Title: Antibiotics: Protein Synthesis, Nucleic Acid Synthesis and Metabolism
1Antibiotics Protein Synthesis, Nucleic Acid
Synthesis and Metabolism
2Principles and Definitions
- Selectivity
- Selectivty8 toxicity9
- Therapeutic index
- Toxic dose/ Effective dose
- Categories of antibiotics
- Bacteriostatic
- Duration of treatment sufficient for host
defenses - Bactericidal
- Usually antibiotic of choice
3Principles and Definitions
- Selectivity
- Therapeutic index
- Categories of antibiotics
- Use of bacteriostatic vs bactericidal antibiotic
- Therapeutic index better for bacteriostatic
antibiotic - Resistance to bactericidal antibiotic
- Protein toxin mediates disease use
bacteriostatic protein synthesis inhibitor
4Principles and Definitions
- Antibiotic susceptibility testing (in vitro)
- Minimum inhibitory concentration (MIC)
- Lowest concentration that results in inhibition
of visible growth - Minimum bactericidal concentration (MBC)
- Lowest concentration that kills 99.9 of the
original inoculum
5Antibiotic Susceptibility Testing
6Zone Diameter Standards for Disk Diffusion Tests
7Principles and Definitions
- Combination therapy
- Prevent emergence of resistant strains
- Temporary treatment until diagnosis is made
- Antibiotic synergism
- Penicillins and aminoglycosides
- CAUTION Antibiotic antagonism
- Penicillins and bacteriostatic antibiotics
- Antibiotics vs chemotherapeutic agents vs
antimicrobials
8Antibiotics that Inhibit Protein Synthesis
9Review of Initiation of Protein Synthesis
10Review of Elongation of Protein Synthesis
11Protein Synthesis
Microbe Library -American Society for
Microbiology www.microbelibrary.org
12Survey of Antibiotics
13Protein Synthesis Inhibitors
- Mostly bacteriostatic
- Selectivity due to differences in prokaryotic and
eukaryotic ribosomes - Some toxicity - eukaryotic 70S ribosomes
14Antimicrobials that Bind to the 30S Ribosomal
Subunit
15Aminoglycosides (bactericidal)streptomycin,
kanamycin, gentamicin, tobramycin, amikacin,
netilmicin, neomycin (topical)
- Mode of action - The aminoglycosides irreversibly
bind to the 16S ribosomal RNA and freeze the 30S
initiation complex (30S-mRNA-tRNA) so that no
further initiation can occur. They also slow
down protein synthesis that has already initiated
and induce misreading of the mRNA. By binding to
the 16 S r-RNA the aminoglycosides increase the
affinity of the A site for t-RNA regardless of
the anticodon specificity. May also destabilize
bacterial membranes.
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17Aminoglycosides (bactericidal)streptomycin,
kanamycin, gentamicin, tobramycin, amikacin,
netilmicin, neomycin (topical)
- Spectrum of Activity -Many gram-negative and some
gram-positive bacteria Not useful for anaerobic
(oxygen required for uptake of antibiotic) or
intracellular bacteria. - Resistance - Common
- Synergy - The aminoglycosides synergize with
-lactam antibiotics. The -lactams inhibit cell
wall synthesis and thereby increase the
permeability of the aminoglycosides.
18Tetracyclines (bacteriostatic)tetracycline,
minocycline and doxycycline
- Mode of action - The tetracyclines reversibly
bind to the 30S ribosome and inhibit binding of
aminoacyl-t-RNA to the acceptor site on the 70S
ribosome. - Spectrum of activity - Broad spectrum Useful
against intracellular bacteria - Resistance - Common
- Adverse effects - Destruction of normal
intestinal flora resulting in increased secondary
infections staining and impairment of the
structure of bone and teeth.
19Spectinomycin (bacteriostatic)
- Mode of action - Spectinomycin reversibly
interferes with m-RNA interaction with the 30S
ribosome. It is structurally similar to the
aminoglycosides but does not cause misreading of
mRNA. - Spectrum of activity - Used in the treatment of
penicillin-resistant Neisseria gonorrhoeae - Resistance - Rare in Neisseria gonorrhoeae
20Antimicrobials that Bind to the 50S Ribosomal
Subunit
21Chloramphenicol, Lincomycin, Clindamycin
(bacteriostatic)
- Mode of action - These antimicrobials bind to the
50S ribosome and inhibit peptidyl transferase
activity. - Spectrum of activity - Chloramphenicol - Broad
range Lincomycin and clindamycin -
Restricted range - Resistance - Common
- Adverse effects - Chloramphenicol is toxic (bone
marrow suppression) but is used in the treatment
of bacterial meningitis.
22Macrolides (bacteriostatic)erythromycin,
clarithromycin, azithromycin, spiramycin
- Mode of action - The macrolides inhibit
translocation. - Spectrum of activity - Gram-positive bacteria,
Mycoplasma, Legionella - Resistance - Common
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24Antimicrobials that Interfere with Elongation
Factors
Selectivity due to differences in prokaryotic and
eukaryotic elongation factors
25Fusidic acid (bacteriostatic)
- Mode of action - Fusidic acid binds to elongation
factor G (EF-G) and inhibits release of EF-G from
the EF-G/GDP complex. - Spectrum of activity - Gram-positive cocci
26Inhibitors of Nucleic Acid Synthesis
27Inhibitors of RNA Synthesis
Selectivity due to differences between
prokaryotic and eukaryotic RNA polymerase
28Rifampin, Rifamycin, Rifampicin, Rifabutin
(bactericidal)
- Mode of action - These antimicrobials bind to
DNA-dependent RNA polymerase and inhibit
initiation of mRNA synthesis. - Spectrum of activity - Broad spectrum but is used
most commonly in the treatment of tuberculosis - Resistance - Common
- Combination therapy - Since resistance is
common, rifampin is usually used in combination
therapy.
29Inhibitors of DNA Synthesis
Selectivity due to differences between
prokaryotic and eukaryotic enzymes
30Quinolones (bactericidal)nalidixic acid,
ciprofloxacin, ofloxacin, norfloxacin,
levofloxacin, lomefloxacin, sparfloxacin
- Mode of action - These antimicrobials bind to the
A subunit of DNA gyrase (topoisomerase) and
prevent supercoiling of DNA, thereby inhibiting
DNA synthesis. - Spectrum of activity - Gram-positive cocci and
urinary tract infections - Resistance - Common for nalidixic acid
developing for ciprofloxacin
31Antimetabolite Antimicrobials
32Inhibitors of Folic Acid Synthesis
- Basis of Selectivity
- Review of Folic Acid Metabolism
33Sulfonamides, Sulfones (bacteriostatic)
- Mode of action - These antimicrobials are
analogues of para-aminobenzoic acid and
competitively inhibit formation of dihydropteroic
acid. - Spectrum of activity - Broad range activity
against gram-positive and gram-negative bacteria
used primarily in urinary tract and Nocardia
infections. - Resistance - Common
- Combination therapy - The sulfonamides are used
in combination with trimethoprim this
combination blocks two distinct steps in folic
acid metabolism and prevents the emergence of
resistant strains.
34Trimethoprim, Methotrexate, Pyrimethamine
(bacteriostatic)
- Mode of action - These antimicrobials binds to
dihydrofolate reductase and inhibit formation of
tetrahydrofolic acid. - Spectrum of activity - Broad range activity
against gram-positive and gram-negative bacteria
used primarily in urinary tract and Nocardia
infections. - Resistance - Common
- Combination therapy - These antimicrobials are
used in combination with the sulfonamides this
combination blocks two distinct steps in folic
acid metabolism and prevents the emergence of
resistant strains.
35Anti-Mycobacterial Antibiotics
36Para-aminosalicylic acid (PSA) (bacteriostatic)
- Mode of action - Similar to sulfonamides
- Spectrum of activity - Specific for Mycobacterium
tuberculosis
37Dapsone (bacteriostatic)
- Mode of action - Similar to sulfonamides
- Spectrum of activity - Used in treatment of
leprosy (Mycobacterium leprae)
38Isoniazid (INH) (bacteriostatic )
- Mode of action - Isoniazid inhibits synthesis of
mycolic acids. - Spectrum of activity - Used in treatment of
tuberculosis - Resistance - Has developed
39Antimicrobial Drug ResistancePrinciples and
Definitions
- Clinical resistance vs actual resistance
- Resistance can arise by mutation or by gene
transfer (e.g. acquisition of a plasmid) - Resistance provides a selective advantage
- Resistance can result from single or multiple
steps - Cross resistance vs multiple resistance
- Cross resistance -- Single mechanism-- closely
related antibiotics - Multiple resistance -- Multiple mechanisms --
unrelated antibiotics
40Antimicrobial Drug ResistanceMechanisms
- Altered permeability
- Altered influx
- Gram negative bacteria
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42Antimicrobial Drug ResistanceMechanisms
- Altered permeability
- Altered efflux
- tetracycline
43Antimicrobial Drug ResistanceMechanisms
- Inactivation
- ?-lactamase
- Chloramphenicol acetyl transferase
44Antimicrobial Drug ResistanceMechanisms
- Altered target site
- Penicillin binding proteins (penicillins)
- RNA polymerase (rifampin)
- 30S ribosome (streptomycin)
45Antimicrobial Drug ResistanceMechanisms
- Replacement of a sensitive pathway
- Acquisition of a resistant enzyme (sulfonamides,
trimethoprim)