Post on 21-Dec-2015
Antimicrobials 3: Resistance
Dr Fiona Walsh
Objectives of lecture
• Genetics of resistance
• Mechanisms of resistance
• Current and future problems
What’s new About Resistance?Emergence of Resistance
• 1928 Discovery of Penicillin
• 1932 Discovery of Sulphonamides
• 1940 1st identification of a -lactamase
• 1945 50% resistance to penicillin in Staphylococcus aureus
• 1950s 50% resistance to sulphonamides in E. coli
• 1970s Resistance began to be taken seriously
Worldwide Streptococcus pneumoniae resistance (2003)
Country Azithromycin % Penicillin %
Ireland 18.9 18.9
France 54.2 35.4
USA 35.4 28.7
Hong Kong 82.9 64.3
Australia 16.8 13.6
Effect of antibiotic concentration on Effect of antibiotic concentration on growth rategrowth rate
0 2 4 6 8 10 12 14
Time (Time (hours))
Bac
teria
l Con
cent
ratio
n (C
FU
/ml)
Resistant variant
Sensitive strain at sub-MIC
Sensitive strain at >MIC
Sensitive strain
10
10
10
10
10
1010
88
66
44
22
Genetics of resistance
• Intrinsic– Proteins or impenetrable
• Acquired– Chromosomal mutation and selection– Plasmid-borne resistance– Transposition (Transposons)– Integrons
Chromosome mutationSelection of a Resistant Variant
• Single mutation or series of mutations required for resistance• Clonal spread of resistance by dissemination of resistant clones
Spontaneous Mutation - Usually Independent of Antibiotic Usage
Selection of Mutation- Often by the Killing of Antibiotic Sensitive Bacteria
Plasmid-borne resistance
• Plasmid is a mobile replicating DNA circle not attached to the chromosome
• May carry resistance genes• Transfer by conjugation• May move between strains and species• Faster than chromosomal selection• Selective pressure not vital• Most clinically important mechanism
Bacterial cell sensitive to ampicillin
Plasmid Transfer of Antibiotic
Resistance genes
Bacterial cell resistant to ampicillin
chromosome
R-plasmid
sex pilus
Resistant to ampicillin
Transposition
• Transposition is migration of a cluster of genes
• Transposon is the cluster of genes, which is unable to replicate independently. It requires a plasmid or chromosome to replicate
How do plasmids acquire new genes?TRANSPOSITION - “jumping genes”
chromosome plasmid
transposon
Conservative Transposition of Class I Transposons from a Chromsomal Site
Chromosomal donor replicon
Plasmid target replicon
Host cell replication of chromosome and hence transposon
Conservative transposition mediated by transposase to target replicon
Degradation of donor replicon
Tn
Donor replicon
Fusion mediated by the action of transposase (tnpA gene product)
Cointegrate
Resolution of cointegrate by site-specific recombination between the two res sites mediated by resolvase ( tnpR gene product)
Donor replicon
res res
res
res
Target replicon
Target replicon
res
tnpA tnpR
Replicative Transposition of Class II transposons
Replication by plasmid
Transposition
Integrons
• Non-replicating cluster of genes found on plasmids and transposons of gram-negative bacteria
How do transposons acquire new genes? INTEGRONS - gene capture and expression systems
“natural” genetic engineering
chromosome
plasmid
integron
resistance gene cassette
integrase Resistance gene expressed
transposon
Mechanisms of resistance
• Impermeability
• Efflux
• Destruction/Inactivation
• Modification
• Alteration of target
• Additional target
• Hyperproduction of target
Mechanisms of Chromosomal Resistance
Impermeability TetracyclineMost antibiotics with Pseudomonas
Efflux TetracyclineFluoroquinolones
Inactivation -lactam-lactamases)Aminoglycosides (modifying enzymes)
Hyperproduction Trimethoprim
Altered Target TrimethoprimSulphonamidesFluoroquinolonesAminoglycosides
Mechanisms of Plasmid-encoded resistance
Inactivation -lactamasesAminoglycoside modifying enzymes
Acetyl transferasesAdenyl transferasesPhosphotransferases
Chloramphenicol acetyl transferase
Efflux TetracyclineChloramphenicol
Altered target TrimethoprimSulphonamides
How do bacteria resist the action of antibiotics?
tetracyclines
active efflux
penicillins
inactivation
altered target
sulphonamides
Permeability
Permeability
• Cannot penetrate cell wall• Permeability problems inherent resistance• Example:
– Pseudomonas aeruginosa few porins• Rare by mutation as energy cost• If transport system required then stopping
transport energy is easy mechanism of resistance
• Example:– Tetracycline needs active transport – Cell stops transport tetracycline cannot get into cell
Efflux
• Efflux is pumping antibiotic out of cell• Active efflux requires energy• Usually associated with porin as needs
way to pump out antibiotic through cell wall
• Mainly low level resistance• Examples:
– Streptococcus pneumoniae fluoroquinolone resistance efflux
Destruction
• Only example are β-lactamases• Very efficient and successful• Resistance to β-lactam antibiotics• Hydrolysis of β-lactam ring common to all
• Gram positives: Surrounding cell• Gram negatives: Periplasmic space
between membranes
-lactamase Action on Amoxycillin
HO
H NH
N
SN
OO
COO -
2
-lactamase
N
S
COO -H
β-lactamases
-lactamase Class
ASerine-
Penicillins
Gram + & Gram -
BMetallo-
Carbapenems
Gram + & Gram -
CSerine-
Cephalosporins
Gram -
DSerine-
Penicillins
Gram + & Gram - Gram - Gram - Gram -
Class & Active Site
Substrate
Chromosomal
Plasmid
Class A β-lactamases
• Chromosomal and plasmid
• At least 75% of all β-lactamases TEM-1
• Highly efficient against amoxycillin
• β-lactamase inhibitors developed
• TEM-1 type mutated
• Cephalosporins developed
• TEM-1 mutated
Class B and E β-lactamases
• Metallo β-lactamases
• Carbapenems
• Chromosomal induction required for sufficient production
• Combined with reduced permeability
• Limited number plasmid mediated = constitutively produced
Class C β-lactamases
• Chromosomally mediated
• Gram negative rods
• Induced
• De-repression: mutation in repressor gene
• Constitutive production of enzyme
Class C β-lactamases
• Repression/Derepression
R P β-lactamase gene1
2 Induction: Interference with repressor protein
3 R P β-lactamase gene
Mutation
β-lactamase
Class D β-lactamases
• Oxa
• Initially oxacillin now wide range of β-lactams
• Mainly plasmid mediated
• Origins unknown
• Diversity of bacterial species
Modification
• Plasmids encode a gene that adds a functional group to antibiotic
• An inactive drug no longer inhibits bacteria
A. Acetyl-transferase – acetyl groupB. Adenyl-transferase – adenyl groupC. Phospho-transferase – Phosphate group
• Chloramphenicol (acetyl) and aminoglycosides (All 3)
Action of Chloramphenicol Acetylase
O OAcAc
H
N
O
2NO
2
CH CH CH
HO
H CClOC
H
N
O
2NO
2
CH CH CH
AcO
H CClOC
N
2NO
2
CH CH CH
H CClOC
Acetyl CoA
Acetyl CoA
Aminoglycoside Modifying Enzymes
2
OOH
HO
O
HO
HO
HO CH NH 2 O
O OH
CH OH
NH2
NH2
2
NH2
Adenylase Acetylase
Phosphorylase
Acetylase
PhosphorylaseAdenylase
Modification
• Produced in cytoplasm act at entrance site of antibiotic
• Only small portion of antibiotic is modified, suggests resistance occurs by antibiotic blocking path for more antibiotic to enter.
• Moderately high levels of resistance
Target Alteration• Most common mechanism of chromosomal mutation
Aminoglycosides• Target on 30S ribosomal subunit alters• No antibiotic binding
Quinolones• Target DNA topoisomerases mutate• Prevents quinolones binding
Macrolides• Plasmid mediated addition of methyl group to target in ribosome• Chromosome mediated alteration of binding site in ribosome• Prevent macrolide binding
Additional target
• Usually plasmid mediated
• Antibiotic binds to target
• Plasmid produces additional target – less susceptible to antibiotic
• Only work if quantity of product required is low
Dihydrofolate
Tetrahydrofolate
DHFR DHFR
ChromosomePlasmid
Tp Tp
By-Pass Mechanism of Plasmid-encoded Trimethoprim Resistance
Production of an Additional Dihydrofolate Reductase
Hyperproduction of target
• Chromosomal dihydrofolate reductase hyperproduced by 100-fold
• Bind many trimethoprim molecules
• Still sufficient enzyme to function
• Highly expensive to cell
• Selective disadvantage when antibiotic not present
Current and future problems
• Multi-drug resistance current– Vancomycin-resistant Staphylococcus aureus– Vancomycin-resistant Enterococcus faecium &
Enterococcus faecalis– Carbapenem-resistant Acinetobacter baumannii
• Multi-drug resistance future– Carbapenem-resistant Pseudomonas aeruginosa– Carbapenem-resistant Klebsiella spp– Multi-resistant Mycobacterium tuberculosis– Penicillin-resistant Streptococcus pneumoniae
Key points
• Genetic methods used by bacteria in resistance spread/development
• Mechanisms used by bacteria to stop antibiotics working (Resistance)
• Examples
• Think of what we need to do to curb resistance