Antibiotics Against DNA/Protein Synthesis

Question 1

name 5 classes of antibiotics that are cell wall synthesis inhibitors

Answer 1

1. penicillins
2. cephalosporins
3. carbapenems
4. monobactams
5. glycopeptides

Question 2

name 2 classes of antibiotics that are cell membrane disrupters

Answer 2

1. polymyxins
2. daptomycin

Question 3

what class of antibiotic is an inhibitor of DNA replication (DNA gyrase and topoisomerase IV inhibitors)

Answer 3

fluoroquinolone

Question 4

what are 2 classes of antibiotics that are inhibitors of DNA biosynthesis (folate metabolism inhibitors)

Answer 4

1. sulfonamides
2. trimethoprim

Question 5

what 4 classes of antibiotics are protein synthesis (50S) inhibitors

Answer 5

1. macrolides
2. lincosamide
3. oxazolidinones
4. pleurmutilin

Question 6

what 2 classes of antibiotics are protein synthesis (30S) inhibitors?

Answer 6

1. aminoglycosides
2. tetracyclines

Question 7

what class of antibiotics are Gentamicin, Tobramycin, Streptomycin, Amikacin, Neomycin, Paromomycin, and Plazomicin?

Answer 7

aminoglycosides: inhibitors of bacterial 30S ribosomal subunit (protein synthesis inhibitors)

*note that Streptomycin and Amikacin are both 2nd-line anti-Mtb drugs

[also remember that tetracyclines also inhibit 30S]

Question 8

what class of antibiotics are Doxycycline, Minocycline, Eravacycline, and Tigecycline?

Answer 8

tetracyclines: inhibitors of bacterial 30S ribosomal subunit (protein synthesis inhibitors)

[remember that aminoglycosides are also 30S inhibitors]

Question 9

what is the basic mechanism of aminoglycosides (Gentamicin, Tobramycin)?

Answer 9

target 16S rRNA A-site of 30S subunit and irreversibility interfere with protein synthesis in 3 ways!

1. block initiation
2. block translocation (—> premature termination)
3. cause mRNA misreading

bactericidal (vs most protein synthesis inhibitors which are bacteriostatic)

exhibit post-antibiotic effect: antibacterial activity persists after drug clearing - allows for once-daily dosing

Question 10

explain why aminoglycosides (Gentamicin, Tobramycin) are able to be administered with once-daily dosing, despite being cleared from the body before the next dose

Answer 10

aminoglycosides: inhibit 16S rRNA A-site of 30S ribosomal subunit by blocking initiation, blocking translocation, and causing mRNA misreading

exhibit post-antibiotic effect: antibacterial activity persists after drug clearing - allows for once-daily dosing

*note that aminoglycosides are bactericidal (unlike most protein synthesis inhibitors which are bacteriostatic)

Question 11

of the aminoglycosides (30S subunit inhibitors), Tobramycin, Gentamicin, and Amikacin are similar in that they are all used for…

Answer 11

most frequently prescribed for systemic treatment, via IM or IV (drugs are basic amines - bad oral bioavailability)

serious infections by aerobic Gram(-) bacilli - mainly used as second agents for empiric therapy for septicemia, complicated UTIs, nosocomial resp. tract infections, osteomyelitis, intra-abdominal infections, etc

however, use is limited because there are less toxic agents available

[do NOT work well against anaerobes]

Question 12

which 3 aminoglycosides (30S inhibitors) are most frequently prescribed for systemic treatment, as second agents for empiric therapy for serious infections caused by aerobic Gram(-) bacilli?

what class of drugs are they typically given in combination with to prevent emergence of resistance?

Answer 12

Tobramycin, Gentamicin, Amikacin

typically given with beta-lactam antibiotics (synergistic)

*note that use is limited because there are less toxic agents available

Question 13

how is bacterial resistance to aminoglycosides (30S inhibitors) typically conferred, and which aminoglycoside is resistant to this?

Answer 13

resistance to aminoglycosides is typically through gene expression that produces enzymes which modify aminoglycosides

Amikacin is resistant to these enzymes (recall this is an anti-TB drug)

Question 14

which aminoglycoside (30S inhibitors) is used as a 2nd-line agent against TB, and a first-line agent against tularemia and plague?

Answer 14

Streptomycin: 2nd-line agent in combination for TB, first-line mono-therapeutic option for tularemia and plauge

recall that tularemia is caused by Francisella tularensis and plague is caused by Yersinia pestis

Question 15

Neomycin, Paromomycin, and Plazomicin are all aminoglycosides (inhibit 30S subunit) - what are their respective clinical uses?

Answer 15

Neomycin: topical infections (toxic!) - part of Neosporin

Paromomycin: intraintestinal Amebiasis, taken orally even though basic because infection is in GI tract itself

Plazomicin: complicated UTIs, including pyelonephritis

Question 16

which aminoglycoside (30S inhibitor) is restricted to topical use because it is very toxic?

Answer 16

Neomycin (part of Neosporin!)

*note that topical includes skin and eyes (eye drops)

fun fact: recall that Bacitracin, antibiotic against lipid phosphatase in peptidoglycan synthesis, is also in Neosporin! (triple antibiotic)

Question 17

explain why it makes sense that Paromomycin, an aminoglycoside (30S inhibitor) can be taken orally, despite its basicity?

Answer 17

basic drugs are not absorbed well, usually given via IV or IM (not oral)

however, Paromomycin is mainly used for treatment of intraintestinal amebic infection, so it can be given orally because the infection is right there in the GI tract!

Question 18

which aminoglycoside (30S inhibitor) is relatively new and approved for complicated UTIs, including pyelonephritis?

Answer 18

Plazomicin

Question 19

what are the 2 primary adverse reactions associated with aminoglycosides (30S inhibitors)?

Answer 19

1. nephrotoxicity: metabolized entirely by kidney and accumulate at high levels - major limiting factor of widespread use and length of use
   *esp. Neomycin (!), Tobramycin, Gentamicin
2. ototoxicity: also limits length of use - auditory (tinnitus) or vestibular (vertigo, ataxia) damage; note these effects tend to be irreversible

Question 20

how do tetracyclines function to inhibit the bacterial 30S ribosomal subunit?

what kind of bacteria does this work on?

Answer 20

bind to 30S subunit and prevent aminoacyl-tRNA binding to the A site, thereby preventing peptide elongation

bacteriostatic for aerobic and anaerobic Gram+/- bacteria (broad spectrum)

Question 21

aminoglycosides and tetracyclines are 2 classes of antibodies that both inhibit the bacterial 30S ribosomal subunit, thus preventing protein synthesis

describe the differences in their mechanism, differences in type of bacteria they are effective against, and state which is bactericidal vs bacteriostatic

Answer 21

aminoglycosides: target 16S rRNA A-site of 30S subunit and irreversibly inhibit protein synthesis via 3 ways - block initiation, block translocation, cause mRNA misreading
bactericidal with postantibiotic effect, mostly aerobic Gram(-)

tetracyclines: bind 30S subunit and prevent aminoacyl-tRNA binding to A site, blocking peptide elongation
bacteriostatic and broad spectrum

Question 22

explain why tetracyclines (30S inhibitors) should not be taken with dairy products or antacids

Answer 22

tetracyclines chelate (= bind metal) multivalent cations, such as Ca2+, Mg2+, Fe2+, and Al3+, which are found in products such as dairy or antacids

absorption form the gut following oral administration is therefore impaired by these cations and byproducts that contain them

Question 23

You’re prescribing Doxycycline, a tetracycline (30S inhibitor) to your patient. As you’re advising them on proper medication adherence, you make sure to tell them to avoid this food product…

explain why

Answer 23

avoid dairy and antacids (among other things) when taking tetracyclines

tetracyclines chelate (bind) multivalent cations (calcium, magnesium, iron, aluminum)

absorption from the gut following oral administration is impaired by these cations and byproducts containing them

Question 24

which tetracycline (30S inhibitors) must be administered by IV? what is it used for?

Answer 24

Tigecycline: really a glycylcycline, poorly absorbed orally but has longer half-life than other tetracyclines

reserved for treatment of refractory infections caused by multi-drug resistant bacteria, including Vancomycin-resistant enterococci (VRE) and Methicillin-resistant Staph. aureus (MRSA)

Question 25

Doxycycline is the most heavily prescribed tetracycline (30S inhibitor), and it is the first line of treatment for these 3 illnesses:

bonus if you can name the other 2 things it’s typically used for (but not first line for)

Answer 25

1. Rickettsial infection (Rocky Mountain spotted fever, typhus, Q fever)
2. Chlamydial STIs (male urethritis, female cervicitis)
3. early localized Lyme disease with erythema migrans (EM, bull’s eye rash)
4. community-acquired bacterial pneumonia (for empiric therapy, in combination with amoxicillin)
5. Acne Vulgaris (in conjunction with topical therapies)

Question 26

what is the first line antibiotic for:

1. Rickettsial infection (Rocky Mountain spotted fever, typhus, Q fever)
2. Chlamydial STIs (male urethritis, female cervicitis)
3. early localized Lyme disease with erythema migrans (EM, bull’s eye rash)

Answer 26

Doxycycline: tetracycline (30S inhibitor)

also used for:
- community-acquired bacterial pneumonia (CABP) empiric therapy
- Acne Vulgaris in conjunction with topical therapies

Question 27

which tetracycline (30S inhibitor) is recently approved for complicated intra-abdominal infections?

Answer 27

Eravacycline

Question 28

what are 4 primary adverse reactions associated with tetracyclines (30S inhibitors)?

Answer 28

1. GI upset
2. deposition in newly-forming teeth/bones (children), due to chelation (binding metals - calcium) - CONTRAINDICATED for long use in children
3. photosensitization (bad sunburns)
4. hepatotoxic - CONTRAINDICATED during pregnancy

Question 29

which antibiotics are contraindicated for long use in children due to deposition in newly-forming teeth and bones? explain why

Answer 29

tetracyclines (30S inhibitors): chelate cations such as calcium (in bones and teeth)

can deposit in teeth, causing fluorescence/discoloration/enamel dysplasia

can deposit in bone, causing deformity or growth inhibition

Question 30

what class of antibiotics do Azithromycin, Clarithromycin, and Erythromycin belong to? what bacteria are they effective against?

Answer 30

Macrolides: inhibit bacterial 50S ribosomal subunit and inhibit translocation step of protein synthesis

bacteriostatic vs aerobic Gram+ and some Gram-

differences in clinical utility between drugs due to pharmacokinetic properties

Question 31

which type of macrolide (50S ribosomal inhibitor) has the longest half life?

Answer 31

Azithromycin - 3 day half-life, allows for less frequent dosing and shorter duration of treatment

Question 32

what 4 illnesses is Azithromycin (macrolide, inhibits 50S subunit) used for? bonus if you can indicate for which it is the preferred drug

Answer 32

1. Bordetella pertussis (“whooping cough”): preferred drug
2. community acquired bacteria pneumonia (CABP): preferred adjunctive option for empiric therapy in combination with amoxicillin
3. chlamydial STIs: preferred in pregnant women who cannot tolerate hepatotoxicity of doxycycline (tetracycline)
4. Streptococcal pharyngitis (“strep throat”): alternative for patients with beta-lactam allergy

Question 33

what is the drug of choice for treating Bordetella pertussis whooping cough?

Answer 33

Azithromycin: macrolide, targets bacterial ribosomal 50S subunit to inhibit translocation step

Question 34

Your patient is a pregnant woman with a chlamydial STI. What is the best drug to prescribe to them for their STI? explain your choice

Answer 34

usual first-line drug for chlamydial STI is doxycycline (tetracycline, targets 30S); however, tetracyclines are contraindicated during pregnancy due to hepatotoxicity

therefore, the drug of choice for this patient is Azithromycin (macrolide, targets 50S)

Question 35

what type of antibiotic is Erythromycin, and what is it a first-line treatment for?

Answer 35

Erythromycin: macrolide, targets 50S ribosomal subunit to inhibit translocation

*first-line drug for diphtheria caused by Corynebacterium diphtheriae

Question 36

what are the 4 primary adverse reactions of macrolides (50S inhibitors)?

Answer 36

1. GI disturbance (esp. Erythromycin!!)

less common:
2. arrhythmias (cardiac)
3. allergic reactions
4. hepatotoxicity (probably hypersensitivity reaction)

Question 37

what is the mechanism and use of Clindamycin (lincosamide that targets 50S subunit)?

Answer 37

mechanism: blocks peptide transfer and ribosomal translocation

use: bacteriostatic vs aerobic and anaerobic Gram+/-

primarily treats anaerobic infections above the diaphragm (Bacteroides fragilis, Clostridium perfringens)

ex: aspiration pneumonia, lung abscess, oral infection

Question 38

why does it make sense that Clindamycin (lincosamide, targets 50S subunit) is commonly used to treat oral infections?

Answer 38

Clindamycin is especially effective against anaerobic Gram(-) bacteria, which heavily colonize the oral cavity

Question 39

what adverse effect of Clindamycin (lincosamide, 50S inhibitor) is the limiting factor of its use?

Answer 39

major disrupter of microbiome in GI tract

—> Clostridium difficile diarrhea (from overgrowth) and pseudomembranous colitis

[recall that C. diff is very hard to treat]

Question 40

what class of antibiotics do Linezolid and Tedizolid belong to? what is the mechanism of this class?

Answer 40

Oxazolidinones: inhibit bacterial 50S ribosomal subunit by binding to A-site of 23S rRNA, blocking initiation of protein synthesis

Question 41

what are Linezolid and Tedizolid (oxazolidinones, target 50S subunit) used for?

Answer 41

bacteriostatic vs aerobic Gram(+)

used for treating multi-drug resistant Gram+ bacteria, including MRSA and VRE (restricted to this use to prevent emergence of resistance)

Question 42

what are the most common adverse side effects of Linezolid and Tedizolid, oxazolidinones which target the 50S ribosomal subunit? (3)

Answer 42

1. thrombocytopenia
2. GI disturbance
3. peripheral neuropathy

Question 43

what antibiotic does this describe?
- binds to A site of 23S rRNA to block initiation of protein synthesis
- bacteriostatic vs aerobic Gram+
- can treat MRSA and VRE
- side effects include thrombocytopenia

Answer 43

Linezolid or Tedizolid: oxazolidinones (inhibit 50S ribosomal subunit)

use restricted to treating multi-drug resistant Gram+ to preserve their effectiveness

side effects: thrombocytopenia, GI disturbance, peripheral neuropathy

Question 44

what is the mechanism of Lefamulin, a pleuromutilin?

Answer 44

Lefamulin: binds BOTH A and P sites of 23S rRNA, blocking peptidyl tRNA binding and ribosomal translocation (pleuromutilins inhibit 50S subunit)

mostly bactericidal with also some bacteriostatic activity (depends on the pathogen)

Question 45

what is Lefamulin (pleuromutilin, inhibits 50S subunit) used for?

Answer 45

mostly bactericidal with some bacteriostatic activity vs Gram+/- pathogens associated with respiratory tract infections

approved to treat community acquired bacterial pneumonia (CABP), or as alternative to patients who can’t tolerate beta-lactams or fluoroquinolones

Question 46

why is Lefamulin (pleuromutilin, inhibits 50S subunit) at risk for drug-drug interactions?

Answer 46

metabolized by CYP3A4 - drugs that modulate this enzyme would interfere with Lefamulin metabolism

Question 47

how do antifolates work to inhibit bacterial DNA synthesis?

Answer 47

inhibit synthesis of purine bases

ex: sulfonamides and trimethoprim-sulfonamide combinations

Question 48

what 2 antibiotics belong to the sulfonamide class, which are antifolates? how do they work?

Answer 48

1. Sulfamethoxazole (SMX)
2. Sulfisoxazole

sulfonamides are PABA analogs that competitively inhibit dihyropteroate synthase, which converts PABA to dihydrofolic acid (first step of pathway in purine synthesis)

sulfonamide-susceptible bacteria cannot use folate, must synthesize it from PABA (p-aminobenzoic acid)

[recall that sulfonamides are antifolates, which inhibit DNA synthesis by inhibiting synthesis of purine bases!]

Question 49

what are sulfonamides (Sulfamethoxazole/SMX and Sulfisoxazole) used for, and what are their adverse effects?

Answer 49

treat UTIs, but not as monotherapy (due to resistance)

sulfonamides are hyperallergenic

[remember that sulfonamides are PABA analogs in purine synthesis]

Question 50

how does trimethoprim (TMP), a type of anti-folate, work to inhibit DNA synthesis?

Answer 50

selectively inhibits bacterial dihydrofolate redactase (DHFR), the 2nd step in purine synthesis pathway

[sulfonamides like SMX compete with PABA in the first step, and in combination TMP-SMX is bactericidal!]

Question 51

what kind of drug is Bactrim?

Answer 51

TMP-SMX: combination of trimethoprim (TMP) and Sulfamethoxazole (SMX, a sulfonamide)

these are both under umbrella of antifolates (inhibit DNA synthesis)

SMX blocks first step of purine pathway (competitive with PABA), while TMP blocks second step (selectively inhibits bacterial dihydrofolate reductase)

alone they are both bacteriostatic but in combination they are bactericidal

[DO NOT confuse wirh Bacitracin, antibiotic against lipid phosphatase of peptidoglycan synthesis]

Question 52

name 3 illnesses for which TMP-SMX (antifolate) is a first-line drug

bonus if you can name for which it is a second-line option

Answer 52

TMP-SMX: trimethoprim + Sulfamethoxazole (Sulfonamide), blocks first 2 steps of purine synthesis pathway

first line:
1. uncomplicated UTIs (empiric)
2. Pneumocystis pneumonia (direct)
3. Shigellosis (direct)

2nd line: Salmonella

Question 53

if a patient takes TMP-SMX for more than 5 days, what should you become concerned for?

Answer 53

serious adverse effects including megaloblastic anemia and leukopenia

TMP-SMX: trimethoprim + Sulfamethoxazole (Sulfonamide), blocks first 2 steps of purine synthesis pathway

Question 54

what kind of antibiotics are fluoroquinolones (FQs), and what common ending do they all have in their names?

Answer 54

Fluoroquinolones (FQs): type of DNA gyrase/Topoisomerase IV inhibitors

all end in “-oxacin” !

ex: Ciprofloxacin, Ofloxacin, Enoxacin
and
respiratory FQs: Levofloxacin, Gemifloxacin, Moxifloxacin (recall these are 2nd-line TB drugs)

Question 55

what kind of antibiotics are Ciprofloxacin, Ofloxacin, and Enoxacin?

Answer 55

Fluoroquinolones (FQs): inhibit bacterial DNA gyrase/Top. IV

also respiratory FQs: Levofloxacin, Gemifloxacin, Moxifloxacin (recall these are 2nd-line TB drugs)

Question 56

the bacterial target of fluoroquinolones (end in “-oxacin”) is slightly different depending on whether bacteria is Gram(+/-)… specify

Answer 56

Gram(-): DNA gyrase is primary target

Gram(+): Topoisomerase IV is primary target

bactericidal against both!

Question 57

for which 3 illnesses are fluoroquinolones (inhibit DNA gyrase/Top. IV) first line drugs? bonus if you can name 2 illnesses they are alternatives for

Answer 57

1. complicated UTIs, including pyelonephritis (Ciprofloxacin, Levofloxacin)
2. Shigellosis and Salmonella (Ciprofloxacin, Levofloxacin)
3. Anthrax prophylaxis (Ciprofloxacin)

also:
4. CABP (community acquired bacterial pneumonia) - respiratory FQs (Levofloxacin) are alternatives for patients who cannot tolerate beta-lactams
5. Otitis Externa (swimmer’s ear)

Question 58

in general, fluoroquinolones (DNA gyrase/Top IV inhibitors) are well tolerated or cause some GI disturbance

however, there are 2 more serious risks (though uncommon) - what are they?

Answer 58

neurological: delirium, hallucinations, seizures

cardiovascular: arrhythmias caused by QT prolongation