Aminoglycosides

Description

The aminoglycoside antibiotics comprise a large group of naturally occurring or semisynthetic polycationic compounds. The therapeutically important members of the group have amino sugars glycosidically linked to aminocyclitols – cyclic alcohols that are also substituted with amino functions. Most are bactericidal agents and share the same general range of antibacterial activity, pharmacokinetic behavior, a tendency to damage one or both branches of the eighth nerve, and a propensity to cause renal damage. The degree and nature of toxicity varies among compounds, and for some it is so great as to preclude systemic use.
Streptomycin was the first aminoglycoside, identified in 1944 by Waksman’s group as a natural product of a soil bacterium, Streptomyces griseus. This was followed by the discovery of neomycin by the same group in 1949 and of kanamycin by Umezawa and his colleagues in 1957. Gentamicin, the most important aminoglycoside in use today, was first reported in 1963. Thereafter there followed an era in which research on new aminoglycosides concentrated on the chemical modification of known compounds, largely in response to developing resistance.

Acquired Resistance

Resistance in many organisms originally susceptible to the older compounds, such as streptomycin and kanamycin, is now widespread. Resistance to the more clinically important agents such as gentamicin has also increased, but there are marked differences even within countries depending on antibiotic use policies. Resistance rates for gentamicin in North America and Europe have so far generally remained low. However, many strains with plasmid-encoded extended- spectrum β-lactamases (p. 228–231) and other resistances are also aminoglycoside resistant, so outbreaks of infection with such strains may result in an increase in aminoglycoside resistance rates.
Bacterial resistance to the aminoglycosides is usually mediated through one, or more, of the three main mechanisms:
• Alteration in the ribosomal binding of the drug
• Reduced uptake
• Inactivation by specific aminoglycoside-modifying enzymes.

Mode of action

Much of the literature on the mode of action of aminoglycosides has concentrated on streptomycin. However, the action of gentamicin and other deoxystreptamine-containing aminoglycosides is clearly not identical, since single-step, high-level resistance to streptomycin, which is due to a change in a specific protein (S12) of the 30S ribosomal subunit, does not extend to other aminoglycosides.
Elucidation of the mode of action of aminoglycosides has been complicated by the need to reconcile a variety of enigmatic observations:
• Streptomycin and other aminoglycosides cause misreading of mRNA on the ribosome while paradoxically halting protein synthesis completely by interfering with the formation of functional initiation complexes.
• Inhibition of protein synthesis by aminoglycosides leads not just to bacteristasis as with, for example, tetracycline or chloramphenicol, but also to rapid cell death.
• Susceptible bacteria (but not those with resistant ribosomes) quickly become leaky to small molecules on exposure to the drug, apparently because of an effect on the cell membrane.
A complete understanding of these phenomena has not yet been achieved, but the situation is slowly becoming clearer. The two effects of aminoglycosides on initiation and misreading may be explained by a concentration-dependent effect on ribosomes engaged in the formation of the initiation complex and those in the process of chain elongation:16 in the presence of a sufficiently high concentration of drug, protein synthesis is completely halted once the mRNA is run off because reinitiation is blocked; under these circumstances there is little or no opportunity for misreading to occur. However, at concentrations at which only a proportion of the ribosomes can be blocked at initiation, some protein synthesis will take place and the opportunity for misreading will be provided.
The mechanism of misreading has been clarified by recent structural information on the interaction of streptomycin with the ribosome.13 Streptomycin binds near to the A site through strong interactions with four nucleotides in 16S rRNA and one residue in protein S12. This tight binding promotes a conformational change which stabilizes the so-called ram state in the ribosome which reduces the fidelity of translation by allowing non-cognate aminoacyl-tRNAs to bind easily to the A site.
The effects of aminoglycosides on membrane permeability, and the potent bactericidal activity of these compounds, remain enigmatic. However, the two phenomena may be related.17 The synthesis and subsequent insertion of misread proteins into the cytoplasmic membrane may lead to membrane leakiness and cell death.

Raw materials

Preparation Products