1P(1) expression was restricted to the vascular endothelium.