Frederick M. Kahan

THE MECHANISM OF ACTION OF FOSFOMYCIN (PHOSPHONOMYCIN)

The discovery of fosfomycin, a new antibiotic produced by strains of Streptomyces, was announced under its former name phosphonomycin by Hendlin and colleagues in 1969.l The chemical structure shown in FIGURE 1 combines two unusual features: an epoxide ring, rare among antibiotics, and a carbon-phosphorus bond which is seen to occur here for the first time among the natural products of the bacteria. Most of the present account concerns the determination of the enzymatic step in cell wall biosynthesis that is ultimately blocked by fosfomycin. We compare in detail the action of that enzyme’s catalytic center upon the antibiotic and its normal substrate. We also describe the role of two stereospecific nutrient transport systems that by mediating the entry and accumulation of fosfomycin comprise the determining factors in the sensitivity of various bacteria to this polar antibiotic. Although the main conclusions of these mechanism of action studies were briefly stated by us in the initial announcement,’, the present publication is the first in which there appears any portion of the original experimental data that support those conclusions. Several reports have appeared from other laboratories 4, and from our own IJ in which certain basic findings and methodology were reproduced in the course of pursuing the independent goals of their studies. Their additional contributions to the understanding of fosfomycin action are cited at appropriate points in the succeeding text.

Phosphonomycin, a New Antibiotic Produced by Strains of Streptomyces

Phosphonomycin is a newly discovered antibiotic produced by streptomycetes. It is effective, when administered by the oral route, to mice infected with Gram-positive or Gram-negative microorganisms. The antibiotic is bactericidal and inhibits cell-wall synthesis.

Antibacterial Agents That Inhibit Lipid A Biosynthesis

Lipid A constitutes the outer monolayer of the outer membrane of Gram-negative bacteria and is essential for bacterial growth. Synthetic antibacterials were identified that inhibit the second enzyme (a unique deacetylase) of lipid A biosynthesis. The inhibitors are chiral hydroxamic acids bearing certain hydrophobic aromatic moieties. They may bind to a metal in the active site of the deacetylase. The most potent analog (with an inhibition constant of about 50 nM) displayed a minimal inhibitory concentration of about 1 microgram per milliliter against Escherichia coli, caused three logs of bacterial killing in 4 hours, and cured mice infected with a lethal intraperitoneal dose of E. coli.

Metabolism of Thienamycin and Related Carbapenem Antibiotics by the Renal Dipeptidase, Dehydropeptidase-I

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.

Carbapenems, a new class of beta-lactam antibiotics: Discovery and development of imipenem/cilastatin

The discovery of Streptomyces cattleya and its antibiotic product, thienamycin, has ushered in a new era of beta-lactam agents, the carbapenems. Numerous carbapenems were subsequently discovered; however, none had the potency, broad-spectrum activity, and lack of cross-resistance exhibited by thienamycin. Chemical instability encountered with thienamycin was overcome by the N-formimidoyl derivative, imipenem. Imipenem is distinguished from other beta-lactams by its outstanding activity against gram-positive organisms as well as against Enterobacteriaceae, Pseudomonas aeruginosa, and Bacteroides. However, development was hindered by extensive renal metabolism of imipenem, resulting in low urinary concentrations of antibiotic. A renal dipeptidase, dehydropeptidase-I, was responsible for hydrolyzing imipenem and other carbapenems. To counter its action, a specific inhibitor, cilastatin, was developed. Coadministered with imipenem in a one-to-one ratio, cilastatin provides prolonged, reversible blockade of imipenem metabolism, dramatically improving urinary recoveries to therapeutically significant levels. Cilastatin also contributes to the safety of imipenem, since its coadministration prevents proximal tubular necrosis which has been observed in sensitive animals receiving imipenem alone in high doses. Thus, the combination imipenem and cilastatin overcame the pharmaceutical and metabolic challenges presented by thienamycin, and allowed for the evaluation in humans of the outstanding antimicrobial activity of this new class of beta-lactam antibiotics.

MK0787 (N-formimidoyl thienamycin): evaluation of in vitro and in vivo activities.

The practical application of thienamycin, a novel beta-lactam antibiotic with a broad activity spectrum, was compromised by problems of instability. MK0787, N-formimidoyl thienamycin, does not have this liability. As reported, bacterial species resistant to most beta-lactam antibiotics, such as Pseudomonas aeurginosa, Serratis, Enterobacter, Enterococcus, and Bacteroides spp., are uniformly susceptible to MK0787, usually at one-half the inhibitory level of thienamycin. Bactericidal activity usually occurs at the minimal inhibitory concentration endpoint. Activity was reduced only at the highest inoculum densities tested and by a lessor factor than was observed with reference beta-lactam antibiotic active against P. aeruginosa and beta-lactamase-bearing strains. MK0787 exhibits a broad spectrum of in vivo activity when evaluated parenterally for efficacy against systemic infections in mice. The order of potency in vivo, 0.03 to 0.06 mg/kg for gram-positive species and 0.65 to 3.8 mg/kg for gram-negative infections including Pseudomonas, exceeded that of thienamycin and was at least 10-fold superior to reference beta-lactam antibiotics including two recently developed agents with antipseudomonal activity, cefotaxime and LY127935.