Micro 20: Antimicrobial agents 1

Question 1

What are the 3 main targets for antibiotics?

Answer 1

Peptidoglycan layer of cell wall

Inhibition of bacterial protein synthesis

DNA gyrase and other prokaryote-specific enzymes

Question 2

Difference in structure of gram +ve v gram -ve bacteria

Answer 2

Gram +ve:
- Thick peptidoglycan cell wall on outside

Gram -ve:

• Thinner peptidoglycan cell wall
• Has an outer membrane which prevents some abx from working on the cell wall

Question 3

Name two groups of antibiotics that inhibit cell wall synthesis (peptidoglycan layer of cell wall) + group of abx in each / examples

Answer 3

Beta-lactams:

• Penicillins
• Cephalosporins
• Carbapenems

Glycopeptides:
- Vancomycin
- Tiecoplanin
(these are abx not groups like in b-lactams)

Question 4

MoA of b-lactams?

Answer 4

Beta-lactam is a structural analogue of the enzyme substrate

Inhibits transpeptidases (aka penicillin-binding protein)

Inactivate enzymes that are involved in the terminal stages of cell wall synthesis

This means that there are no peptide crosslinks between peptidoglycan chains so the cell wall is weak

This causes bacteria to burst and die due to osmotic lysis (from osmotic pressure)

Question 5

Limitations of b-lactams?

Answer 5

They work on the stationary phase of the cell cycle - only effective against rapidly dividing bacteria

They are also ineffective against bacteria w/ no cell wall - intracellular pathogens (eg. Mycoplasma & chlamydia)

Question 6

4 types of penicilins?

Answer 6

Penicillin
Amoxicillin
Flucloxacillin
Piperacillin

Question 7

Describe the coverage and mechanism of resistance of penicillin?

Answer 7

Active against Gram-positives (e.g. Streptococci, Clostridia)

Broken down by beta-lactamases (mainly produced by S. aureus)

NOTE: penicillin is the MOST ACTIVE beta-lactam antibiotic

Question 8

Describe the coverage, mechanism of resistance and limitations of Amoxicillin

Answer 8

Broad-spectrum penicillin

Extends coverage to Enterococci and Gram-negative organisms

Broken down by beta-lactamase produced by S. aureus and many Gram-negatives

Question 9

Describe the coverage, mechanism of resistance and limitations of Piperacillin

Answer 9

Similar to amoxicillin

Extends coverage to Pseudomonas and other non-enteric Gram-negative organisms

Broken down by beta-lactamase produced by S. aureus and many Gram-negatives

Note: P for Piperacillin, P for Pseudomonas

Question 10

Describe the coverage and limitations of Flucloxacillin

Answer 10

Similar to penicillin but less active

Does NOT get broken down by beta-lactamase produced by S. aureus

• This is why S. aureus is treated w/ flucloxacillin

Question 11

Name two beta-lactamase inhibitors.

What is the benefit of giving beta-lactamase inhibitors with beta-lactams?

Answer 11

Clavulanic acid
Tazobactam

Protect penicillins from breakdown by beta-lactamases thereby increasing the coverage to include S. aureus, Gram-negatives and anaerobes

Question 12

What is co-amoxiclav?

Answer 12

Amoxicillin + Clavulanic Acid

Question 13

Examples of 1st, 2nd and 3rd gen cephalosporins?

What is the difference between different generations?

Answer 13

1st = Cephalexin

2nd = Cefuroxime

3rd = Cefotaxime, Ceftriaxone, Ceftazidime

NOTE: as you go up the generations you get increasing activity against Gram-negatives and less activity against Gram-positives

Question 14

Benefit of cephalosporins v penicillins?

Answer 14

Stable to many b-lactams produced by gram -ve bacterias

Question 15

Coverage of cefuroxime (2nd gen cephalosporin)

Answer 15

Stable to many b-lactamases made by gram -ves

Similar cover to co-amoxiclav

But less active against anaerobes -> combine w/ metronidazole to cover anaerobes

Question 16

What cephalosporin is the mainstay of bacterial meningitis mx? Why?

What adverse reaction is this associated w/?

Answer 16

Ceftriaxone (3rd gen cephalosporin) - This is excreted less than other b-lactams hence maintains conc in CNS

Associated w/ C.Diff infection

Question 17

What cephalosporin provides good cover against Pseudomonas?

Answer 17

Ceftazidime (3rd gen cephalosporin)

Question 18

What are ESBLs?

Answer 18

Type of beta-lactamase that also breaks down cephalosporins as well as penicillins

Question 19

List three examples of carbapenems

Answer 19

Meropenem (Broadest + anti-pseudomonal activity)

Imipenem (Similar to meropenem, can cause renal failure + seizures - give cilastatin)

Ertapenem (not as broad as others, doesnt cover pseudo or enterococci)

Question 20

What is the main benefit of carbapenems?

Answer 20

Stable to EBSL enzymes

Question 21

Outline the key features of beta-lactam antibiotics (5)

Answer 21

Relatively non-toxic

Renally excreted (reduced dose in renal impairment)

Short half-life

Will not cross an intact blood-brain barrier (may cross inflamed meninges in meningitis)

Cross allergenic (penicillins have 5-10% cross-reactivity with cephalosporins and carbapenems)

Question 22

List examples of bacteria that have shown carbapenem resistance and how?

Answer 22

Acinetobacter and Klebsiella

Presence of carbapenemase enzyme

Question 23

Examples of glycopeptide ABX?

Answer 23

Vancomycin

Teicoplanin

Question 24

MoA of Glycopeptides?

Answer 24

Glycopeptides bind to amino acid chains at the end of peptidoglycan precursors

This prevents glycosidic bonds being formed (via transglycosidase) and prevents peptide crosslinks being formed (via transpeptidase)

NOTE: they are similar to beta-lactams but instead of binding to the enzymes, they bind to substrates (cell wall component precursors)

Question 25

What are glycopeptides often used to treat?

Answer 25

Serious MRSA infections

C. difficile infections (oral vancomycin)

Question 26

Which type of bacteria are glycopeptides effective against and why?

Answer 26

Gram-positives

They are large molecules so they cannot cross the outer membrane of Gram-negative cell walls

Question 27

Major side effect of glycopeptides? prevention?

Answer 27

Nephrotoxic - monitor blood levels to prevent accumulation

Question 28

How are Bacterial ribosome different to human ribosomes?

Answer 28

Both have 2 subunits but bacterial is smaller:

• Human = 60S + 40S
• Bacterial = 50S + 30S

Question 29

What are some antibiotics that work by inhibiting protein synthesis?

Answer 29

ATMCO

Aminoglycosides - 30S subunit
Tetracyclines - 30S subunit
MLS Group (Macrolides, Lincosamides, Streptogramins) - 50S subunit
Chloamphenicol - 50S subunit
Oxazolidinones - 23S subunit of 50S

Question 30

MoA of aminoglycosides?

Which class of antibiotics can be used in combination to produce a synergistic effect?

Answer 30

Binds to amino-acyl site of the 30S ribosomal subunit and prevents elongation of the polypeptide chain

B-lactams (eg. in endocarditis)

Question 31

Major side effect of aminoglycosides? prevetion?

Answer 31

Ototoxic and nephrotoxic - monitor levels

Question 32

Limitations of aminoglycosides?

Answer 32

No activity against anaerobes

Inhibited by low pH - won’t work in abscesses

Question 33

Examples of Aminoglycosides?

Answer 33

Gentamicin

Amikacin

Tobramycin

Question 34

What are tetracyclines? activity against what?

Examples of tetracyclines?

Answer 34

Broad-spectrum agents with activity against intracellular pathogens - no cell wall (e.g. Chlamydiae, Rickettsiae and Mycoplasmas) as well as most conventional bacteria

Doxycycline
Lymecycline

Question 35

MoA of tetracyclines?

Answer 35

Binds to the ribosomal 30S subunit and prevents the binding of aminoacyl-tRNA to the ribosomal acceptor site, thereby inhibiting protein synthesis

Question 36

Major issue w/ tetracycline use in terms of effectiveness?

How has this been overcome?

Answer 36

Most gram -ves show widespread resistance

Tigacycline - broadened spectrum of tetracyclines

Question 37

Characteristic side effect of tetracyclines?

Who should not recieve tetracycline treatment and why?

Answer 37

Light sensitive rash

Children and pregnant women - Because it can deposit in bone and cause discoloration of growing teeth

Question 38

Examples of macrolides?

Answer 38

Erythromycin

Clarithromycin

Azithromycin

Question 39

MoA of macrolides?

Limitation

Answer 39

Binds to the 50S ribosomal subunit and interferes with translation
Also stimulates the dissociation of peptidyl-tRNA

Limited activity against gram -ves due to outer membrane (generally gram -ve are macrolide resistant)

Question 40

What does the MLS group of abx consist of + examples of each?

Answer 40

Macrolides - Azithromycin

Lincosamides - Clindamycin

Streptogramins - Synercid

Question 41

MoA of Oxazolidinones + example?

Answer 41

Binds to the 23S components of the 50S subunit to prevent the formation of a functional 70S initiation complex (needed for translation)

Linezolid

Question 42

What are Oxazolidinones active against?

Drawbacks of their use?

Answer 42

Highly active against gram-positives (including MRSA and VRE)
Not active against Gram-negatives

Expensive + may cause optic neuritis, thrombocytopaenia and anaemia

Question 43

What types of abx inhibit DNA synthesis + examples of each?

Answer 43

Quinolones:
Ciprofloxacin
Moxifloxacin
Levofloxacin

Nitroimidazoles:
Metronidazole
Tinidazole

Question 44

MoA of Quinolones?

Answer 44

Acts on the alpha-subunit of DNA gyrase predominantly with other actions

Question 45

What are quinolones active against?

Answer 45

Broad antibacterial activity, especially against Gram-negatives, including Pseudomonas aeruginosa

NOTE: newer agents (levofloxacin, moxifloxacin) increased activity against Gram-negatives and intracellular organisms (eg chlamydia)

Question 46

Uses of quinolones? - think conditions (not organisms)

Limitations? (reasons why use has decreased)

Answer 46

UTI
Pneumonia
Atypical pneumonia
Bacterial gastroenteritis

Use has decreased due to resistance against E.Coli and side effects (tinnitus)

Note - well absorbed after oral administration

Question 47

MoA of nitroimidazoles? Coverage?

Answer 47

Under anaerobic conditions, an active intermediate is formed, which causes DNA strand breakage

Only active against anaerobic bacteria and protozoa (e.g. Giardia)
- low resistance against anaerobes

Question 48

What is a related compound to nitroimidazoles + what are their advantages?

R

Answer 48

Nitrofurans (eg. Nitrofurantoin)

Benefits:

• Concentrates in bladder - hence doesnt cause C. Diff
• Active against lots of EBSL organisms - not inhibited by mechanisms of resistance

Question 49

What drugs are inhibitors of bacterial RNA synthesis?

Examples?

Answer 49

Rifamycins such as:
Rifampicin
Rifabutin

Question 50

Main activity of rifampicin? MoA?

Answer 50

Mainly Mycobacteria and Chlamydiae

Inhibits protein synthesis by binding to DNA-dependent RNA polymerase thereby inhibiting initiation

Question 51

Side effects of Rifampicin?

Answer 51

Inducer of CYP450 - important to monitor interactions (OCP, warfarin) + LFTs

May turn urine + contact lenses orange

Question 52

Can rifampicin be used as single agent? Why?

Answer 52

No, rifampicin should never be used alone

Resistance develops rapidly due to chromosomal mutation (single amino acid change in beta-subunit of RNA polymerase)

Question 53

Name two cell membrane toxins

Answer 53

Daptomycin

Colistin

Question 54

Describe the activity of:
Daptomycin
Colistin

+specific organisms?

Answer 54

Daptomycin

• Gram-positives
• Likely to be used in treating MRSA and VRE

NOTE: it is a cyclic lipopeptide

Colistin
- Active against Gram-negatives including Pseudomonas aeruginosa, Acinetobacter baumanii and Klebsiella pneumoniae

NOTE: it is a polymyxin

Question 55

Name two families of antibiotics that work by inhibiting folate metabolism + examples?

MoA?

Answer 55

Sulphonamides - sulphamethoxazole
Diaminopyrimidines - trimethoprim

Act indirectly on DNA through interference with folic acid metabolism

NOTE: they act on sequential stages in same pathway so have synergistic action

Question 56

What is co-trimoxazole? why is this used and when?

Answer 56

Sulphamethoxazole + trimethoprim

Sulphonamide RESISTANCE is common - hence extends coverage

Useful for PCP (immunocompromised), HAP (less likely to cause C. Diff)

Question 57

What is used to treat community-accquried UTIs?

Answer 57

Trimethoprim

Question 58

List some mechanisms of antibiotic resistance.

Answer 58

INACTIVATION - Chemical modification or inactivation of the drug

ALTERED TARGET - Modification or replacement of the target

REDUCED ACCUMULATION - Reduced antibiotic accumulation (impaired uptake or enhanced efflux)

BYPASS - Bypass antibiotic-sensitive step in cell division

Question 59

Which bacteria produce beta-lactamases?

Answer 59

S. aureus and Gram-negative bacilli (coliforms)

NOTE: this is not the mechanism of resistance in pneumococcus and MRSA

Question 60

In which groups of bacteria is penicillin resistance not reported in?

Answer 60

Group A, B, C and G beta-haemolytic streptococci

Question 61

Describe how MRSA uses ‘altered targets’ as a mechanism of resistance.

Answer 61

MRSA has a mecA gene which encodes novel PBP2a (peptidoglycan transpeptidase)
This has a low affinity for binding beta-lactams therefore is not inactivated by beta-lactams

Question 62

Describe the mechanism of resistance in Streptococcus pyogenes.

Answer 62

Results from acquisition of a series of stepwise mutations in PBP genes

Lower level resistance can be overcome by increasing the dose

Question 63

What are extended spectrum beta-lactamases?

Where is this more common? Advice?

Answer 63

Able to breakdown cephalosporins as well as penicillins

Becoming more common in E. coli and Klebsiella

NOTE: if there is > 10% resistance then empirical therapy is not advised

Question 64

What are AmpC beta-lactamases?

Answer 64

Breakdown penicillins and cephalosporins but are not inhibited by clavulanic acid

Question 65

MoA of resistance to Macrolides?

Answer 65

Adenine-N6 methyltransferase modifies the 23S RNA

This reduces the binding of macrolides thereby resulting in resistance

Encoded by erm (erythromycin ribosome methylation) genes

NOTE: caution when using clindamycin in Staphylococcus and Streptococcus which is resistant to macrolides because lincosamides can induce this mechanism of resistance

Question 66

Which abx have resistance due to chemical modification or inactivation of the drug ? - INACTIVATION

Answer 66

B-Lactams

Aminoglycosides

Chlroamphenical

Question 67

Which abx have resistance due to modification or replacement of the target ? ALTERED TARGET

Answer 67

B-Lactams
Glycopeptides
Macrolides
Chloramphenicol
Linezolid
Quinolones
Rifampicin

Question 68

Which abx have resistance due to reduced antibiotic accumulation (impaired uptake or enhanced efflux) ?- REDUCED ACCUMULATION

Answer 68

B-lactams
Aminoglycosides
Tetracyclines
Chloramphenicol
Quinolones

Question 69

Which abx have resistance due to bypass antibiotic-sensitive step in cell division
?

Answer 69

Trimethoprim

Sulphonamides

Question 70

What does bactericidal and bacterostatic mean?

Answer 70

Bactericidal - Kills bacteria

Bacteriostatic - Stops bacterial growth

Question 71

Which classes of Abx are bactericidal and bacteriostatic?

Answer 71

Bactericidal:

• Anything that doesn’t work via inhibition of protein synthesis
• Protein synthesis abx = Aminoglycosides + Oxazolidinones (against strep)

Bacteriostatic:

• Only protein synthesis abx
• Except aminoglycosides + oxazolidinones (work for staph + enterococci)

Question 72

What abx work against Gram +ve?

What work against gram -ve?

Answer 72

Gram +ve:

• B-lactams (penicillins, cephalosporins, carbapenems)
• Glycopeptides
• Macrolides - useful in penicillin allergy
• Oxazolidinones

Gram -ves:

• Aminoglycosides
• Fluroquinolones

Question 73

MoA of Chloramphenicol?

Answer 73

• Chloramphenicol binds to the peptidyl transferase of the 50S ribosomal subunit
• And inhibits the formation of peptide bonds during translation