Antibacterial drugs
- Inhibitors of Protein Synthesis
- Aminoglycosides
- Structure consists of a cyclohexane rings and amino sugars
- Some examples include Streptomycin, Kanamycin, Neomycin, Tobramycin synthesized by Streptomyces
- Gentamycin is produced by Micromonospora purpurea
- They bind to 30S ribosomal subunit and inhibit protein synthesis by causing misreading of the mRNA
- Bactericidal
- Effective against gram negative pathogens
- Aminoglycosides
- Tetracyclines
- 4 ringed structure with different side chains
- Oxytetracline and Chlortetracycline are natural antibiotics produced by Streptomyces
- Some other semi-synthetic drugs are also available
- Bind 30S ribosomal subunit and blocks binding of aminoacyl tRNA at the A site of ribosome. Hence, inhibits protein synthesis
- Bacteriostatic
- Broad spectrum being active against gram-negative and gram positive bacteria, rickettsias, chlamydiae and mycoplasmas
- Used to treat acne
- Macrolides
- Contains 12-22 C lactone rings and sugars
- Erythromycin binds to 23S rRNA of 50S ribosomal subunit and inhibits peptidyl transferase reaction. Peptidyl transferase adds the growing peptide chain at the P site of ribosome to the next amino acid held by the tRNA at A site. This prevents growth of the peptide chain
- Used for whooping cough and diarrhoea
- Other examples include clindamycin, azithromycin
- Chloramphenicol
- First obtained from Streptomyces venezuelae but now synthesized chemically
- Binds to 23S rRNA of 50S ribosomal subunit and inhibits peptidyl transferase reaction. Peptidyl transferase adds the growing peptide chain at the P site of ribosome to the next amino acid held by the tRNA at A site. This prevents growth of the peptide chain
- Being highly toxic it is used a drug of choice during aplastic anaemia, leukopenia and other life-threatening situations
- Inhibitors of Nucleic acid Synthesis
- Made up of quinolone rings
- Do not have a selective toxicity as prokaryotes and eukaryotes do not differ greatly with respect to nucleic acid synthesis
- Synthetic antibiotics
- Examples are Nalidixic acid (quinolone), fluroquinolones – ciprofloxacine, ofloxacine, norofloxacine
- Quinolones inhibit DNA gyrase which introduces negative twist in DNA and helps separate its strand. Inhibition of DNA gyrase disrupts DNA replication and repair and chromosome separation during cell division
- Fluoroquinolone inhibits topoisomerase II that untangles DNA during replication and affects in the same way as quinolones
- Rifampicin inhibits RNA polymerase thereby preventing transcription
- Quinolones are broad spectrum antibiotics and usually administered orally
- Metabolic Antagonists
- These drugs are bacteriostatic but broad spectrum
- Sulfonamides
- Synthetic antibiotic
- Structurally related to sulphanilamide
- They are analogous to para-aminobenzoic acid, thus competitively inhibit the enzyme that uses PABA as its substrate and consequently inhibits folate synthesis
- Folate is an important vitamin to bacteria used for synthesis of purines and pyrimidines that form the building blocks of DNA and RNA. Absence of folic acid causes them to die
- Have high therapeutic index since eukaryotes do not synthesize folate hence very safe to eukaryotic cells
- Sulfonamides
- These drugs are bacteriostatic but broad spectrum
- Trimethoprim
- Synthetic antibiotic
- Broad spectrum antibiotic
- Binds to Dihydrofolate reductase that converts dihydrofolate to tetrahydrofolate in folic acid synthesis. This inhibits this metabolic process and causes death of the pathogens
- Both drugs are given together for synergistic effect