2024 ESKAPE Pathogens Lecture 1 PDF

Summary

This document is a lecture on ESKAPE pathogens, focusing on the bacteria Enterococcus faecium and Staphylococcus aureus. It covers various aspects including virulence factors, antibiotic resistance mechanisms, and genomic analysis. It's suitable for microbiology students.

Full Transcript

Professor Christopher McDevitt
Email:
http://mcdevittlab.org
Department of Microbiology & Immunology
Peter Doherty Institute for Infection and Immunity
 Learn the bacteria that make up the
ESKAPE pathogens
Understand the key virulence, genomic
Learning and evolutionary factors that have led
to the rise of MRSA and VRE
Objectives Know the molecular mechanisms for
vancomycin and methicillin resistance in
VRE and MRSA, respectively
 “Resistance to antibiotics
could bring the end of modern
medicine as we know it”

Margaret Chan, 2012
Director-General, WHO
 Common opportunistic and nosocomial pathogens with high levels of
antibiotic resistance from multiple mechanisms

E Enterococcus faecium
S Staphylococcus aureus
K Klebsiella pneumoniae
A Acinetobacter baumannii
P Pseudomonas aeruginosa
E Enterobacter spp.
 Enterococcus faecium Staphylococcus
Klebsiella pneumoniae
aureus

Acinetobacter baumannii Pseudomonas aeruginosa Enterobacter sp.
 World Health Organization (WHO) priority pathogens for
development on new antibiotic therapeutics

Medium Priority High Priority Critical Priority

1. Streptococcus pneumoniae 1. Enterococcus faecium 1. Acinetobacter baumannii
2. Haemophilus influenzae 2. Staphylococcus aureus 2. Pseudomonas aeruginosa
3. Shigella spp. 3. Helicobacter pylori 3. Enterobacteriaceae
4. Campylobacter
5. Salmonella spp.
6. Neisseria gonorrhoeae
 Gram-positive, cocci shaped bacterium
Also known as ‘Golden Staph’
Discovered in 1884 by Friedrich Rosenbach
Non-motile and non-spore forming
Catalase positive
β-haemolytic on blood-agar plates
⍺-toxin lyses red blood cells
Common component of microbial flora
Major cause of healthcare associated infections (HAI)
>500,000 infections per year in US hospitals
>50,000 deaths each year in USA
 Skin infections
Minor skin infections such as pimples, impetigo and boils
Invasive soft-tissue infections, such as cellulitis
Food poisoning
Enterotoxigenic strains
Life threatening serious infections
Endocarditis (heart valve infections), bacteraemia, pneumonia,
osteomyelitis, implant infections
Transmission
Contact an infected object or tissue (e.g. pus)
Nosocomial infections – often from colonised healthcare workers
Community acquired/hospital acquired infections have
increased over the past 20 years
 Bacterial capsule
Adhesins
Microbial surface components that recognize
adhesive matrix molecules (MSCRAMMs)
Enable initial attachment of bacteria to host
tissue.
Biofilm formation
Enzymes
Coagulase, hyaluronidase, DNases, and lipases
Toxins
Superantigens – e.g. TSST-1
Enterotoxins
α-toxin, β-toxin, etc
 S. aureus genome
Average genome size is ~2.8 Mbp
Clinical isolates range from 2.5 – 3.0 Mbp
Genomes encode between 2,500 and 2,800 open
reading frames (strain dependent)
Core genome is only 1,441 genes
Accessory genome and unique genes make up about
80% (5,970 genes) of the pan-genomic content
Pan-genome is heavily enriched for genes
associated with mobile genetic elements
Transposons
Bacteriophages
Staphylococcal cassette chromosome (SCC) elements
 Methicillin
Semi-synthetic β-lactamase resistant penicillin introduced in 1959
Methicillin resistant S. aureus emerged in 1960
MRSA remained rare until the 1980s
Resistance due to mecA gene – alternate PBP (PBP2a)
Confers resistance to almost all β-lactam antibiotics
Unlike penicillin resistance, methicillin resistance is not
by plasmid-borne β-lactamase
Spread to many staphylococcal species
On mobile genetic elements
 Mobile genetic element transmission of methicillin resistance
SCCmec
Mobile 21-60 Kb element
Multiple SCCmec types
Similar genetic structure
Resistance acquired from environmental staphylococci
Genomic analysis show regions from environmental and
animal staphylococcal species with high levels of similarity
to MRSA SCCmec
Species include Staphylococcus sciuri, Staphylococcus
fleurettii and Staphylococcus vitulinus
 Gram-positive, cocci shaped bacterium
Occurs as pairs or as chains
Catalase negative
Associated with healthcare associated infections (HAI)
Gamma-haemolytic (i.e. non-haemolytic)
No apparent haemolysis on blood agar, but there can be a slight discolouration
Other enterococci can show haemolysis
Commensal bacterium, but can also be a pathogen
Gastrointestinal (GI) tract of humans and animals
Outbreak-related enterococci have acquired tailored gene repertoires
not present in commensal organisms
 E. faecium genome
Average genome size is ~2.85 Mbp
Animal and clinical isolates range from 2.4 – 3.4 Mbp
Genomes encode between 2,300 and 3,300 open reading
frames (strain dependent)
Core genome is only 1,013 genes
Accessory genome and unique genes make up about
two-thirds of the pan-genomic content
Pan-genome is heavily enriched for genes involved in
carbohydrate transport and metabolism
 MSCRAMMs
(microbial surface components
recognizing adhesive matrix
molecules)
 Worldwide transmission and spread of HAIs
In E. faecium:
HAIs associated with clade A, while
clade B represents commensal bacteria

Clade A features:
Altered cell wall and capsule
Missing CRISPR system
Unique phosphotransfer system
Prominent starvation tolerance
Overall better adapted to hospital environment
 HAI-related E. faecium primarily emerged
by gaining genes through horizontal gene
transfer (HGT)
HGT is a prominent driver of E. faecium
strain diversity

E. faecium genome is highly dynamic
Constant flux of accessory genes through HGT events

Acquisition of new genetic material mainly via conjugation
Not known to be naturally transformable (i.e. not naturally competent)
Acquisition of genes related to antimicrobial resistance
 E. faecium genomes contain a total of 34 unique
antibiotic resistance genes Penicillin
Average of 9 antibiotic resistance genes per genome
Significant isolate to isolate variation in resistance complement
Intrinsic resistance to most β-lactam antibiotics
Attributable to a low affinity for PBP5
b-lactam ring
Ampicillin can be used for treatment
Monotherapy for endocarditis treatment
has a relatively poor cure rate (< 40%).
Kanamycin
Intrinsic resistance to aminoglycoside antibiotics
Poor penetration into cells limits efficacy
Acquired resistance
HGT events facilitating the acquisition of new or enhancing
resistance mechanisms
 Vancomycin
Vancomycin is a glycopeptide antibiotic used to
treat Gram-positive bacterial infections
Vancomycin Resistant Enterococci (VRE)
Resistance emerged in 1980s
Leading cause of MDR infections
~80% of device associated infections such as
catheter, central line, ventilators
Limited treatment options for VRE infections
VRE colonized individuals are more likely to transmit the pathogen to
other patients
 Vancomycin inhibits cell wall synthesis in Gram-positive bacteria
Prevents D-ala D-ala moieties from
interacting with the cell wall cross-linking
enzyme
Vancomycin resistance
Change of the D-ala D-ala moiety to
D-ala D-lac reduces vancomycin binding
affinity by ~1000-fold
Other stem peptide variations have
also been observed (D-ala D-ser)
Cell wall synthesis no longer blocked
 Vancomycin is made by the soil
bacterium Amycolatopsis orientalis
Resistance mechanisms may have been
acquired from this or a related organism

Expression of an enzyme alters the
terminal residue
VanA – High level resistance to
vancomycin and teicoplanin; inducible
upon exposure to antibiotic
VanB – Low level resistance to
vancomycin; inducible upon exposure
 vanA operon carried on Tn1546
Predominantly occurs within an Inc18 family plasmid
Can also occur in a plasmid independent manner
Vancomycin intermediate S. aureus (VISA)
VISA arises from mutations that result in thicker cell wall via
increased D-Ala-D-Ala production
Vancomycin resistant S. aureus (VRSA)
Vancomycin susceptible S. aureus (VSSA) acquires resistance
vanA genes move from VRE to
Tn1546 moved from VRE to MRSA on conjugative plasmid
Tn1546 then transposed to a plasmid resident in VSSA

Vancomycin resistance not yet widespread in S. aureus
 vanB operon on Tn1549
Tn1549 carried by commensal anaerobic
gut bacteria
Mobilised via HGT within the GI tract to E.
faecium
De novo evolution of vanB-mediated
resistance also observed in patients
 Key Learning Concepts

S. aureus
Highly significant bacterial pathogen that can cause a range of acute and invasive
infections
Genome is enriched for mobile genetic elements which permits transmission of
virulence factors, such as antibiotic resistance
Methicillin resistance arises from mecA, which is on SSCmec, a mobile genetic element
E. faecium
A GI tract commensal, but also associated with outbreak as a HAI
Genomics of HAI strains reveal tailored genetic repertoires comprised of genes for
capsule formation, adherence to biotic and abiotic surfaces and biofilm formation
Vancomycin resistance in VRE is carried on mobile genetic elements, which can be
transmitted to other bacteria