VancomycinOO OClHOCH 2R 2 OHNHH
NH−COCHNHCOCHNHCOCHNHCOCHNHCOCHCHOH NHCH 3CH 2 CH(CH 3 ) 2HOOH
OHH
HOOCOCH 2 CONH 2OR 1 OHHOHOClSN
OHO
CH 3
CH 3H COOHON
OO CH 2 OHHHH COOHClavulanic acidSulbactamFigure 7.2 (a)b-Lactamase inhibitors and (b) theb-lactamase resistant drug vancomycintheb-lactam ring before the drug reaches the bacteria. However, with Gram-
negative bacteria, the hydrolysis takes place within the periplasmic space. In
addition, some Gram-negative bacteria produceacylases, which can cleave the
side chains of penicillins. Bacteria that have developed a resistance tob-lactam
antibiotics are treated using either a dosage form incorporating ab-lactamase
inhibitor, such as clavulanic acid or sulbactam, or a lactamase resistant drug,
such as vancomycin (Figure 7.2).
7.3 Drugs that target enzymes
Enzymes (Appendix 7) are often targets in drug design. Inhibition offers a
method of either preventing or regulating the chemical reactions occuring in
pathological conditions. Selecting a lead for an enzyme target requires either a
detailed knowledge of the biochemistry of the pathological condition or using
techniques such as computational (Chapter 5) and combinatorial chemistry
(Chapter 6). One advantage of targeting enzymes is that an enzyme process
that occurs in a pathogen may not occur in humans. This means that an
inhibitor active in a pathogen should not inhibit the same process in humans.
Enzyme inhibitors (I) may have either a reversible or irreversible action.
Reversible inhibitors tend to bind to an enzyme (E) by electrostatic bonds,
hydrogen bonds and van der Waals’ forces, and so tend to form an equilibrium
system with the enzyme. A few reversible inhibitors bind by weak covalent
bonds, but this is the exception rather than the rule. Irreversible inhibitors
138 SELECTED EXAMPLES OF DRUG ACTION AT SOME COMMON TARGET AREAS