Protein Synthesis Inhibitors

Question 1

Structure of tetracyclines

Answer 1

All have four rings, all end in “cycline”

Question 2

MOA of tetracyclines

Answer 2

reversible binding to the 30s subunit, preventing charged tRNA from binding to acceptor site,

Susceptible bacteria concentrate the drug intracellularly, making it reach high enough levels to favor complexing with its binding site

Conversely, bacteria become resistant by pumping the drug out with efflux pumps!

Question 3

Major factors in tetracycline effectiveness

Answer 3

Absorption is a major issue for these drugs, and it’s all about ionic displacement: metallic cations, antacids, milk or calcium-containing drugs or foods will bind to the drug and prevent its absorption.

Teratogenic: Serum drug levels in pregnant mothers reach the fetus and damages bones and teeth due to interference with calcium in those tissues with the drug being deposited instead of calcium. Thus, this drug class is teratogenic and never to be given to pregnant mothers.

For the same reason affecting bones and teeth, these drugs are not for use under 8 years of age

Metabolized and made less effective by p450 enzymes

Question 4

Special effectiveness of doxycycline

Answer 4

Doxycycline is excreted in bile at high levels and useful for biliary tree infections

Question 5

Toxicities for tetracyclines

Answer 5

Demeclocycline specifically inhibits action of ADH in collecting duct, and can cause iatrogenic diabetes insipidus as a result.

Take with food to decrease GI upset that is more common with this class of drugs than other antibiotics

DO NOT TAKE WITH ANY DAIRY CONTAINING FOODS, ANTACIDS, OR METAL CATIONS as it decreases absorption

Photosensitivity: excessive skin burning with sun exposure

Fatal hepatic necrosis with high doses

Inner ear toxicity with vertigo, nausea, dizziness; minocycline and doxycycline especially

TERATOGENICITY and avoidance in children, nursing mothers, pregnant mothers due to effects on bones and teeth

Question 6

MOA of aminoglycosides

Answer 6

Inside the cell, aminoglycosides bind to specific 30S-subunit ribosomal proteins and inhibit protein synthesis 3 ways:

Interference with the initiation complex of peptide formation;

Misreading of mRNA, which causes incorporation of incorrect amino acids into the peptide and results in a nonfunctional or toxic protein; and

Breakup of polysomes into nonfunctional monosomes.

Question 7

Examples of aminoglycosides and when they’re used

Answer 7

Gentamycin and tobramycin

serious gram-negative infections, or gram-positive infections that require synergistic use of cell wall antibiotics like penicillins

Question 8

Limitations of aminoglycosides

Answer 8

They depend on specific environmental factors in the human body, like availability of oxygen and alkaline pH, to be able to work well.

They enter the periplasmic space via passive diffusion via porins, then are actively transported across the cell membrane into the cytoplasm by an oxygen-dependent process and thus are a poor choice for abscesses, which tend to be an anaerobic environment.

Higher tissue pH: these antibiotics work better in an alkaline environment than an acidic environment, again demonstrating that abscesses with their acidic environment won’t be effectively treated with aminoglycosides.

Transport of these drugs is improved by cell wall-active drugs such as penicillin or vancomycin that create holes in the cell wall; this is the basis of the synergism of these antibiotics with aminoglycosides, and they are frequently used in combination in life-threatening infections that require this synergy, such as endocarditis.

Question 9

WHich aminoglycoside is used for pseudomonnas

Answer 9

tobramycin

Question 10

Mechanism of resistance to aminoglycosides

Answer 10

Inactivation of the drug by bacterial enzymes.

Anaerobic or acidic environment limiting entrance into cell and activation

Question 11

Pharmacokinetics/dynamics/interactions for aminoglycosides

Answer 11

Poor GI absorption; only IV or IM for systemic infections.

Renal excretion; these drugs concentrate in the renal cortex and are only partially dialyzed, and can be very nephrotoxic even within therapeutic levels.

These drugs are both time and concentration-dependent in their killing: Once concentration breached, the time the serum level is maintained above threshold is critical.

The post-antibiotic effect with these drugs leads to dosing strategies with less frequent, larger doses, which helps ensure trough levels are low enough.

Trough levels must be monitored to prevent toxicity, especially when renal function fluctuates; clearance will be directly proportional to creatinine clearance.

Question 12

Toxicities and contraindications for aminoglycosides

Answer 12

Toxicitiies caused by trough levels being too high – nephrotoxocity, ototoxicity

Question 13

Clinical use of neomycin

Answer 13

Topical/enteral use only, Its use as an orally consumed agent in bowel preps in the past contributed to resistance to other aminoglycosides that are used systemically. You may also see it used in injecting infected spaces; it has a negligible effect.

Hepatic encephalopathy, decrease the gut bacteria producing byproducts of nitrogen/protein metabolism that the liver can’t detoxify

Common in skin antibiotics oitnments (neosporin)

Question 14

What is the post-antibiotic effect

Answer 14

Occurs when low levels of antibiotics can still inhiit growth of bacteria- seen with aminoglycosides. Good to limit toxicities

Question 15

Macrolides MOA

Answer 15

bind to 50s ribosomal subunit, preventing translocation and blocking the polypeptide exit tunnel. The protein being made in the tunnel thus can’t elongate and production shuts down.

Question 16

What causes resistance to macrolides

Answer 16

Resistance to macrolides is carried on plasmids and spread via conjugation, the most testable form of resistance is modification of the ribosomal binding site by a macrolide-inducible methylase that also affects other drug classes. The bacteria will appear susceptible initially in the lab but resistance emerges during therapy

Question 17

What is the D-Test

Answer 17

Question 18

Azithromycin pharmacodynamics

Answer 18

Azithromycin is absorbed and then extensively distributed to tissue. S.l.o.w.l.y…the drug comes back out of tissue and into bloodstream, with a T1/2= 3 days, due to its extremely large volume of distribution! Some things that are great about this drug compared to the other macrolides when used properly: it can treat chlamydia in a single dose in the ER in adolescent patients that are not likely to follow up or take meds!

Question 19

Erythromycin pharmacodynamics and toxicities (what cytochrome does it target)

Answer 19

Drug interactions are a major problem since erythromycin inhibits CYP3A4, meaning patients on erythromycin are at risk for toxicity from theophylline, warfarin, cyclosporine, and methylprednisolone

Erythromycin increases the absorption of oral digoxin, increasing risk of toxicity.

Question 20

Macrolides adverse effects

Answer 20

Acute hepatitis and cholestasis; this indicates a person who is more sensitive to the p45- inhibition effect and who should not take these drugs again

Macrolide class toxicity that is very dangerous to fatal: in patients who already have QT prolongation, the addition of these drugs can cause unstable ventricular arrhythmias and sudden death without warning, particularly in combination with other QT prolonging meds.

Question 21

What are ketolides and toxicities

Answer 21

This class has the same MOA as macrolides, and bacteria have not evolved efflux pumps or methylases yet so less resistance. It is a reversible cyt p450 inhibitor, and carries the toxicity of drug-induced hepatitis.

Question 22

Example of Lincosamide

Answer 22

Clindamycin

Question 23

MOA of lincosamides. What are they good for

Answer 23

It has the same mechanism of action and binding site as the macrolides, 50s

It SHINES and should stick in your memory for coverage of anaerobic bacteria

It also covers most community-acquired methicillin-resistant staph aureus (MRSA)

It also has GREAT penetration into abscesses/pus, because it is concentrated by phagocytic cells that are chemotactically attracted by c3a and c5a to abscesses!

Question 24

Mechanism of climdamycin resistance

Answer 24

inducible methylases, same as macrolides

Have to check on a D test

Question 25

MOA of streptogramins

Answer 25

Quinupristin-dalfopristin, aka Synercid; 2 streptogramins complexed together for synergistic action.

Quinupristin binds to the 23s subunit of the 50s ribosome, altering its conformation and increasing its affinity for dalfopristin by 100x while also blocking translocation.

Dalfopristin binds the 50s ribosome and blocks the transpeptidase enzyme.

Gram-positive coverage only due to porin size, used for penicillin-resistant pathogens

Question 26

Pharmacodynamics of streptogramins

Answer 26

This drug inhibits CYP3A4 just like erythromycin. Increased levels of warfarin, diazepam, NNRTIs, and cyclosporine are all seen.

Question 27

Main toxicities of streptogramins

Answer 27

Arthralgia/myalgia syndromes are its main toxicity: painful or inflamed joints and muscles.

Question 28

MOA for chloramphenicol

Answer 28

Chloramphenicol binds to the 50s subunit and inhibits peptide formation.

Question 29

Chloramphenicol interactions and toxicities

Answer 29

Chloramphenicol is a potent inhibitor of protein synthesis that is inactivated in liver by activity of glucuronyl transferase. Remember from your prior study of the biochemistry of neonatal jaundice that newborn babies are relatively deficient in this enzyme. Giving this drug resulting in “gray baby syndrome” = vomiting, flaccidity, hypothermia, gray color, shock, and vascular collapse when given usual doses of drug. This toxicity is one of the major issues you will see on exam questions.

Chloramphenicol also inhibits metabolism of phenytoin, tolbutamide, chlorpropamide, and warfarin, and will increase levels of those drugs to possibly toxic levels.

Question 30

Chloramphenicol toxicities

Answer 30

Irreversible anaplastic anemia

Question 31

Primary drug for Oxazolidinones

Answer 31

Linezolid

Question 32

MOA of oxazolidnones

Answer 32

prevents formation of the entire ribosome complex that initiates protein synthesis.

Question 33

Major use of linezolid

Answer 33

It is one of the few options left for vancomycin-resistant enterococcus (VRE.)

Question 34

Toxicities and contraindications of oxazolidnones

Answer 34

Thrombocytopenia is the most common, but anemia and neutropenia can also occur

optic and peripheral neuropathy and lactic acidosis have been reported with prolonged courses of linezolid. These side effects are thought to be related to linezolid-induced inhibition of mammalian mitochondrial protein synthesis.

Serotonin syndrome occurring when linezolid is coadministered with serotonergic drugs, most frequently selective serotonin reuptake inhibitor antidepressants. Kind of like sympathetic overdrive