Miscellaneous protein synthesis inhibitors

Last updated: September 25, 2024

Miscellaneous protein synthesis inhibitors

Watch later

Watch later

Development of the muscular system
Erb-Duchenne palsy
Klumpke paralysis
Thoracic outlet syndrome
Muscles of the thoracic wall
Vessels and nerves of the thoracic wall
Winged scapula
Brachial plexus
Carpal tunnel syndrome
Anatomy clinical correlates: Wrist and hand
Vessels and nerves of the hand
Muscle weakness: Clinical
Vessels and nerves of the forearm
Muscles of the forearm
Anatomy clinical correlates: Median, ulnar and radial nerves
Muscles of the hand
Fascia, vessels and nerves of the upper limb
Baker cyst
Myotonic dystrophy
Bursitis
Unhappy triad
Meniscus tear
Superficial structures of the neck: Anterior triangle
Iliotibial band syndrome
Neurocutaneous disorders: Pathology review
Bones of the lower limb
Bones of the upper limb
Anatomy of the anterior and medial thigh
Necrotizing fasciitis
Skin cancer: Clinical
Bone tumors: Pathology review
Neuromuscular junction disorders: Pathology review
Legg-Calve-Perthes disease
Pediatric orthopedic conditions: Clinical
Restless legs syndrome
Anatomy of the leg
Osgood-Schlatter disease (traction apophysitis)
Developmental dysplasia of the hip
Anatomy of the hip joint
Anatomy of the orbit
Patellofemoral pain syndrome
Anatomy of the elbow joint
Joints of the ankle and foot
Femoral hernia
Achondroplasia
Lower back pain: Clinical
Osteoporosis
Osteoporosis medications
Back pain: Pathology review
Lordosis, kyphosis, and scoliosis
Osteopetrosis
Osteomalacia
Osteomalacia and rickets
Paget disease of bone
Acute tubular necrosis
Bones of the cranium
Bones of the neck
Pediatric bone tumors: Clinical
Bone histology
Bone remodeling and repair
Seronegative arthritis: Clinical
Seronegative and septic arthritis: Pathology review
Reactive arthritis
Juvenile idiopathic arthritis
Joint pain: Clinical
Gout
Gout and pseudogout: Pathology review
Non-steroidal anti-inflammatory drugs
Sjogren syndrome: Clinical
Sjogren syndrome
Sjogren syndrome: Pathology review
Pediatric bone and joint infections: Clinical
Pasteurella multocida
Bites and stings: Clinical
Spondylitis
Cauda equina syndrome
Systemic lupus erythematosus (SLE): Clinical
Skin and soft tissue infections: Clinical
Antiphospholipid syndrome
Systemic lupus erythematosus (SLE): Pathology review
Fibromyalgia
Myasthenia gravis
Lambert-Eaton myasthenic syndrome
Raynaud phenomenon
Cholinomimetics: Indirect agonists (anticholinesterases)
Scleroderma: Pathology review
Scleroderma
Skin histology
Skin cancer: Pathology review
Hypersensitivity skin reactions: Clinical
Hair, skin and nails
Acneiform skin disorders: Pathology review
Benign hyperpigmented skin lesions: Clinical
Pigmentation skin disorders: Pathology review
Blistering skin disorders: Clinical
Papulosquamous and inflammatory skin disorders: Pathology review
Vesiculobullous and desquamating skin disorders: Pathology review
Eczematous rashes: Clinical
Body focused repetitive disorders
Cellulitis
Seborrhoeic dermatitis
Malassezia (Tinea versicolor and Seborrhoeic dermatitis)
Atopic dermatitis
Contact dermatitis
Papulosquamous skin disorders: Clinical
Hypokinetic movement disorders: Clinical
Movement disorders: Pathology review
Actinic keratosis
Hypopigmentation skin disorders: Clinical
Angiosarcomas
Human herpesvirus 8 (Kaposi sarcoma)
Bartonella henselae (Cat-scratch disease and Bacillary angiomatosis)
Impetigo
Erysipelas
Orbital cellulitis
Periorbital cellulitis
Abscesses
Osteomyelitis
Periapical lesions
Staphylococcus aureus
Herpesvirus medications
Herpes simplex virus
Poxvirus (Smallpox and Molluscum contagiosum)
Varicella zoster virus
Epstein-Barr virus (Infectious mononucleosis)
Autoimmune bullous skin disorders: Clinical
Sarcoidosis
Pityriasis rosea
Rosacea
Sunburn
Burns: Clinical
Burns
Acetaminophen (Paracetamol)
Paracetamol toxicity
Bronchodilators: Leukotriene antagonists and methylxanthines
Cholinomimetics: Direct agonists
Skeletal muscle histology
Mechanisms of antibiotic resistance
Cell wall synthesis inhibitors: Penicillins
Cell wall synthesis inhibitors: Cephalosporins
DNA synthesis inhibitors: Fluoroquinolones
Miscellaneous protein synthesis inhibitors
Protein synthesis inhibitors: Tetracyclines
Miscellaneous cell wall synthesis inhibitors
Antituberculosis medications
Antimetabolites: Sulfonamides and trimethoprim
Protein synthesis inhibitors: Aminoglycosides
Integrase and entry inhibitors
Nucleoside reverse transcriptase inhibitors (NRTIs)
Protease inhibitors
Hepatitis medications
Non-nucleoside reverse transcriptase inhibitors (NNRTIs)
Neuraminidase inhibitors
Azoles
Echinocandins
Miscellaneous antifungal medications
Anthelmintic medications
Antimalarials
Anti-mite and louse medications

Transcript

Watch video only

Protein synthesis inhibitors include many different classes of medications that prevent bacterial ribosomes from synthesizing proteins. The ones that target the 50S subunit of the ribosome include chloramphenicol, macrolides, lincosamides, and oxazolidinones.

Okay, first, let’s look at how genes become proteins. There’s two steps: transcription and translation. During transcription, a specific gene on the DNA is “read” and a copy is made called a messenger RNA, or mRNA, which is like a blueprint with instructions on what protein to build. Translation is also known as protein synthesis, and it’s when organelles called ribosomes assemble the protein from amino acids within the cytoplasm.

Now, prokaryotic cells, like bacteria, have smaller ribosomes than eukaryotic cells, like those found in humans. Bacterial ribosomes are made up of a 50S subunit and a 30S subunit which combine to form a 70S ribosome. Eukaryotic ribosomes are made up of a 60S and a 40S subunit that form a 80S ribosome. Since these proteins are different, we can create medications that selectively interfere with the bacterial ones.

Protein synthesis involves initiation, elongation, and termination. In bacteria, initiation occurs when the 50S and 30S subunits bind to the mRNA sequence to form a ribosome-mRNA complex, also called the initiation complex. The mRNA serves as a blueprint for the protein that will be synthesized. It’s made up of three nucleotide-long sequences, called codons, on top of which transport RNA, or tRNA, carrying amino acids can bind with their matching anticodon. The complete ribosome has 3 sites where tRNA can enter and bind. These are called the A, or aminoacyl site, the P, or peptidyl site, and the E, or exit site.

Elongation starts when the first tRNA, carrying a formylmethionine amino acid, enters the P site and binds to the start codon. This causes a conformational change which unlocks the A site for the next tRNA. The next tRNA binds at the A site, the amino acid detaches from the tRNA in the P site, and a peptide bond is formed by an enzyme called peptidyl transferase between the amino acids in the P and A sites, a process known as transpeptidation. Now, the A site has the newly formed peptide chain dangling from it, while the P site has an empty tRNA with no amino acids. In the final stage of elongation, the tRNA in the P site slides over to the E site, and the tRNA in the A site slides over to the P site. The ribosome slides over so the free A site is over the next codon on the mRNA and this process is called translocation. Next, a new tRNA with the matching anticodon binds, and the process repeats until a long peptide chain called a protein is synthesized.

Okay, so let’s look at some protein synthesis inhibitors. Chloramphenicol is a bit of a loner, and is the single representative in its group. It works during elongation by inhibiting peptidyl transferase, thus preventing peptide bond formation between new amino acids and the polypeptide chain. It’s a broad spectrum bacteriostatic medication, meaning it limits the growth of bacteria, rather than eradicating them. It’s usually administered parenterally, and it readily crosses the blood-brain barrier so it could be used to treat bacterial meningitis. Resistance to chloramphenicol occurs through acetyltransferase enzymes, which add an acetyl group to chloramphenicol to inactivate it. Chloramphenicol is effective against some strains of Haemophilus influenzae, Neisseria meningitidis, Bacteroides species, and Rickettsia species. However, due to its severe toxicity, it’s no longer used systemically in most countries with access to safer alternatives. It is also commonly used in the form of eye ointments to treat bacterial conjunctivitis. For the side effects, it’s very toxic to the bone marrow and could kill off the hematopoietic cells, leading to bone marrow suppression. This will usually lead to aplastic anemia first, followed by a decrease in platelets and leukocytes. It’s also notoriously teratogenic, as it readily crosses the placenta, so it should not be given to pregnant people or newborns. This is because infants lack the hepatic enzyme glucuronosyl transferase which normally metabolizes chloramphenicol. When this medication accumulates, it causes “gray baby syndrome”, where the infant is anemic and cyanotic, where the skin is a pale, or grayish color, and it can lead to cardiovascular collapse. Chloramphenicol also inhibits the hepatic enzymes in the cytochrome p450 family. These enzymes break down many other drugs, like warfarin, so when they are inhibited, it increases the action of those medications.

Next, let’s look at the macrolide antibiotics which include erythromycin, azithromycin, and clarithromycin. There’s also a novel macrolide called fidaxomicin. They work by binding to the 50S subunit of the ribosome and blocking translocation, so the ribosome can’t slide to the next codon on the mRNA. Most macrolides can be administered perorally as well as parenterally. Fidaxomicin is administered only perorally and it’s not absorbed in the systemic circulation. It is only used for Clostridioides difficile infection that causes pseudomembranous colitis. Now, in general, the rest of the macrolides are broad spectrum bacteriostatic medications effective against Gram positive and Gram negative bacteria alike. Specifically, they are used as the first line therapy for Bordetella pertussis, which causes whooping cough. They can also be used to treat typical pneumonia as well as atypical pneumonia caused by Mycoplasma pneumoniae or Legionella species. bacteria. Clarithromycin is used in combination with amoxicillin and omeprazole to treat Helicobacter pylori which causes peptic ulcers. Azithromycin is often used to treat sexually transmitted infections like chlamydia. Finally, resistance against macrolides typically involves developing efflux proteins that actively pump macrolides out of the cell. In addition, methylase enzymes can alter the ribosomal target site of the drug, and thus, decrease the drug binding. Side effects of macrolides are rare and the most common is gastrointestinal problems like diarrhea, nausea, and vomiting. The more serious side effects include a prolonged QT interval, so they should be avoided in people with arrythmias, and hepatotoxicity, so they are contraindicated in people with liver disease. Both erythromycin and clarithromycin can inhibit cytochrome p450.

Lincosamides are represented by clindamycin, which is the most commonly used member of the family. They function similarly to macrolides by binding to the 50S subunit of the ribosome and they inhibit translocation. Clindamycin can be given perorally, parenterally, or as a topical cream. It’s used to treat anaerobic bacterial infections of the lungs and mouth, in other words above the diaphragm. It is also used for Gram positive bacteria, such as group A streptococcus, especially in patients with penicillin allergy. Lincosamides are also used in toxin-mediated conditions, such as toxic shock syndrome, because they can reduce toxin production by inhibiting protein synthesis. Topical formulations of clindamycin can also be given to treat acne. Clindamycin tastes extremely bitter so it's not commonly prescribed to children. Common side effects include GI distress like diarrhea, nausea, vomiting, and cramps. Long term use can cause bacterial superinfection by Clostridioides difficile, formerly known as Clostridium difficile, which can cause pseudomembranous colitis.

Key Takeaways

Protein synthesis inhibitors are a class of antibiotics which prevent bacterial ribosomes from synthesizing proteins. They include drugs like chloramphenicol, macrolides, lincosamides, and oxazolidinones.

Most of these drugs act on the 50S subunit of the ribosome, but their mechanisms can be very different. For example, oxazolidinones like linezolid stop the initiation complex from forming. Both the macrolides and lincosamides prevent translocation. Chloramphenicol inhibits peptidyl transferase which is the enzyme that creates the peptide bonds.

Sources

  1. "Katzung & Trevor's Pharmacology Examination and Board Review,12th Edition" McGraw-Hill Education / Medical (2018)
  2. "Rang and Dale's Pharmacology" Elsevier (2019)
  3. "Goodman and Gilman's The Pharmacological Basis of Therapeutics, 13th Edition" McGraw-Hill Education / Medical (2017)
  4. "Chloramphenicol: A Review" Pediatrics in Review (2004)
  5. "Clarithromycin: Review of a New Macrolide Antibiotic with Improved Microbiologic Spectrum and Favorable Pharmacokinetic and Adverse Effect Profiles" Annals of Pharmacotherapy (1992)
  6. "New Macrolide Antibiotics: Azithromycin and Clarithromycin" Annals of Internal Medicine (1992)
  7. "Macrolides and ketolides: azithromycin, clarithromycin, telithromycin" Infectious Disease Clinics of North America (2004)
  8. "Enhancement of opsonophagocytosis of Bacteroides spp. by clindamycin in subinhibitory concentrations" Journal of Antimicrobial Chemotherapy (1989)
  9. "Linezolid versus Vancomycin for the Treatment of Methicillin‐ResistantStaphylococcus aureusInfections" Clinical Infectious Diseases (2002)