Ketolides in the treatment of respiratory infections

The ketolides are a new class of macrolides specifically designed to combat respiratory tract pathogens that have acquired resistance to macrolides. The ketolides are semi-synthetic derivatives of the 14-membered macrolide erythromycin A. There are currently two ketolides in the late stages of clinical development in the US (telithromycin [HMR-364, Kelek; Aventis] and ABT-773 [Abbot Laboratories]), as well as newer compounds in earlier stages of testing. Ketolides have a mechanism of action very similar to that of erythromycin A. They potently inhibit protein synthesis by interacting close to the peptidyl transferase site of the bacterial 50S ribosomal subunit. Ketolides bind to ribosomes with higher affinity than macrolides. The ketolides exhibit good activity against Gram-positive and some Gram-negative aerobes and have are active against macrolide-resistant Streptococcus species, including most mef A and erm B strains of Streptococcus pneumoniae. Ketolides have pharmacokinetics which allow once-daily dosing and extensive tissue distribution with very high uptake into respiratory tissues and fluids relative to serum. Evidence suggests the ketolides are primarily metabolised by the cytochrome P450 (CYP) enzyme system in the liver and that elimination is a combination of biliary, hepatic and urinary excretion. Clinical trial data are only available for telithromycin and have focused on respiratory tract infections (RTIs) including community-acquired pneumonia (CAP), acute exacerbations of chronic bronchitis (AECB), sinusitis and streptococcal pharyngitis. Bacteriological and clinical cure rates have been similar to comparators. Ketolides have similar safety profiles to the newer macrolides. In summary, early clinical trials support the clinical efficacy of the ketolides in common RTIs, including activity against macrolide-resistant pathogens.     

Ketolides in the treatment of respiratory infections

The ketolides are a new class of macrolides specifically designed to combat respiratory tract pathogens that have acquired resistance to macrolides. The ketolides are semi-synthetic derivatives of the 14-membered macrolide erythromycin A. There are currently two ketolides in the late stages of clinical development in the US (telithromycin [HMR-364^®, Kelek^®; Aventis] and ABT-773 [Abbot Laboratories]), as well as newer compounds in earlier stages of testing. Ketolides have a mechanism of action very similar to that of erythromycin A. They potently inhibit protein synthesis by interacting close to the peptidyl transferase site of the bacterial 50S ribosomal subunit. Ketolides bind to ribosomes with higher affinity than macrolides. The ketolides exhibit good activity against Gram-positive and some Gram-negative aerobes and have are active against macrolide-resistant Streptococcus species, including most mefA and ermB strains of Streptococcus pneumoniae. Ketolides have pharmacokinetics which allow once-daily dosing and extensive tissue distribution with very high uptake into respiratory tissues and fluids relative to serum. Evidence suggests the ketolides are primarily metabolised by the cytochrome P450 (CYP) enzyme system in the liver and that elimination is a combination of biliary, hepatic and urinary excretion. Clinical trial data are only available for telithromycin and have focused on respiratory tract infections (RTIs) including community-acquired pneumonia (CAP), acute exacerbations of chronic bronchitis (AECB), sinusitis and streptococcal pharyngitis. Bacteriological and clinical cure rates have been similar to comparators. Ketolides have similar safety profiles to the newer macrolides. In summary, early clinical trials support the clinical efficacy of the ketolides in common RTIs, including activity against macrolide-resistant pathogens.     

Ketolides: an emerging treatment for macrolide-resistant respiratory infections,focusing on S. pneumoniae

Resistance to antibiotics in community acquired respiratory infections is increasing worldwide. Resistance to the macrolides can be class-specific, as in efflux or ribosomal mutations, or, in the case of erythromycin ribosomal methylase (erm)-mediated resistance, may generate cross-resistance to other related classes. The ketolides are a new subclass of macrolides specifically designed to combat macrolide-resistant respiratory pathogens. X-ray crystallography indicates that ketolides bind to a secondary region in domain II of the 23S rRNA subunit, resulting in an improved structure–activity relationship. Telithromycin and cethromycin (formerly ABT-773) are the two most clinically advanced ketolides, exhibiting greater activity towards both typical and atypical respiratory pathogens. As a subclass of macrolides, ketolides demonstrate potent activity against most macrolide-resistant streptococci, including ermB- and macrolide efflux (mef)A-positive Streptococcus pneumoniae. Their pharmacokinetics display a long half-life as well as extensive tissue distribution and uptake into respiratory tissues and fluids, allowing for once-daily dosing. Clinical trials focusing on respiratory infections indicate bacteriological and clinical cure rates similar to comparators, even in patients infected with macrolide-resistant strains.     

Ketolides: an emerging treatment for macrolide-resistant respiratory infections, focusing on S. pneumoniae

Resistance to antibiotics in community acquired respiratory infections is increasing worldwide. Resistance to the macrolides can be class-specific, as in efflux or ribosomal mutations, or, in the case of erythromycin ribosomal methylase (erm)-mediated resistance, may generate cross-resistance to other related classes. The ketolides are a new subclass of macrolides specifically designed to combat macrolide-resistant respiratory pathogens. X-ray crystallography indicates that ketolides bind to a secondary region in domain II of the 23S rRNA subunit, resulting in an improved structure-activity relationship. Telithromycin and cethromycin (formerly ABT-773) are the two most clinically advanced ketolides, exhibiting greater activity towards both typical and atypical respiratory pathogens. As a subclass of macrolides, ketolides demonstrate potent activity against most macrolide-resistant streptococci, including ermB- and macrolide efflux (mef)A-positive Streptococcus pneumoniae. Their pharmacokinetics display a long half-life as well as extensive tissue distribution and uptake into respiratory tissues and fluids, allowing for once-daily dosing. Clinical trials focusing on respiratory infections indicate bacteriological and clinical cure rates similar to comparators, even in patients infected with macrolide-resistant strains.     

The ketolides: a critical review

Ketolides are a new class of macrolides designed particularly to combat respiratory tract pathogens that have acquired resistance to macrolides. The ketolides are semi-synthetic derivatives of the 14-membered macrolide erythromycin A, and retain the erythromycin macrolactone ring structure as well as the D-desosamine sugar attached at position 5. The defining characteristic of the ketolides is the removal of the neutral sugar, L-cladinose from the 3 position of the ring and the subsequent oxidation of the 3-hydroxyl to a 3-keto functional group. The ketolides presently under development additionally contain an 11, 12 cyclic carbamate linkage in place of the two hydroxyl groups of erythromycin A and an arylalkyl or an arylallyl chain, imparting in vitro activity equal to or better than the newer macrolides. Telithromycin is the first member of this new class to be approved for clinical use, while ABT-773 is presently in phase III of development. Ketolides have a mechanism of action very similar to erythromycin A from which they have been derived. They potently inhibit protein synthesis by interacting close to the peptidyl transferase site of the bacterial 50S ribosomal subunit. Ketolides bind to ribosomes with higher affinity than macrolides. The ketolides exhibit good activity against Gram-positive aerobes and some Gram-negative aerobes, and have excellent activity against drug-resistant Streptococcus pneumoniae, including macrolide-resistant (mefA and ermB strains of S. pneumoniae). Ketolides such as telithromycin display excellent pharmacokinetics allowing once daily dose administration and extensive tissue distribution relative to serum. Evidence suggests the ketolides are primarily metabolised in the liver and that elimination is by a combination of biliary, hepatic and urinary excretion. Pharmacodynamically, ketolides display an element of concentration dependent killing unlike macrolides which are considered time dependent killers. Clinical trial data are only available for telithromycin and have focused on respiratory infections including community-acquired pneumonia, acute exacerbations of chronic bronchitis, sinusitis and streptococcal pharyngitis. Bacteriological and clinical cure rates have been similar to comparators. Limited data suggest very good eradication of macrolide-resistant and penicillin-resistant S. pneumoniae. As a class, the macrolides are well tolerated and can be used safely. Limited clinical trial data suggest that ketolides have similar safety profiles to the newer macrolides. Telithromycin interacts with the cytochrome P450 enzyme system (specifically CYP 3A4) in a reversible fashion and limited clinically significant drug interactions occur. In summary, clinical trials support the clinical efficacy of the ketolides in upper and lower respiratory tract infections caused by typical and atypical pathogens including strains resistant to penicillins and macrolides. Considerations such as local epidemiology, patterns of resistance and ketolide adverse effects, drug interactions and cost relative to existing agents will define the role of these agents. The addition of the ketolides in the era of antibacterial resistance provides clinicians with more options in the treatment of respiratory infections.     

The macrolide-bacterium interaction and its biological basis

Erythromycin, the first antibacterial macrolide introduced into the clinical setting over 50 years ago, was used extensively not only for the treatment of respiratory tract infections in both adults and children, but also for bone and soft tissue infections, and specific sexually transmitted diseases. Macrolide antibiotics have undergone a dramatic chemical evolution over the past 50 years, culminating in the improved 14- and 16-membered macrolides, acylides and new ketolides. In all cases, improvements in antibacterial activity involved changes in the interplay between the chemical structure of the macrolide and the components of the bacterial cell that dictate ultimate antibacterial activity and efficacy. Target site modification by methylation of ribosomal RNA, the so-called Macrolide-Streptogramin-Lincosamide, (MLS0 resistance and active efflux are the two most common forms of resistance present in the clinic today; however, other resistance mechanisms are known. The first macrolide that bound to MLS-resistant ribosomes was reported in 1989, demonstrating that appropriate structural changes could regain access to the modified ribosome-binding site. In addition, macrolide analogs with reduced affinity for the active efflux pump were identified in 1990, demonstrating that features of pump recognition could be separated from ribosome binding site recognition. Progressive medicinal chemistry led to the synthesis and development of the more recent ketolide class, which combines attributes of both prototypes into one molecule, i.e. non-recognition by the efflux pump and regaining some access to the modified ribosome binding site. Ketolide also lack of induction of erm methylase as do 16-member macrolides.     

Review of macrolides and ketolides: focus on respiratory tract infections

The first macrolide, erythromycin A, demonstrated broad-spectrum antimicrobial activity and was used primarily for respiratory and skin and soft tissue infections. Newer 14-, 15- and 16-membered ring macrolides such as clarithromycin and the azalide, azithromycin, have been developed to address the limitations of erythromycin. The main structural component of the macrolides is a large lactone ring that varies in size from 12 to 16 atoms. A new group of 14-membered macrolides known as the ketolides have recently been developed which have a 3-keto in place of the L-cladinose moiety. Macrolides reversibly bind to the 23S rRNA and thus, inhibit protein synthesis by blocking elongation. The ketolides have also been reported to bind to 23S rRNA and their mechanism of action is similar to that of macrolides. Macrolide resistance mechanisms include target site alteration, alteration in antibiotic transport and modification of the antibiotic. The macrolides and ketolides exhibit good activity against gram-positive aerobes and some gram-negative aerobes. Ketolides have excellent activity versus macrolide-resistant Streptococcus spp. Including mefA and ermB producing Streptococcus pneumoniae. The newer macrolides, such as azithromycin and clarithromycin, and the ketolides exhibit greater activity against Haemophilus influenzae than erythromycin. The bioavailability of macrolides ranges from 25 to 85%, with corresponding serum concentrations ranging from 0.4 to 12 mg/L and area under the concentration-time curves from 3 to 115 mg/L x h. Half-lives range from short for erythromycin to medium for clarithromycin, roxithromycin and ketolides, to very long for dirithromycin and azithromycin. All of these agents display large volumes of distribution with excellent uptake into respiratory tissues and fluids relative to serum. The majority of the agents are hepatically metabolised and excretion in the urine is limited, with the exception of clarithromycin. Clinical trials involving the macrolides are available for various respiratory infections. In general, macrolides are the preferred treatment for community-acquired pneumonia and alternative treatment for other respiratory infections. These agents are frequently used in patients with penicillin allergies. The macrolides are well-tolerated agents. Macrolides are divided into 3 groups for likely occurrence of drug-drug interactions: group 1 (e.g. erythromycin) are frequently involved, group 2 (e.g. clarithromycin, roxithromycin) are less commonly involved, whereas drug interactions have not been described for group 3 (e.g. azithromycin, dirithromycin). Few pharmacoeconomic studies involving macrolides are presently available. The ketolides are being developed in an attempt to address the increasingly prevalent problems of macrolide-resistant and multiresistant organisms.     

Ketolides: pharmacological profile and rational positioning in the treatment of respiratory tract infections

Ketolides differ from macrolides by removal of the 3-O-cladinose (replaced by a keto group), a 11,12- or 6,11-cyclic moiety and a heteroaryl-alkyl side chain attached to the macrocyclic ring through a suitable linker. These modifications allow for anchoring at two distinct binding sites in the 23S rRNA (increasing activity against erythromycin-susceptible strains and maintaining activity towards Streptococcus pneumoniae resistant to erythromycin A by ribosomal methylation), and make ketolides less prone to induce methylase expression and less susceptible to efflux in S. pneumoniae. Combined with an advantageous pharmacokinetic profile (good oral bioavailability and penetration in the respiratory tract tissues and fluids; prolonged half-life allowing for once-a-day administration), these antimicrobial properties make ketolides an attractive alternative for the treatment of severe respiratory tract infections such as pneumonia in areas with significant resistance to conventional macrolides. For telithromycin (the only registered ketolide so far), pharmacodynamic considerations suggest optimal efficacy for isolates with minimum inhibitory concentration values < or = 0.25 mg/l (pharmacodynamic/pharmacokinetic breakpoint), calling for continuous and careful surveys of bacterial susceptibility. Postmarketing surveillance studies have evidenced rare, but severe, side effects (hepatotoxicity, respiratory failure in patients with myasthenia gravis, visual disturbance and QTc prolongation in combination with other drugs). On these bases, telithromycin indications have been recently restricted by the US FDA to community-acquired pneumonia, and caution in patients at risk has been advocated by the European authorities. Should these side effects be class related, they may hinder the development of other ketolides such as cethromycin (in Phase III, but on hold in the US) or EDP-420 (Phase II).     

The macrolide binding site on the bacterial ribosome

Macrolides are a diverse group of antimicrobials that are widely prescribed in clinical and veterinary medicine. Macrolides inhibit bacterial growth by interacting with the large (50S) subunit of the ribosome and thereby blocking protein synthesis. The liberal application of macrolides and the mechanistically similar lincosamide and streptogramin B compounds has in recent years led to increased prevalence of resistance to these drugs. To counteract this trend and improve the efficacy of treatment, numerous macrolide derivatives have been developed and the latest of these, the ketolides, are now becoming available for clinical use. However, in the on-going battle against resistance pathogens continual improvement of drugs will be necessary, and more efficient means of drug development are required. An indication of how rational drug design might be feasible is offered by the recent crystallographic structures of the bacterial ribosome. These structures give us a view of the macrolide target at previously unseen resolution, enabling us to understand the molecular details of macrolide interaction and resistance, and provide strong clues about potential new drug targets.     

Structural consideration of macrolide antibiotics in relation to the ribosomal interaction and drug design

Macrolide antibiotics exert antimicrobial effects by binding to the peptidyl transferase center of the 50S subunit of bacterial ribosomes and inhibiting protein synthesis. Hence, the structure of macrolides and their interaction with bacterial ribosomes have been investigated in order to understand the structural mechanisms of macrolide-ribosome interaction. Most macrolides have been found tom adopt a common conformation both in crystal form and in solution, which is believed to play an important role for binding to bacterial ribosomes as well as representing bi-facial property essential for excellent biological functions of macrolides. Chemical footprinting and mutant analysis have offered topological information on macrolide-ribosome interaction at the nucleotide level. Recently, crystal structures of the 50S ribosomal subunit and the 50S subunit with macrolide antibiotics have been published. These crystal structures provide much structural information on macrolide-ribosome interaction at the atomic level and will enable structure-based drug design of novel macrolide antibiotics with potent activity against resistant strains.     

Macrolide antibiotic interaction and resistance on the bacterial ribosome

Our understanding of the fine structure of many antibiotic target sites has reached a new level of enlightenment in the last couple of years due to the advent, by X-ray crystallography, of high-resolution structures of the bacterial ribosome. Many classes of clinically useful antibiotics bind to the ribosome to inhibit bacterial protein synthesis. Macrolide, lincosamide and streptogramin B (MLSB) antibiotics form one of the largest groups, and bind to the same site on the 50S ribosomal subunit. Here, we review the molecular details of the ribosomal MLSB site to put into perspective the main points from a wealth of biochemical and genetic data that have been collected over several decades. The information is now available to understand, at atomic resolution, how macrolide antibiotics interact with their ribosomal target, how the target is altered to confer resistance, and in which directions we need to look if we are to rationally design better drugs to overcome the extant resistance mechanisms.     

The emerging new generation of antibiotic: ketolides

The bacterial ribosome is a target for a variety of drug classes including macrolides. Macrolide antibiotics are primarily used for the treatment of respiratory tract infections. One of the most important features of the macrolide class is the excellent safety profile allowing the drug to be used broadly across all age groups. The emergence of macrolide resistance, especially in S. pneumoniae, threatens the long-term usefulness of macrolide antibiotics. The newly developed ketolide class, including telithromycin and ABT-773, evolved from the macrolide class and displays significant improvements over macrolides while maintaining safety profiles similar to macrolides. The key improvement in antimicrobial spectrum is the in vitro potency against macrolide resistant pathogens, especially S. pneumoniae. This review outlines the key improvements of ketolides over macrolides in terms of in vitro microbiology, as well as the pharmacokinetic and pharmacodynamic profiles and updates the current understanding of drug-ribosome interactions. The application of cutting-edge technology such as ribosome structure-based rational drug design and genetic engineering are also briefly discussed.     

30 S核糖体的结构及其与氨基糖苷类抗生素相互作用的新进展

氨基糖苷类抗生素（AGs）是临床上广泛应用的抗生素之一,其靶位是细菌的30S核糖体.现综述30S核糖体的精确结构及几种AGs如链霉素、巴龙霉素、庆大霉素C1a、妥布霉素、潮霉素B、Geneticin与30S核糖体结合方式,从分子水平上理解AGs的作用机制、构效关系和耐药性,指导设计新的抗生素.     

New research in macrolides and ketolides since 1997

Macrolide and ketolide antibacterials remain a very dynamically active group. To overcome erythromycin A resistance within Gram-positive cocci and bacteria, novel compounds have been semi-synthesised, such as ketolides and C-4' carbamate erythromycylamine derivatives. The continual efforts of those studying macrolides have led to molecular level investigations into the mechanism of action of these antibacterials. Among all novel derivatives, only telithromycin and AB-773 are currently under development. No real novel developments have been seen with the 15- and 16-membered ring macrolides, however, research is also continuing in this area. This review is an update of our knowledge in the field of macrolides.     

Protein synthesis as a target for antibacterial drugs: current status and future opportunities

The discovery and development of clinically useful antibiotic classes, such as the aminoglycosides, macrolides and tetracyclines, have clearly demonstrated that bacterial protein synthesis is a suitable target for drug intervention. New information on the binding of classical protein synthesis inhibitors to ribosomal RNA provides a rational explanation for their selective action against bacteria and also explains why chromosomal point mutations conferring resistance by structural changes at the target site are relatively rare in the majority of bacteria. These principles will be helpful when considering strategies for the screening or design of novel protein synthesis inhibitors that could be developed as new antibiotics. Recent progress in the discovery and development of bacterial protein synthesis inhibitors is illustrated by consideration of the glycylcyclines, ketolides, oxazolidinones and streptogramins.     

The streptogramin antibiotics: update on their mechanism of action

Antibiotics of the streptogramin class are an association of two types of chemically different compounds, group A molecules and group B molecules, acting in synergy. The combination of these molecules generally inhibits bacterial growth at a lower concentration than does either the group A or group B molecule alone and is often bactericidal against strains of bacteria for which each type of molecule alone is only bacteriostatic. The semisynthetic streptogramin quinupristin/dalfopristin (RP 59500), the first water-soluble member of this class, is under development for the treatment of severe infections caused by methicillin-resistant Staphylococcus aureus, methicillin-resistant Staphylococcus epidermidis, penicillin-resistant Streptococcus pneumoniae, glycopeptide-resistant Enterococcus faecium, and other organisms. The streptogramins block the translation of mRNA into protein. Both group A and group B molecules bind to the peptidyl-transferase domain of the bacterial ribosome. The group B molecule stimulates the dissociation of peptidyl-tRNA from the ribosome and may interfere with the passage of the completed polypeptide away from the peptidyl-transferase centre. The group A molecule inhibits the elongation of the polypeptide chain by preventing both the binding of aminoacyl-tRNA to the ribosomal A site and the formation of the peptide bond. When the two types of molecule are used in combination, the binding of the group A molecule alters the conformation of the ribosome such that the affinity of the ribosome for the B molecule is increased. This accounts, in part or entirely, for the observed synergy. This synergy is unaffected by ribosomal modifications conferring resistance to the macrolides, lincosamides, and group B molecules alone.     

The streptogramin antibiotics: update on their mechanism of action

Antibiotics of the streptogramin class are an association of two types of chemically different compounds, group A molecules and group B molecules, acting in synergy. The combination of these molecules generally inhibits bacterial growth at a lower concentration than does either the group A or group B molecule alone and is often bactericidal against strains of bacteria for which each type of molecule alone is only bacteriostatic. The semisynthetic streptogramin quinupristin/dalfopristin (RP 59500), the first water-soluble member of this class, is under development for the treatment of severe infections caused by methicillin-resistant Staphylococcus aureus, methicillin-resistant Staphylococcus epidermidis, penicillin-resistant Streptococcus pneumoniae, glycopeptide-resistant Enterococcus faecium, and other organisms. The streptogramins block the translation of mRNA into protein. Both group A and group B molecules bind to the peptidyl-transferase domain of the bacterial ribosome. The group B molecule stimulates the dissociation of peptidyl-tRNA from the ribosome and may interfere with the passage of the completed polypeptide away from the peptidyl-transferase centre. The group A molecule inhibits the elongation of the polypeptide chain by preventing both the binding of aminoacyl-tRNA to the ribosomal A site and the formation of the peptide bond. When the two types of molecule are used in combination, the binding of the group A molecule alters the conformation of the ribosome such that the affinity of the ribosome for the B molecule is increased. This accounts, in part or entirely, for the observed synergy. This synergy is unaffected by ribosomal modifications conferring resistance to the macrolides, lincosamides, and group B molecules alone.     

脲原体耐药机制研究进展

脲原体(包括微小脲原体和解脲脲原体)是引起人类非淋球菌性泌尿生殖道感染的主要病原体之一.四环素类、大环内酯类及喹诺酮类抗生素是治疗脲原体感染的主要药物.随着脲原体对抗生素的耐药情况日趋严重,其耐药机制研究逐渐受到重视.一般认为tetM转座子或整合子介导的核糖体保护作用是脲原体对四环素类耐药的主要机制.23S rRNA操纵子及核糖体相关的L4或L22蛋白的基因突变,可能是脲原体对大环内酯类耐药的原因.对喹诺酮类的主要耐药机制与编码DNA促旋酶和拓扑异构酶Ⅳ亚单位的基因突变有关.     

Macrolide resistance based on the Erm-mediated rRNA methylation

Macrolide, lincosamide and streptogramin B (MLSB) antibiotics are extensively used for the treatment of wide variety of clinically important Gram-positive bacteria. MLSB antibiotics inhibit protein biosynthesis by targeting the peptidyl transferase centre within the 50S ribosomal subunit. The most widespread mechanism of bacterial resistance to MLSB antibiotics, reported early after their introduction into clinical practice is the modification of the target site exhibited by a family of rRNA methyltransferases designated Erm. Using S-adenosyl-L-methionine, Erm enzymes catalyze mono- or dimethylation of a specific adenine residue in the 23S rRNA. The methyl group sterically hinders the MLSB binding site and disrupts the hydrogen bonding between the macrolides and the rRNA, thus rendering bacteria resistant. This review summarizes the current understanding of Erm-mediated resistance, in light of high-resolution structural data of bacterial ribosome and with specific focus on the results of recent genetic, biochemical and structural studies of Erm methyltransferases and their cognate rRNA substrate. Although many features of MLSB resistance remain indistinct, the present knowledge can now serve as the guidance for development of both new antimicrobial drugs and potential inhibitors of Erm enzymes, hence providing a new lead to solve the urgent problem of the macrolide resistance based on the ribosome methylation.     

Molecular analytical evaluation of macrolide- and ketolide-resistant Streptococcus pneumoniae--mechanism of action of telithromycin and resistance to it

PROTEKT (Prospective Resistant Organism Tracking and Epidemiology for the Ketolide Telithromycin) is a worldwide epidemiologic survey for investigating drug susceptibility against major bacterial pathogens in respiratory tract infections, and that is also designed to identify the action mechanism of telithromycin (TEL), a ketolide antibacterial agent, on the resistant Streptococcus pneumoniae and the resistance mechanism for TEL on the TEL-resistant S. pneumoniae strain, in addition to determine macrolide/ketolide resistant S. pneumoniae activities of TEL using molecular analysis. TEL exerted the antibacterial action on the macrolide-resistant S. pneumoniae regardless maintaining the macrolide-resistant mechanism and exhibited the potent antibacterial activity against all of ermB gene-positive strains, mefA gene-positive strains and ribosome variants. This result was considered to reflect the fact that TEL did not induce resistance to ermB and had extremely low ability to select resistant strain by mutation. These actions of TEL were considered to be derived from its novel chemical structure and might be characteristics of ketolides not possessed by macrolides. In the survey of PROTEKT in 1999 to 2002, among 13,864 strains of S. pneumoniae isolated worldwide, ketolide-resistant strain (TEL MIC > or = 4 microg/ml) was observed in 10 strains (0.07%). MIC of these 10 strains was 4 or 8 microg/mL and all of these strains were ermB-positive strains. Based on this fact, potential involvement of adenine demethylase (ermB gene product) was considered in the background of development of ketolide-resistant S. pneumoniae.