Anti-Mycobacterial Therapies - Fan 5/3/16

Question 1

major mycobacterial disease

Answer 1

tuberculosis

• latent (LTBI) : treated with isoniazid, rifampin, or combo
• active TB : always treated with combo

leprosy

M. avium Complex (MAC) infection

• M. avium, M. intracellulare, M. paratuberculosis
• complication of late stage AIDS and chronic lung disease

Question 2

anti-TB drugs (US guidelines)

Answer 2

1st line: RIPE

• rifampin (plus derivatives: rifabutin, rifapentin)
• isoniazid
• pyrazinamide
• ethambutol

2nd line

• ethionamide
• p-aminosalicylic acid
• cycloserine
• streptomycin, amikacin/kanamycin, capreomycin
• levofloxalin, moxifloxalin, gatifloxalin
• bedaquilline

Question 3

2nd line TB drugs

• guidelines
• characteristics

Answer 3

guidelines

• MDR (resistant to rifampin and isoniazid)
• XDR (MDR + resistance to a fluoroquinollone and injectable aminoglycoside)
• cases where first line drugs are effective but toxic

characteristics

• less effective than 1st line
• significant toxic side effects
• expensive

Question 4

mycobacterial wall features/targets

Answer 4

acyl lipids : targeted by

mycolate : targeted by isoniazid, ethionamide p-aminosalicylic acid (INH, ETA, PAS)

arabinogalactan : targeted by ethambutol (EBM)

lipoarabinomannan : targeted by

Question 5

drugs targeting macromolecule synthesis

Answer 5

fluoroquinolones: inhibit DNA synth

rifampin: inhibit RNA synth

streptomycin: inhibit protein synth (via 23S)

macrolides: inhibit protein synth (via 30S)

Question 6

challenges in TB treatment

Answer 6

1. dormant or slow-growing intracellular infection
   * chronic, asymptomatic infections with slow growing bacteria that can be dormant
2. Mtb is good at picking up genetic mechs for resistance
3. patient and doctor compliance

• issues with lengthy tx regimen, especially if there are side effects
• potential solution: direct observed treatment

4. strong, lipid-rich cell wall
   * potential solution: drugs targeting cell wall components
5. coincidence of TB and HIV/AIDS
   * need to treat both; be watchful for drug interactions

Question 7

Mtb mechanisms of resistance

Answer 7

genetic mechanisms

• natural resistance due to chromosomal mutation (not horizontal gene transfer)

biochemical mechanisms

• overexpression of drug target, decreased drug binding, increased drug removal
• deficiency in pro-drug activation (IHN, PZA, PSA)

Question 8

difference between tx regimen for culture positive and culture negative TB

why multiple drug therapy?

why RIPE?

Answer 8

culture positive: aggressive tx

• RIPE start, potentially taper down
• long period of tx (9mo)

culture negative: less aggressive tx

• RIPE start for 2 months
• RI for 2 months

why use multiple drugs?

much lower chance of bacteria being resistant to BOTH drugs than to one or the other

why RIPE?

no cross resistance indicated!

Question 9

de facto monotherapy

Answer 9

responsible for the devpt of resistance in patients treated with multiple drugs

can occur due to

• preexisting resistance
• poor distribution of drugs due to fibrotic tissues
• differential targeting of bacterial forms (active vs dormant forms)

Question 10

INH

isoniazid

Answer 10

• small, water soluble molecule
• bactericidal against intra- and extra-cellular mycobacteria

mechanism

• prodrug, activated by KatG (catalase peroxidase) to IHN-NAD (active) → inhibits mycolic acid synthesis

admin, PK, combo use

• oral: absorbed from GI tract and distributed
• high probability of resistance → always used in combo with others (except prophylaxis or LTBI)

Question 11

mycolic acid biosynth

role of INH

Answer 11

synthesized in two stages

FAS-I : single polypeptide that synthesize chains from C16-C26 using CoA as carrier

FAS-II : multienzyme system that lengthens FA chains to >C52

INH targets the Fab1 (InhA) unit of FAS-II

• Fab1 carries out last step in FAS-II cycle
  
  • NADH-dependent enoyl ACP reductase
• binds INH-NAD tightly in NADH binding region

Question 12

INH

adverse rxn

elimination

resistance

Answer 12

adverse rxn

• hepatitis risk
• peripheral neuropathy (10-20%)
  
  • mild form: sensory abnormality, muscle weakness
  • severe form: burning pain, muscle paralysis/wasting, organ/gland dysfx (maldigestion, difficulty breathing, low bp, etc)

WHY?

INH resembles pyridoxine, so subs in for some of those rxns → causes issues

• tx: boost vitB6 in the diet

elimination

metabolism initiated by acetylation by liver-specific N-acetyltransferase

• genetically, there are slow acetylators and fast acetylators → might influence

resistance

• KatG mutations (precludes INH-NAD formation)
• mutation of Fab1 NADH binding pocket
• mutation increasing expression of Fab1
• mutation increasing levels of NADH (outcompetes INH-NAD)

Question 13

RIF

rifampin

Answer 13

• semi-synthetic antibiotic based on rifamycin (from Streptomyces)
• inhibits RNA synth by messing with bacterial transcription elongation
• bactericidal for Gram+, Gram-, chlamydia, mycobacteria

Question 14

RIF mechanism of action, resistance

Answer 14

interacts with large beta subunit of bacterial RNA poly → blocks path of growing RNA strand → RNA poly is effectly stuck at promoter region

*doesnt bind human RNA poly! selective for bacteria

resistance occurs via mutation of beta subunit of RNApoly

• also see cross-resistance with other rifamycin derivatives

Question 15

RIF

use

administration

adverse effects

Answer 15

uses

• bactericidal against fast-growing extracellular, slow-growing intracellular mycobacteria
• effective for leprosy, atypical mycobacterial infection when used with sulfone

admin and PK

• oral admin: well absorbed and distributed
• penetrates CSF if meninges inflamed
• mainly excreted in feces

adverse rxn

• if administered under 2x weekly, flu like symptoms
• induces cytochrome P450s (incl CYP3A) to increase elimination of other drugs
  
  • might need to change the dose of RIF or sub it with other drugs
• harmless purple or red color to urine/tears

Question 16

rifabutin/rifapentine

vs

RIF

Answer 16

more potent

longer half life

better membrane permeability

less active induction of CYP3A activity: bettery compatibility with other drugs (ex. HIV and arrythmia meds)

Question 17

PZA

pyrazinamide

advantages and disadvantages

Answer 17

prodrug: converted to active form by bacterial PcnA enzyme

advantages

• synergistic with rifampin
• no cross reactivity
• persistent killer : targets dormant Mtb (not actively dividing)
  
  • combine with 2 or more others to avoid de facto monotherapy
• cheap
• oral admin (well absorbed, distributed

disadvantages

• resistance emerges rapidly (via PcnA mutation)
• hepatotoxicity, hyperuricemia, nausea, vomiting, drug fever

Question 18

PZA mech of action

Answer 18

not positive…

doesn’t target wall synth

PZA → POA (active) via PcnA

accumulation of POA kills by multiple mechs:

• disruption of energy production
• inhibition of transtranslation
• possible inhibition of pantothenate and CoA biosynth

Question 19

trans-translation

how does PZA inhibit it?

Answer 19

when stressed, translating ribosomes can become stalled → huge challenge for dormant bacteria (resources scarce)

• don’t want to toss the stalled ribo and mRNA within, want to recycle them

tmRNA (transfer-mRNA) helps do that by using an open reading frame and RpsA → gives you a rescued ribosome and a hydbrid protein product pre-tagged for degradation

role of PZA:

PZA → POA

• binds to RpsA (aka ribosomal protein S1 of the 30S subunit)
  *

Question 20

ethambutol (EMB)

Answer 20

synthetic, bacteriostatic

synergistic with other drugs

mechanism of action:

• blocks EmbA and EmbB arabinosyl transferases (incorporate arabinose into arabinogalactan layer) → weakens cell wall
• inhibits fast-growing extracellular Mtb; less effective against intracellular

Question 21

EMB

adverse effects

admin

Answer 21

admin:

• oral, well absorbed, but 50% excreted in urine unchanged (accumulation in renal failure)
• crosses blood brain barrier if meninges inflamed
• resistance pops up quick; should be used in combo with other drugs

adverse rxn

• optic neuritis and red-green color blindness at higher doses
• avoid in young children (bc unreliable vision testing)
• rare hypersensitivity

Question 22

tx for TB in HIV patients

Answer 22

immune deficiency → inefficient pathogen clearance → more aggressive regimen

consider: poor interactions of RIF with antiretrovirals (protease inhibitors, nucleoside reverse transcriptase inhibitors)
* rifabutin has fewer bad interactions

Question 23

tx for MAC infection

Answer 23

MAC complex pathogens (M. avium, M. intracellulare, M. paratuberculosis) are much less resistant to anti-TB drugs than M. tuberculosis

antibiotics: azithromycin, clarithromycin, ciproflaxin, EMB, rifabutin

• prophylaxis: with CD4s < 50/uL
• definitive, suppressive tx: higher doses (complete eradication req recovery of the immune system via ARVs)