Cethromycin (formerly ABT-773) is a ketolide antibiotic originally
developed by Abbott in the late 1990s, but abandoned in 2002. Since
2004, Advanced Life Sciences has promoted current development of
cethromycin. The ketolides are structurally derived from erythromycin
A and are designed to overcome resistance to macrolides. One of the
main features is the lack of the neutral sugar L-cladinose at position 3
of the erythonolide ring, which is replaced by a keto group (thus giving
rise to the class name). Lack of the L-cladinose
moiety results in better drug absorption and less gastric irritation
through improved acid stability.
Cethromycin is a 6-O-ketolide, meaning that, compared with 11-Nketolides such as telithromycin, linkage with the macrolactone ring is in the 6-O-position, with an O-propylallyl linkage replacing the aminopropyl linkage of telithromycin. Cethromycin presents as a white crystalline powder. As yet, cethromycin has been used only in clinical trials and is not available for clinical use. Development is primarily directed at upper and lower respiratory tract infections.
ChEBI: Cethromycin is a macrolide antibiotic which displays in vitro activity against both gram-positive and gram-negative bacteria and is currently under investigation for the treatment of community-acquired pneumonia. The US Food and Drug Administration (FDA) have also granted orphan drug designation to cethromycin for the treatment of anthrax prophylaxis, tularemia, and plague (PDB entry: 1NWX). It has a role as an antibacterial drug and a protein synthesis inhibitor. It is a macrolide antibiotic, a member of quinolines and a monosaccharide derivative.
Oral bioavailability of cethromycin has been poorly studied in humans. Animal studies report values ranging from approximately 36% to 50%. Absorption of cethromycin appears to be dose dependent with time to Cmax increasing from 0.9 to 5.1 hours with increasing dosage. Food does not appear to exert meaningful effects on the pharmacokinetics of cethromycin, but this aspect deserves additional study. In a study on the effects of drug co-administration on the pharmacokinetics of cethromycin, ranitidine was found to significantly reduce cethromycin Cmax concentrations, by 25.7%. Conversely, sucralfate had no effect on cethromycin concentrations. The degree of serum protein binding is considered to approach 90%.
The mechanism of action is similar to macrolides and is based on interaction with the peptidyl transferase site of the 50S ribosomal subunit, thus inhibiting the translation of rRNAs and preventing the elongation step of protein synthesis. In addition, cethromycin also interferes at an earlier stage of protein synthesis by disrupting the assembling of 50S subunit precursors to block the formation of a functional 50S subunit. Ketolides in general (including cethromycin) inhibit protein synthesis by binding to the 50S ribosomal subunit, close to the peptidyl transferase site at the entrance of the ribosomal exit tunnel. The presence of a 3-keto group in place of the L-cladinose moiety, common to all ketolides, allows cethromycin to bind to the ribosomal target in the 23S rRNA domain V without causing expression of ribosomal mutations. The additional flexible side chain (in the 6-O position for cethromycin) attached to the macrocyclic ring allows binding to an additional ribosomal site. This dual binding affinity increases the binding affinity of cethromycin several-fold compared with that of erythromycin. It is probably also responsible for overcoming resistance mediated by both the ribosomal mutations (erm) and efflux pump (mef) mechanisms. This leads to an enhanced activity against S. pneumoniae, including most of the macrolide-resistant strains. Conversely, the methoxy group at position C-6 provides greater acid stability than that of other macrolides, and is related to greater gastrointestinal stability.
Ketolides and macrolides are substrates and inhibitors of the
cytochrome P450 (CYP450) 3A4 system. So far, data available
specifically for cethromycin are very limited and mainly exist in
abstract form. It is expected that interactions are similar to other drugs
that are involved in this pathway. This is exemplified by ketoconazole,
a potent CYP3A4 inhibitor that caused a 5-fold increase in
cethromycin AUC and a 2.5-fold increase in drug Cmax, although
cethromycin’s main metabolite showed a decreased Cmax but no effect
on its AUC. Similarly, rifampicin (600 mg)
significantly affected the pharmacokinetics of cethromycin (300 mg),
with a 95% reduction in the ketolide’s AUC and its metabolite
N-desmethyl cethromycin.
