C-Terminus Two N-TerminiIonsChannel C-Terminus(a) (b)(HOOC)Val−Gly−Ala−Leu−Ala−Val−Val−Val−Trp−Leu
HOCH 2 CH 2 NHTrp−Leu−Trp−Leu−TrpDL D L D LL L D L D L D L(Configurations)3HNCHH 3 CCH 3COO
CH 3CONH
CH
H 3 C CH 3C COO CH
HCH
CHHCOCHCH CH^3
3D-Valine L-Lactic L-Valine
acidD-Hydroxy
isovaleric acidFigure 7.1 The general mode of action of ionophores in ion transport. (a) A channel formed by
two gramicidin A molecules, N-terminus to N-terminus. (b) The sequence of events in the
operation of a carrier ionophore such as valinomycin. Valinomycin is a cyclic peptide consisting
of three repeating units with the structure shown7. 2. 2. 2 Cell wall synthesis inhibition
The cell walls (Appendix 3) of all bacteria are being continuously replaced
because they are continuously being broken down by enzymes in the extracellu-
lar fluid. Antibacterial agents, commonly referred to as antibiotics, often act by
inhibiting this replacement biosynthesis of the cell wall at any stage in its
formation. Most drugs that act in this fashion inhibit either the formation of
the precursor starting compounds, the formation of the peptidoglycan chains or
the cross linking of the peptidoglycan (Table 7.2). However, increasing numbers
of bacteria are resistant to antibiotics, especially tob-lactam antibiotics. This
resistance is likely to become a major problem in the future.
The activity of the penicillins and cephalosporins is believed to be due to the
b-lactam ring. Bacterial resistance to these drugs is thought to be mainly due to
inactivation of the drug by hydrolysis of theb-lactam ring by theb-lactamases
produced by the bacteria. Both Gram-positive and Gram-negative bacteria
(Appendix 2) produceb-lactamases. In the former case, the enzyme is liberated
into the medium surrounding the the bacteria, which results in the hydrolysis of
136 SELECTED EXAMPLES OF DRUG ACTION AT SOME COMMON TARGET AREAS