Aerocyanidin, a new antibiotic produced by Chromobacterium violaceum.

Aerocyanidin, a new antibiotic containing an isonitrile group, has been isolated from fermentations of Chromobacterium violaceum ATCC 53434. Structure 1 was assigned on the bais of spectroscopic characterization of the antibiotic and of a degradation product that results from treatment with base. The antibiotic is primarily active against Gram-positive bacteria.

Aerocavin, a new antibiotic produced by Chromobacterium violaceum.

A new antibiotic, aerocavin, has been isolated from fermentation broths of a non-pigmented strain of Chromobacterium violaceum. The structure 1 was deduced from its spectroscopic properties and X-ray diffraction analysis. Aerocavin exhibits activity in vitro against Gram-positive and Gram-negative bacteria.

The new monobactams: chemistry and biology.

The discovery of the monobactams led to the successful development of aztreonam as the first of this novel class of beta-lactam antibiotics to enter the clinical field. Continued structural modification on the monobactam nucleus has resulted in two additional compounds from this class that show interesting biologic properties. The first, SQ 83,360, is like aztreonam in exhibiting high activity against members of the Enterobacteriaceae but has the added characteristic of being exceptionally active against strains of Pseudomonas aeruginosa. Also, significant gains are made with SQ 83,360 in activity against Pseudomonas spp. and Acinetobacter. The second compound, tigemonam, is also like aztreonam, having good activity against Enterobacteriaceae, Haemophilus influenzae, and Neisseria gonorrhoeae and showing good beta-lactam stability. Tigemonam differs from aztreonam in being well absorbed orally by experimental laboratory animals.

Xylocandin: a new complex of antifungal peptides. I. Taxonomy, isolation and biological activity.

Xylocandin is a complex of novel peptides with potent antifungal activity that is produced by Pseudomonas cepacia ATCC 39277. The complex was isolated from the fermentation broth by extraction with butanol-methanol, 9:1, followed by collection of the precipitate formed upon concentration of the solvent extract. Purification was effected by chromatography on reversed phase and size exclusion gels followed by TLC on silica gel. These techniques afforded eight components: A1, A2, B1, B2, C1, C2, D1 and D2. A mixture of the two closely related components, xylocandins A1 and A2, displayed potent anticandidal and antidermatophytic activities in vitro. The activity was diminished by the presence of serum or vaginal washings. No antibacterial activity was demonstrable.

In vivo evaluation of tigemonam, a novel oral monobactam.

Tigemonam, a new monobactam with excellent activity against gram-negative bacteria, was evaluated for in vivo efficacy and absorption after oral administration to laboratory animals. Tigemonam is absorbed when administered orally to mice and dogs. In a variety of gram-negative systemic infections in mice, orally administered tigemonam was efficacious in all infections studied. Comparison drugs such as amoxicillin, cephalexin, and cefaclor were less efficacious, especially in infections caused by beta-lactamase-producing organisms. In localized infections, tigemonam also demonstrated excellent in vivo activity. In acute pyelonephritis in mice caused by Escherichia coli or Proteus sp., tigemonam was very effective. In a rat lung model with Klebsiella pneumoniae, tigemonam was active with a median effective dose of 46 mg/kg compared with 160 mg/kg for cefaclor and over 200 mg/kg for amoxicillin. Tigemonam was well absorbed in laboratory animals and with its excellent gram-negative spectrum of activity should prove of value in oral antibiotic therapy in humans.

In vitro evaluation of tigemonam, a novel oral monobactam.

Tigemonam, a novel, orally administered monobactam, exhibited potent and specific activity in vitro against members of the family Enterobacteriaceae, Haemophilus influenzae, and Neisseria gonorrhoeae. Its activity was variable to poor against gram-positive bacteria, Acinetobacter spp., Pseudomonas aeruginosa, and anaerobes. Within its spectrum of activity, tigemonam was far superior to oral antibiotics currently available, including amoxicillin-clavulanic acid, cefaclor, and trimethoprim-sulfamethoxazole. In addition, tigemonam was superior to cefuroxime, which is under development as an oral pro-drug, and more active than cefixime against several genera of the Enterobacteriaceae. The activity of tigemonam against the enteric bacteria, Haemophilus species, and Neisseria species was, in general, comparable to that of the quinolone norfloxacin. The excellent activity of tigemonam against beta-lactamase-producing bacteria reflected its marked stability to hydrolysis by isolated enzymes. The expanded spectrum of activity against gram-negative bacteria observed with tigemonam thus extends oral beta-lactam coverage to include members of the Enterobacteriaceae that are intrinsically or enzymatically resistant to broad-spectrum penicillins and cephalosporins.

Evaluation of aztreonam, cefoperazone, latamoxef and ceftazidime in the hamster colitis model.

Aztreonam, ceftazidime, cefoperazone and latamoxef (moxalactam) were evaluated in a hamster model for antibiotic-associated colitis. Aztreonam, a novel monocyclic beta-lactam antibiotic specifically directed against aerobic Gram-negative bacteria with limited activity against Gram-positive and anaerobic bacteria did not cause haemorrhagic caecitis and death in hamsters when administered intraperitioneally or orally. Quantitative caecal cultures showed no changes in the anaerobic caecal microflora of hamsters treated intraperitoneally with aztreonam and only a temporary decrease in anaerobic Gram-negative bacilli in hamsters treated orally. Clostridium difficile and its cytotoxin were not present in these animals. Parenteral administration of ceftazidime also did not affect the anaerobic caecal microflora or cause caecitis. However, when given orally, ceftazidime suppressed the anaerobic caecal microflora and a lethal C. difficile-induced caecitis developed. Latamoxef or cefoperazone given parenterally resulted in caecitis and death in five days with marked changes in the anaerobic caecal microflora and C. difficile present in the caecal contents of these animals. The lethal haemorrhagic caecitis observed in this study was indistinguishable from that seen in the clindamycin-induced colitis model in the hamster. The possible correlation of these findings to gastrointestinal disturbances as a complication of antibiotic therapy in humans is discussed.

Discovery and development of the monobactams.

A novel procedure designed to detect naturally occurring beta-lactam-containing molecules led to isolation of the monobactams - structurally unique, bacterially produced, monocyclic beta-lactam antibiotics. Although none of these monobactams exhibited impressive antimicrobial activity, side-chain variation - as with the penicillins and cephalosporins - resulted in potently active compounds. Aztreonam was chosen from hundreds of compounds for extended laboratory studies. In addition to a unique chemical structure, aztreonam has biologic properties that are unique in comparison with those of the classical penicillins and cephalosporins. Aztreonam is relatively inactive against gram-positive bacteria and anaerobes but is extremely effective against aerobic gram-negative bacteria, including Pseudomonas aeruginosa. The drug is highly resistant to enzymatic hydrolysis by beta-lactamases, particularly those known to be mediated by R plasmids, and is a poor inducer of chromosomal beta-lactamases. In the majority of drug combinations tested, aztreonam exhibits additive or synergistic activity. In a series of animal-model infections, the drug showed a high degree of efficacy that was consistent with findings in studies in vitro. In a hamster model for Clostridium difficile-induced pseudomembranous colitis, aztreonam did not induce any significant changes.

Novel potentiators of beta-lactam antibiotics. Isolation of SQ28,504 and SQ28,546 from Chromobacterium violaceum.

Two novel compounds, SQ28,504 and SQ28,546 are produced by Chromobacterium violaceum. These compounds enhance the antibacterial activity of beta-lactam antibiotics against Gram-negative organisms. Both SQ28,504 and SQ28,546 induce morphological changes in the presence of beta-lactam antibiotics. Only SQ28,546 has weak antimicrobial activity against several Gram-negative organisms.

Resistance caused by decreased penetration of beta-lactam antibiotics into Enterobacter cloacae.

Strains of Enterobacter cloacae were selected on the basis of resistance to aztreonam, ceftazidime, moxalactam, or imipenem. All strains produced the same E2 beta-lactamase, with an isoelectric point greater than 9.5 and with high hydrolytic activity in the presence of cephaloridine. Resistance to beta-lactams could not be correlated with the amount of beta-lactamase present in the various strains. beta-Lactamase activity was induced strongly by moxalactam and imipenem in the wild-type and moxalactam-resistant strains, with beta-lactamase representing as much as 4% of the total cellular protein after induction (2 X 10(5) molecules per cell). Ceftazidime and aztreonam were poor inducers. None of the antibiotics studied was readily hydrolyzed by the E2 beta-lactamase; aztreonam and moxalactam inhibited the enzyme with apparent Ki values of 1.2 and 100 nM, respectively. Aztreonam, which bound covalently to the E2 beta-lactamase with a half-life of 2.3 h at 25 degrees C, was used to measure penetrability of beta-lactam into the periplasmic space of the resistant E. cloacae strains. In all of the E2-producing organisms studied, a significant permeability barrier existed. A maximum concentration of 0.02 microgram of aztreonam per ml should have saturated the periplasmic beta-lactamase in the highest enzyme producers studied. However, fully active beta-lactamase was observed in the periplasm of cells exposed to aztreonam at concentrations at least 1,000-fold higher than that theoretically necessary to inhibit the total enzyme within the cell. Thus, the major cause for resistance to beta-lactam antibiotics in these E. cloacae strains was lack of penetration across the outer membrane.

Aztreonam: the first monobactam.

A novel screening procedure led to isolation of the structurally unique, bacterially produced, monocyclic beta-lactam antibiotics early in 1979. These naturally occurring "monobactams" were not clinically useful as antibiotics because of their poor antibacterial properties. They were, however, found to interact with certain penicillin-binding proteins of bacteria and thus to interfere with the biosynthesis of bacterial cell walls. The focus of monobactam development then turned toward increasing the binding activity of the beta-lactam ring of the molecule. Aztreonam was the first compound to emerge that fulfilled the objectives of the program. It is relatively inactive against gram-positive and anaerobic bacteria but is extremely effective against aerobic gram-negative bacteria, even in low concentrations. In addition, it is highly resistant to enzymatic hydrolysis by beta-lactamases and demonstrates a high degree of stability against plasmid-mediated gram-negative lactamases. With the chromosomally mediated beta-lactamases, on the other hand, aztreonam can act either as an inhibitor or as a poor substrate. It is unique in that it does not induce production of chromosomally mediated enzymes. Interference with normal gut flora by the use of broad-spectrum antibiotics can result in decreased defense capacity and can lead to intestinal colonization by resistant pathogenic organisms. Therapy directed specifically against the invading pathogen is thus preferred. Such directed therapy is provided by aztreonam. Its narrow spectrum can, if necessary, be broadened by combining it with other antibiotics while continuing to maintain an alternative to the more generalized "shotgun" therapy with its attendant side effects such as disturbances of the natural gut flora, diarrhea, and the emergence of resistant bacteria.

Structure activity relationships among the monobactams.

The monobactam nucleus (3-AMA) exhibits weak antibacterial activity and thus, as with the penicillins and cephalosporins, molecular substitution around the central nucleus is essential to realize the antibacterial potential of these molecules. Side chain structure/activity relationships in monobactams parallel those of the penicillins and cephalosporins. Such a relationship is not unexpected in view of the common enzymatic targets shared by these structurally divergent types. Side chain substitution of the monobactam nucleus leads to compounds exhibiting primarily Gram-positive, primarily Gram-negative or broad-spectrum activity. However, incorporation of small polar groups (amino, hydroxyl, carboxylic or sulphonic) at the alpha position of these side chains leads to poorly active compounds. This observation is the most striking divergence between monobactam and penicillin/cephalosporin structure-activity relationships. The most striking gain in anti-bacterial activity is observed with the introduction of an aminothiazoleoxime side chain as the 3-acyl substituent. In the case of carbonyl-activated and phosphate activated compounds, there is total reliance on this side chain grouping for achieving activity. Activity against Gram-positive bacteria, if present, is closely related to the nature of the acyl side chain. The aminothiazoleoxime side chains characteristically reduce activity against this organism class. Substitution at the 4-position of the monocyclic ring although capable of producing dramatic changes in biological activity, is highly unpredictable. In the SO3-activated molecules 4-substitution is essential for beta-lactamase stability and in many instances results in increased intrinsic activity of the molecule. Incorporation of 4-substituents on the beta-lactamase susceptible O-activated molecules has little or no effect on beta-lactamase stability or antibacterial activity. In the case of carbonyl- and phosphate-activated species, while offering no advantages, 4-substitution in many instances is highly deleterious to the activity of the molecule. The 'activating' group on the beta-lactam nitrogen, responsible for the activation of the beta-lactam ring can be varied quite widely while retaining high intrinsic activity. The O-activated compounds although showing the potential for broad-spectrum activity are beta-lactamase unstable, while the beta-lactamase stable compounds tend to show preferential activity against Gram-negative rods. There can be little doubt that additional activating groups will be incorporated on the monocyclic beta-lactam ring and it will be interesting to see what additional properties can be achieved by this approach.