Antimicrobial 2: Agents that Target Bacterial Protein Synthesis

Question 1

Antibiotics Targeting Protein Synthesis

Antibiotics/ antimicrobials that inhibit protein synthesis and are primarily bacteriostatic include drugs in the which classes?

Answer 1

• Tetracyclines
• Aminoglycosides
• Macrolides
• Chloramphenicol
• Oxazolidinones
• Fusidic Acid
• Streptogramins

Question 2

Protein Synthesis

Describe the steps in Protein Synthesis:

Answer 2

DNA –> (transcription) –> RNA –> mRNA –> (translation) –> protein

(see slide 5 picture for details)

Question 3

Bacterial Ribosome

what are the components?

Answer 3

See slide 6 picture

50S: 2 ribosomal rRNA (5S rRNA, 23S rRNA)
30S: 16S rRNA

forms 70S complex

Question 4

Tetracyclines (bacteriostatic)

Drugs

See slide 7 for molecular structure.

Answer 4

• Tetracycline
• Oxytetracycline
• Demeclocycline
• Doxycycline
• Minocycline - BEST FOR CNS
• Tigecycline

bacteriostatic

Question 5

Tetracyclines (bacteriostatic)

Effective against gram-positive & gram-negative bacteria:

Answer 5

Mycoplasma
Rickettsia
Chlamydia
Also effective against protozoa

Question 6

Tetracyclines (bacteriostatic)

MOA

Answer 6

• Are taken up into susceptible organisms by active
  transport and inhibit protein synthesis
• Tetracyclines bind reversibly to the 16S subunit of the
  30S ribosomal subunit and inhibit translation

Question 7

Tetracyclines (bacteriostatic)

AE

Answer 7

• • Staining of teeth & dental hypoplasia
• • Bone deformities
    Chelating calcium: stay in deposits of bones and teeth
• GI disturbances (initially via direct irritation and
  followed by modification of the gut flora)
• Vitamin B complex deficiency
• Hepatotoxicity
• Phototoxicity (demeclocycline)
• Vestibular disturbances (minocycline)
• Anti-anabolic actions in the host Bone marrow
  depression

**Contraindicated in pregnant women, nursing mothers and children

Question 8

Aminoglycosides (bactericidal in high doses & bacteriostatic)

Drugs

See slide 10 for molecular structure.

Answer 8

• Gentamicin
• Streptomycin
• Amikacin
• Tobramycin
• Neomycin

Question 9

Aminoglycosides (bactericidal & bacteriostatic)

Characteristics

Answer 9

• Are more effective against gram-negative bacteria
• Their penetration through the cell membrane
  depends on oxygen-dependent active transport
  (minimal action against anaerobic bacteria)
• Have both bacteriostatic and bactericidal actions
• Amikacin was designed as a poor substrate for
  microbial enzymes that inactivate aminoglycosides
  (to counteract aminoglycoside resistance)

Question 10

Aminoglycosides (bactericidal & bacteriostatic)

MOA

Answer 10

• Bind irreversibly to the 30S ribosomal subunit and
  inhibit protein synthesis (trap ribosomes at the AUG
  start codon)
• As cationic molecules they create fissures and pores
  in the outer cell membrane, causing leakage of
  intracellular contents and enhancing antibiotic
  uptake

Question 11

Aminoglycosides (bactericidal & bacteriostatic)

AE

Answer 11

• • Ototoxicity
• • Nephrotoxicity
• • Paralysis via neuromuscular blockade (rare)

Question 12

Macrolides (bacteriostatic)

Drugs

See slide 13 for molecular structure.

Answer 12

• Macrolides are lactone rings attached to deoxysugars
and include the following:

• Erythromycin
• Clarithromycin
• Azithromycin
• Telithromycin
• Have similar antimicrobial spectrum to that of
  Penicillins, and are thus safe alternatives for
  individuals showing hypersensitivity to penicillins

bacteriostatic

Question 13

Macrolides (bacteriostatic)

MOA

SIGNIFICANT CYP450 INHIBITORS

Answer 13

• Bind the 23S rRNA molecule of the 50S ribosomal
  subunit and inhibit peptidyl transferase (block transfer of new amino acids onto the growing peptide chain)

Blocks the exit channel

Question 14

Macrolides (bacteriostatic)

AE

Answer 14

• • Cholestatic jaundice (treatment > 2 wks)
    bile can’t flow from liver to duodenum
• GI disturbances
• Hypersensitivity reactions (rash and fever)
• Transient hearing disturbances

Question 15

Chloramphenicol (bacteriostatic)

Characteristics

See slide 16 for molecular structure

Answer 15

• Chloramphenicol was originally isolated from cultures
  of Streptomyces

- Is bacteriostatic against Gram-negative and Gram- 
  positive organisms and should be reserved for serious 
   infections Meningitis (when penicillin cannot be used)

Question 16

Chloramphenicol (bacteriostatic)

MOA

Answer 16

• (same as macrolides) bind the 23S rRNA molecule of
  the 50S ribosomal subunit and inhibit peptidyl
  transferase (block transfer of new amino acids onto
  the growing peptide chain)

Question 17

Chloramphenicol (bacteriostatic)

AE

Answer 17

• • ‘grey baby’ syndrome, grey colour of skin, vomiting, diarrhea, mortality
• Severe depression of bone marrow causing
  
  • pancytopenia, decrease in all blood cells

Question 18

Oxazolidinedione (bacteriostatic)

Consider the first truly new class of antibacterials to reach the market -

Drug

See slide 18 for molecular structure

Answer 18

Linezolid

Question 19

Oxazolidinedione (bacteriostatic)

Charactistics

Answer 19

• Active against wide variety of Gram-positive bacteria
  and useful against drug-resistant bacteria such as
  MRSA

Question 20

Oxazolidinedione (bacteriostatic)

MOA

Answer 20

• Inhibit bacterial protein synthesis via a novel
  mechanism involving antagonism of the N-
  formylmethionyl-tRNA binding to the 70S ribosome

Question 21

Oxazolidinedione (bacteriostatic)

PK?

Answer 21

• Linezolid has 100% oral bioavailability

- Linezolid is also a weak monoamine oxidase inhibitor

Question 22

Oxazolidinedione (bacteriostatic)

AE

Answer 22

• • Thrombocytopenia
• • Serotonin syndrome
• • Hyperlactatemia
• Diarrhea
• Nausea
• Rash
• Dizziness

Question 23

Other Agents Targeting Protein Synthesis

Fusidic Acid (bacteriostatic)

MOA

See slide 21 for molecular structure

Answer 23

• Steroid antibiotic against Gram-positive bacteria that
  inhibits bacterial protein synthesis by interfering with translation
• steroid backbone

Question 24

Other Agents Targeting Protein Synthesis

Fusidic Acid

AE

Answer 24

• • Jaundice

- GI disturbances

Question 25

Other Agents Targeting Protein Synthesis

Streptogramins (Quinupristin & Dalfopristin) -

(bacteriostatic)

MOA

See slide 22 for molecular structure

Answer 25

• Cyclic peptides that inhibit bacterial protein synthesis
  by binding to the 50S subunit of the bacterial ribosome
  (Gram-positive organisms)

Question 26

Other Agents Targeting Protein Synthesis
Streptogramins (Quinupristin & Dalfopristin) -

(bacteriostatic)

AE

Answer 26

• Inflammation at infusion site (*arthralgia and *myalgia)

- Nausea, vomiting & diarrhea

Question 27

Other Agents Targeting Protein Synthesis

Clindamycin (a lincosamide) - (bacteriostatic)

MOA

See slide 23 for molecular structure

Answer 27

• Same as macrolides & chloramphenicol
• Inhibit bacterial protein synthesis
• Bind the 23S rRNA molecule of the 50S ribosomal
  subunit and inhibit peptidyl transferase (block transfer
  of new amino acids onto the growing peptide chain)

Question 28

Other Agents Targeting Protein Synthesis

Clindamycin (a lincosamide) - (bacteriostatic)

AE

Answer 28

• • Potentially lethal psuedomembranous colitis (toxin-
    forming C. difficile)
• GI disturbances (uncomfortable diarrhea)

Question 29

Quinolones (Bactericidal)

Drugs

Effective against both Gram-positive & Gram-negative bacteria

See slide 24 for molecular structure

Answer 29

Quinolones are broad-spectrum fluorinated) and include;
• Nalidixic Acid
• Ciprofloxacin
• Levofloxacin
• Ofloxacin
• Norfloxacin
• Moxifloxacin

good for UTI

Question 30

Quinolones (Bactericidal)

MOA

Answer 30

• Inhibit topoisomerase II (bacterial DNA gyrase which cuts open DNA and reseals it) and topoisomerase IV
• Prevent negative supercoiling of DNA (required to
  allow transcription or replication of DNA) by DNA
  gyrase.
• Prevent topoisomerase IV mediated decatenation of
  daughter DNA molecules.

Question 31

Quinolones (Bactericidal)

AE

Answer 31

• *Arthropathy
• *Convulsions (can be exacerbated with concurrent use of theophyllines)
• due to point mutations of DNA gyrase enzyme
• high conc in kidneys for excretion
• GI disturbances
• Hypersensitivity reactions (rashes)
• Headache and dizziness

Question 32

Summarize Antibacterials that interfere with bacterial protein synthesis : (6)

Answer 32

• Tetracyclines bind reversibly to the 16S subunit of the
  30S ribosomal subunit and inhibit translation
• Aminoglycosides bind irreversibly to the 30S ribosomal
  subunit and inhibit protein synthesis (trap ribosomes at
  the AUG start codon)
• Macrolides bind the 23S rRNA molecule of the 50S
  ribosomal subunit and inhibit peptidyl transferase
  (block transfer or new amino acids onto the growing
  peptide chain)
• Chloramphenicol & clindamycin have a similar
  mechanism of action as the macrolide antibiotics
• Oxazolidinones are the newest class of antibacterials,
  which inhibit bacterial protein synthesis via a novel
  mechanism involving antagonism of the N-
  formylmethionyl-tRNA binding to the 70S ribosome
• Quinolines, which inhibit topoisomerase II (bacterial
  DNA gyrase) and thereby prevent supercoiling of
  DNA, leading to cessation of transcription/replication
  of DNA

Question 33

why do antibiotics have hard time targeting G- bac ?

Answer 33

• outer membrane makes it hard for drugs to reach bacterium

- outer membrane has porin channels that prevent entry of chemicals