Macrolide antibiotics inhibition

Champney, W. S., and Burdine, R. (1995). Macrolide antibiotics inhibit SOS ribosomal subunit assembly in Bacillus subtilis and Staphylococcus aureus. Antimicrob. Agents Chemother. 39, 2141-2144. 

Watkins, P.B., S.A. Wrighton, E.G. Schuetz, P. Mawel, and PS. Guzelian (1986). Macrolide antibiotics inhibit the degradation of the glucocorticoid-responsive cytochrome P-450p in rat hepa-tocytes in vivo and in primary monolayer culture. J. Biol. Chem. 261, 6264-6271. 

Macrolide antibiotics inhibit CBZ metabolism, thus increasing CBZ plasma levels and decreasing clearance with the potential for toxicity effects. Drug-induced changes in CBZ pharmacokinetics are particularly pronounced in children (28). 

The macrolide erythromycin inhibits protein synthesis and resistance is induced by N -dimethyl-ation of adenine within the 23S rRNA, which results in reduced affinity of ribosomes for antibiotics related to erythromcin (Skinner et al. 1983). Sulfonamides function by binding tightly to chromosomal dihydropteroate synthetase and resistance to sulfonamides is developed in the resistance plasmid through a form of the enzyme that is resistant to the effect of sulfonamides. 

Sirolimus is currently the only FDA-approved ToR inhibitor. One of its derivatives, everolimus, is in phase III clinical trials and has been approved for use in some European countries.30 Sirolimus is a macrolide antibiotic that has no effect on cal-cineurin phosphatase.11,31,32 Sirolimus inhibits T cell activation and proliferation by binding to and inhibiting the activation of the mammalian ToR, which suppresses cellular response to IL-2 and other cytokines (i.e., IL-4 and IL-15J.11,31 Studies have shown that sirolimus may be used safely and effectively with either cyclosporine or tacrolimus as a replacement for either azathioprine or mycophenolate mofetil.33 However, when using both sirolimus and cyclosporine as part of a patient s immunosuppressant therapy, because of a drug interaction between the two resulting in a marked increase in sirolimus concentrations, it is recommended to separate the sirolimus and cyclosporine doses by at least 4 hours. Sirolimus also can be used as an alternative agent for patients who do not tolerate calcineurin inhibitors due to nephrotoxicity or other adverse events.34... 

Jurima-Romet, M., Crawford, K. et al. (1994). Terfenadine metabolism in human liver. In vitro inhibition by macrolide antibiotics and azole antifungals. Drug Metab. Dispos., 22(6), 849-57. 

Zotarolimus (53 Endeavor stent) Sirolimus (33) Macrolide antibiotic Semi-synthetic NP Microbial Cardiovascular surgery Inhibits cell proliferation, preventing scar tissue formation and minimizes restenosis in angioplasty patients 467 74... 

Everolimus (40 Afinitor ) Sirolimus (34) Macrolide antibiotic Semi-synthetic NP Microbial Anticancer Inhibits mTOR kinase activity 375-382... 

Pharmacology Macrolide antibiotics reversibly bind to the P site of the SOS ribosomal subunit of susceptible organisms and inhibit RNA-dependent protein synthesis. They may be bacteriostatic or bactericidal, depending on such factors as drug concentration. 

Rapamycin (sirolimus), a macrolide antibiotic, has been used recently in organ transplantation for its potent immunosuppressive actions by inhibiting both cytokine mediated and growth factor mediated proliferation of smooth muscle cells and lymphocytes [55, 56]. In the RAVEL trial of non-acute single vessel lesions, the Sirolimus-eluting stent was compared to bare metal stent (BMS) in a 1 1 fashion [57]. One-year major adverse cardiovascular events and 6 month neointimal proliferation as assessed by late luminal loss (-0.01 0.33 mm in Sirolimus stent versus 0.80 0.53 mm in BMS) were improved. The Sirolimus-eluting stent thus virtually eliminated in-stent restenosis with no evidence of edge effect, dissection, or in-stent thrombosis. 

Tacrolimus (previously known as FK506) is a macrolide antibiotic which is obtained from the fungus Streptomyces tsukubaensis. Tacrolimus binds in-tracellularly to the protein FKBP (FK binding protein) which is distinct from the protein that binds cyclosporine. However both drug-protein complexes associate in a similar way with calcineurin and inhibits its serine/threonine phosphatase activity, although the immunosuppressive potency of tacrolimus is approximately 100 fold higher than that of cyclosporine. 

Although it is not chemically related to cyclosporine, tacrolimus (6.7) has a similar mechanism of action. Tacrolimus is an immunosuppressant macrolide antibiotic derived from Streptomyces tsukubaenis. Like cyclosporine, tacrolimus inhibits the same cytoplasmic phosphatase, calcineurin, which catalyzes the activation of a T-cell-specific transcription factor (NF-AT) involved in the biosyntheses of interleukins such as IL-2. Sirolimus (6.8) is a natural product produced by Streptomyces hydroscopicus, it blocks the ability of T cells to respond to cytokines. 

It is an immunosuppressant macrolide antibiotic produced by Streptomyces tsukubaensis. Like cyclosporine, tacrolimus binds to a cytoplasmic immunophylin and the complex inhibits the activity of the calcium dependent phosphatase known as calcineurin. This in turn, inhibits the translocation of the transcription factor NF-AT into the cell nucleus, blocking the initiation of NF-AT dependent T-cell responses. It is indicated in atopic dermatitis. 

Maximal plasma concentrations occur 2 to 3 hours after oral administration of reboxetine (178). Reboxetine has linear pharmacokinetics over its clinically relevant dosing range and a half-life of approximately 12 hours. For this latter reason, a twice a day, equally divided dosing schedule was used during clinical trial development. Its clearance is reduced and half-life becomes longer as a function of advanced age (mean = 81 years of age) and renal and hepatic impairment ( 178, 322, 323). Reboxetine is principally metabolized by CYP 3A3/4 such that its dose should be reduced when used in combination with drugs that are substantial inhibitors of CYP (e.g., certain azole antifungals, certain macrolide antibiotics). Reboxetine itself, however, does not cause detectable inhibition of CYP 3A3/4 based on formal in vivo pharmacokinetic interaction studies as well as its own linear pharmacokinetics. 

Nefazodone substantially decreases the clearance rate for triazolam, which results in a 400% increase in triazolam s serum levels (131). Erythromycin can also interfere with the metabolism of triazolam, resulting in decreased clearance and increased plasma levels, possibly causing toxicity. Troleandomycin and other macrolide antibiotics, such as clarithromycin, flurithromycin, josamycin, midecamycin, or roxithromycin, also may inhibit triazolam s metabolism (132). The coadministration of itraconazoie and triazolam can produce a marked elevation of triazolam plasma levels associated with statistically significant impairment of psychomotor tests and a prolongation of other effects (e.g., amnesia, lethargy, and confusion) for hours after awakening ( 133). 

With the important exception of additive effects when combined with other CNS depressants, including alcohol, BZDs interact with very few drugs. Disulfiram (see the section The Alcoholic Patient in Chapter 14) and cimetidine may increase BZD blood levels, and diazepam may increase blood levels of digoxin and phenytoin. Antacids may reduce the clinical effects of clorazepate by hindering its biotransformation to desmethyidiazepam. Coadministration of a BZD and another drug known to induce seizures may possibly increase seizure risk, especially if the BZD is abruptly withdrawn. Furthermore, as noted earlier, important interactions have been reported among nefazodone, erythromycin, troleandomycin, and other macrolide antibiotics, as well as itraconazole. In each case, metabolism is inhibited, and triazolam levels can increase significantly. 

Rapamycin, also known as sirolimus, is a new macrolide antibiotic that interacts with cellcycle regulating proteins and inhibits cell division. The main side effects are thrombocytopenia and hyperlipidaemia. There is also evidence that it causes interstitial pneumonitis, which may resolve on withdrawing the drug or dose reduction. The drug is currently being assessed for combination therapy with tacrolimus or cyclosporin. 

The catabolism of lovastatin, simvastatin, and atorvastatin proceeds chiefly through CYP3A4, whereas that of fluvastatin and rosuvastatin is mediated by CYP2C9. Pravastatin is catabolized through other pathways, including sulfation. The 3A4-dependent reductase inhibitors tend to accumulate in plasma in the presence of drugs that inhibit or compete for the 3A4 cytochrome. These include the macrolide antibiotics, cyclosporine, ketoconazole and its congeners, HIVprotease inhibitors, tacrolimus, nefazodone, fibrates, and others (see Chapter 4). Concomitant use of reductase inhibitors with amiodarone or verapamil also causes an increased risk of myopathy. 

Tacrolimus (FK 506) is an immunosuppressant macrolide antibiotic produced by Streptomyces tsukubaensis. It is not chemically related to cyclosporine, but their mechanisms of action are similar. Both drugs bind to cytoplasmic peptidyl-prolyl isomerases that are abundant in all tissues. While cyclosporine binds to cyclophilin, tacrolimus binds to the immunophilin FK-binding protein (FKBP). Both complexes inhibit calcineurin, which is necessary for the activation of the T-cell-specific transcription factor NF-AT. 

Macrolide antibiotics target the bacterial ribosome and inhibit the bacterial protein biosynthesis. Many gram-negative bacteria are inherently resistant to mac-rolides because their outer membrane is impermeable to macrolides. Several mechanisms of acquired resistance have been reported. In some cases, resistance is conferred by methylation of ribosomes by methylase enzymes, the genes of... 

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