Week 5 Cont - Protein Synthesis Inhibitors PDF

Summary

This document provides an overview of protein synthesis inhibitors, including different classes like aminoglycosides, tetracyclines, and macrolides. It also details learning objectives, mechanisms of action, and pharmacokinetic properties of these drugs.

Full Transcript

Overview of Unit: Week 5 (part 2)
Protein synthesis inhibitors
Aminoglycosides
Tetracyclines
Macrolides
Lincosamides
Streptogramins
Oxazolidinones
 Learning Objectives – Week 5 (part 2)
1. Describe the mechanism of action of each drug
2. Compare and contrast the structural differences among the
different classes of protein synthesis inhibitors
3. Identify the spectrum of activity relative to the structure-activity
relationship (SAR) of the drug
4. List their clinical uses
5. Describe their PK and PD properties that allow for their clinical
utility
6. List common important ADR
7. Identify common mechanisms of drug resistance
Bacterial Protein Synthesis
Bacterial Protein Synthesis

Ribosome moves 5’–3’ on mRNA
30S binds and decodes codon/anti-codon 30S Decoding
=

50S forms peptide bonds (peptidyl transferase) 50s form peptide
=
bond
 Protein Synthesis Inhibitors
Target 30S ribosomal subunit Target 50S ribosomal subunit
Aminoglycosides Macrolides
Gentamicin Erythromycin
Tobramycin Clarithromycin
Amikacin Azithromycin
Tetracyclines Telithromycin (ketolide)
Doxycycline Fidaxomicin* Bind to sigma subunit.

inhibit
=
transcription
Tigecycline (glycylcycline) Lincosamides ·

Minocycline Streptogramins
Oxazolidinones*
Inhibiting Protein Synthesis
 Targets 30s subunit

General Features of Aminoglycosides
 General Features of Aminoglycosides
Derived from Streptomyces (“mycin” suffix)
Amikacin derived from kanamycin
Derived from Micromonospora (“micin” suffix)
Structure: positively charged molecule containing two
amino sugars joined by a glycosidic linkage to a central
nucleus
Many positively charged groups
~ gram negative
Aids in binding to the negatively charged bacterial outer membrane
Large molecule, but not too large
Can slowly diffuse across the outer cell membrane
Aminoglycoside Structure
amino sugars

bond
>
glycosidic
 Aminoglycoside: MOA
Concentration-dependent, bactericidal peak: MIC

[High]

(low]

Binds 16S rRNA of 30S ribosomal subunit
 Concentration-Dependent
Killing Effects of Aminoglycosides
1. Low (aminoglycoside) inside the bacterial cell; high (aminoglycoside) outside
the cell
1. Drug slowly diffuses through bacterial outer membrane porins
2. Transport across cytoplasmic membrane depends on a transmembrane electrical
gradient O2 dependent
=

2. Aminoglycoside within the cell binds to 30S ribosomal subunit—misreading
"Weird
of mRNA—formation of aberrant proteins proteins
=
"

3. Aberrant proteins insert into the membrane of the bacteria
1. Pore formation in the membrane
4. Aminoglycoside drug molecules now freely pass through these pores
1. High (aminoglycoside) within the cell: complete and irreversible inhibition of ribosome
function stopping protein Synthesis
=
Pharmacokinetics: Aminoglycosides

A: poorly absorbed from GI tract Administered parenterally or via inhalation
=
Not given orally

D: low distribution in most tissues [High] in cells of the renal cortex and otic
(does not cross BBB) tissue

M: minimal to no hepatic metabolism

E: mostly excreted in urine,
Dosing based on renal function
unchanged
 Pharmacodynamics: Aminoglycosides
aprane
pass cytoplasmic
only works
D on
Spectrum: aerobic gram-negative rods bacteria that

Requires O2-dependent transport system across inner USE O2

membrane
No activity against anaerobic bacteria
Post-antibiotic effect once daily dosing
:

Narrow-therapeutic window therapeutic
low index

Pregnancy risk category: D
Positive evidence of human fetal risk
 Clinical Applications: Aminoglycosides
~

Synergism with cell wall-active agent Treating
Pseudonomas
Extend spectrum to aerobic gram-positive cocci infections

Gentamicin, tobramycin, amikacin
Hospital-acquired pneumonia (HAP)
&

Causative bacteria P Aeruginosa.

Gentamicin
Plague
Tularemia
 ADRs: Aminoglycosides

Acute kidney injury
Drug accumulation in proximal tubular
cells (can be reversible)
Ototoxicity : ear damage
Vestibular or cochlear
Can be permanent
Neuromuscular blockage
Drug competition with Ca2+; reduction in
acetylcholine release; respiratory
paralysis
 Resistance to Aminoglycosides
Plasmid-encoded production of
transferases produce
can
enzymes that
modify drug
structure

Adenylation, acetylation >
Transferases

Decreased accumulation of drug
Presence of efflux pumps =
keep drug [3 low

Mutation of drug target
Modify now
Lowers affinity to 30S subunit drug looks
 Targets 30s subunit

General Features of Tetracyclines
Y cyclic
Rings
 General Features of Tetracyclines
Structure: four fused rings
with a system of double bonds
Intracellular accumulation 123 4

Enter by passive diffusion
through porins
Active transport across inner
membrane

& work on
gram positive
B bacteria
gram negative
Tetracycline Structure
Glycylamido-group

D
overcome
resistance
(

mechanisms

D
Minocycline
 Tetracycline: MOA
Bind ____
14S rRNA of ____
30S

Blocks binding of
aminoacyl-tRNA to A-site N

Different
MOA

W
 Pharmacokinetics: Tetracyclines
A: oral absorption impaired in the
Also administered IV/IM
presence of di-/trivalent cations ex Mg, cae
,

& Available orally

D: well distributed in tissue and body Concentrate in fetal bone
fluids, sequestration in bone and teeth (pregnancy risk category D)

M: small amount of glucuronidated metabolites

E: primarily urine; bile
 Clinical Applications: Tetracyclines
·
gram positive gram negative, atypical
,

Doxycycline Broad-spectrum, bacteriostatic,
concentration-dependent; AUC/MIC
“Niche” indications
3
Gram-negative cholera, gram-positive anthrax, spirochete Lyme disease, Rickettsia
S Pneumoniae.
> M Pneumonia C Pneumonial.
,.

CAP, atypical infections
Drug - resistant

MRSA (complicated skin and soft tissue infections [SSTIs])
Tigecycline (glycylcycline)
Intra-abdominal infections (anaerobes), enterococci (VRE)
MRSA (complicated SSTIs)
CAP caused by multidrug-resistant (MDR) S. pneumoniae
Minocycline Fyl
Most commonly used for anti-inflammatory properties
Acne vulgaris, RA (off-label)
 ADRs: Tetracyclines

UV-absorbing properties lead to cutaneous
photosensitivity (sunburn)
Effects on calcified tissue
Enamel hypoplasia, tooth discoloration, shunted growth
Avoid in pregnancy and children under eight years of age
GI distress : can take wh food

Esophagitis
But remember dairy foods and antacids decrease oral absorption
Superinfections … why? Broad spectrum antibiotic
(good B bad)
 Resistance to Tetracyclines
Intrinsic resistance
Inability of microbe to accumulate the drug
Plasmid-encoded efflux pumps
Tigecycline avoids these pumps
Alteration of proteins that interfere with drug binding
to A-site Ribosomal Protection Proteins (RPPs)
:

site
Enzymatic inactivation -change binding
Fyl Omadacycline: Third Generation Tetracycline
Clinical indication
Treatment of adults with: 1234

(CAP) CABP: community-acquired bacterial pneumonia
ABSSSI: acute bacterial skin and skin structure
infections
Has activity against bacterial strains
expressing the two forms of tetracycline
resistance
out of the cell
1. Efflux pumps found on
: bacteria cell membrane =
Remove drug
2. Ribosomal protection
PK properties: PO/IV, not metabolized
ADRs: N/V, headache, infusion site reaction,
increased liver enzymes
Fyl Eravacycline: Third Generation Tetracycline
Clinical indication
Drug Resistant
Treatment of complicated intra-abdominal infections caused by
gram-positive and gram-negative bacteria in patients 18 and older
PK properties: IV only, hepatic metabolism
ADRs
N/V, infusion site reactions
Targets 50s subunit

Macrolides =
ACT by THROwing

50s MLS

TAg
30S
 General Features of Macrolides s
large
Structure: large “macro” cyclic lactone ring to which one or more sugars are attached

Erythromycin
9
1
2
6
14-membered 1
lactone ring

Interacts with ribosome

Azithromycin and clarithromycin are semisynthetic derivatives of erythromycin
Telithromycin is a semisynthetic ketolide derivative of erythromycin
derivatives of erythromycin Structures
Acid stability; Better absorption,
longer tissue penetration less GI upset

chain
side
9 Methoxy group amate
9 carb
6 12 6
1 1
12
1

Ketone group
15-membered ring sugar
sugar
Azithromycin Clarithromycin Telithromycin

Bind to two domains
interacts with 50S Ribosome in 50S subunit
 Macrolide: MOA
Amino sugar at position three Broad-spectrum, bacteriostatic,
concentration-dependent; AUC/MIC
binds 23S rRNA adjacent to the
&
peptidyl transferase center of
a end 50S subunit Ribosome is

producin -Shiftingposition
set

Inhibits ____________ of tRNA
I

Translocation

from P-site to E-site, resulting in
dissociation of incomplete
nascent peptide
Blocks ___________
Peptide bond formation
> close to peptidyl transferase center
 Pharmacokinetics: Macrolides
A: all adequately absorbed orally Erythromycin absorption reduced by food
I take on empty stomach)

Erythromycin, azithromycin accumulate in MQ
D: excellent lung tissue penetration and
Azithromycin half-life: over 60 hours
intracellular activity
All concentrate in the liver

M: all, but erythromycin, are converted to active metabolites

E: primarily bile
 ADRs: Macrolides

GI intolerance > forptw/ constipation
Erythromycin given as a GI stimulant
Hepatitis :
telithromycin
Fever, jaundice, impaired liver function
Cardiac
Prolongation of the QT interval
Ototoxicity :
damage to ear tissue
 Clinical Applications: Macrolides
"Broad Spectrum
Gram-positive
- NOT MRSA
Staphylococci, pneumococci, GAS
Gram-negative
Respiratory infections =
M.
Catarrhalis

STIs N Gonarrhea
:.

Atypicals
No anaerobic activity
Other
Lyme disease, H. pylori
 Resistance to Macrolides
Change in target site leads to decreased drug binding
Methylation of rRNA
Does not affect telithromycin 2 binding
areas
Mutation in 50S subunit
Efflux pumps
Does not affect telithromycin
Production of esterases Degrade Macrolides

Degrade macrolides
 Novel Macrocyclic Antibiotic: Fidaxomicin (Dificid)
sinhibit transcription
MOA: binding to the sigma subunit of RNA polymerase
PD: bactericidal, PAE equals 10 hours
Narrow-spectrum: active against gram-positive aerobes and
anaerobes
PK: administered orally, negligible systemic absorption,
minimal intestinal metabolism, high fecal concentration
Clinical use: C Diff infections.

ADR: N/V, GI hemorrhage
 Clindamycin
Lincosamide class D

Lincomycin natural product of
Streptomyces
Clindamycin is a synthetic derivative
Structure: amino acid derivative plus
amino sugar
MOA
Resistance same as macrolides
 Clindamycin (cont.)
Bacteriostatic or bactericidal,
concentration-dependent; AUC/MIC

Spectrum: gram-positive aerobic and anaerobic
Anaerobic gram-negative only
ADR: C. difficile-associated diarrhea (CDAD)
PK: well-absorbed orally, available IV and topical, widely
distributed in many fluids and tissues, majority excreted
as inactive metabolite in feces/bile
Clinical applications: intra-abdominal infections, toxic
shock therapy, skin and soft tissue infections
 Quinupristin/Dalfopristin (combo product)
Streptogramin A and B :
Target 50S subunit

Synergistic antibiotic isolated from
Streptomyces
Structure: macrocyclic compounds
Spectrum: gram-positive only
Clinical applications: MRSA, VRE, 30:70
Streptogramin B
penicillin-resistant pneumococci *
PK: IV formulation
ADR: pain and phlebitis at the infusion
site, arthralgias, and myalgias
Streptogramin A
 Quinupristin/Dalfopristin: MOA
Bacteriostatic separately, bactericidal together,
concentration-dependent; AUC/MIC long PAE

Dalfopristin induces conformational change in 50S
enhancing binding of quinupristin Binding site
=

Binding to different sites on the 50S bacterial ribosomal
subunit, thereby inhibiting protein synthesis
Resistance: modification of binding site, enzymatic
W
inactivation of drug, efflux pumps

Similarise
in
synthetically made Oxazolidinone: MOA
Bind to the ________
235 of ____
URNA to
prevent formation of functional ___
70S
initiation complex
Resistance: efflux pumps, a single
AA mutation in 23S rRNA of 50S
 First Generation Oxazolidinone: Linezolid
Completely synthetic Thick cell ·

Gram-positive infections only
Wall
23SRNA
Bacteriostatic or bactericidal depending on infection A

Time-dependent, bactericidal for Streptococcus infections
Allows cell
Bacteriostatic for Staphylococcus and Enterococcus infections wall
penetration
Clinical application
Resistant gram-positive infections (MRSA, VRE,
penicillin-resistant S. pneumoniae)
PK: PO/IV administration
ADRs: thrombocytopenia, serotonin syndrome
when given with other serotonin agents
Fyl Second Generation Oxazolidinone: Tedizolid
MOA: same as linezolid, but has activity 235

against mutated 23S rRNA URNA

Gram-positive infections only
Similar spectrum to linezolid A

Clinical applications Allows cell
skin infection
ABSSSI caused by linezolid-resistant MRSA
wall
penetration
Retains activity against Cfr methyltransferase
mutation to the 23S rRNA
PK: PO/IV availability
ADRs: N/V/D, C. difficile
pseudomembranous colitis