Multi Drug Resistant Organisms - Microbiology Notes PDF

Summary

These notes cover Multi Drug Resistant Organisms (MDROs) focusing on Gram-positive organisms such as MRSA, VRE, and PRSP. They detail the mechanisms of beta-lactamases and their role in antibiotic resistance, as well as their classification.

Full Transcript

▬▬▬▬ MULTI DRUG RESISTANT ORGANISMS ▬▬▬▬

MDRO – Part 1

Gram-positive organisms: MRSA (ORSA), BORSA,
PRSP, VRE & HLAR in enterococci

The β-lactamases
In order to be effective, β-lactam agents must bind to the penicillin binding proteins (PBPs) in bacterial
cell walls. In their defense, bacteria produce enzymes, called β-lactamases which open up (cleave) the
antimicrobial’s beta-lactam ring, altering the structure of the antibiotic. Once the β-lactam ring is
modified, the antimicrobial cannot bind to the PBPs, and the antimicrobial is rendered ineffective.

hundreds (well over 500) of β-lactamase enzymes have been documented
o β-lactamase enzymes have been documented against every β-lactam drug
most β-lactamases inactivate either penicillins (called penicillinases) or cephalosporins
(cefinases) – and some can inactivate both drug classes.
multiple β-lactamases are possible in the same strain of bacteria
detection of β-lactamases can be difficult: the chromogenic beta-lactamase test (Nitrocefin is
the substrate) only determines if narrow spectrum agents (e.g., penicillin and ampicillin) are
affected, and in only a few species. This direct testing is not always useful – it doesn’t tell us
which β-lactamase is produced.
many β-lactamases are found only by through looking at AST patterns in specific antimicrobials –
eg., to find the extended spectrum beta-lactamases (ESBL’s) in the Enterobacterales, we look at
the resistance/susceptibility patterns of the first and third generation cephalosporins.
hyper-production of β-lactamase can knock out a normally effective β-lactam drug. Hyper-
production = where an organism starts to produce more beta-lactamase in response to
increasing concentrations of a beta-lactam agent.
o e.g. hyper-β-lactamase producing strains of S. aureus can show resistance to oxacillin,
which is considered a penicillinase-resistant β-lactam agent
some β-lactamases are constitutive – meaning they are always produced
others are inducible - β-lactamase production is initiated (or turned on) when an organism that
has a β-lactamase gene is exposed to a β-lactam agent – for example, when the patient takes the
drug. Conversely, production is turned off when no antibiotic is present in or around the cell
β-lactamase Inhibitors: β-lactam agents are combined with β-lactamases inhibitor drugs:
clavulanic acid, tazobactam and sulbactam are the earliest ones developed.
o newer drugs: avibactam, relabactam and vaborbactam
o the β-lactamase inhibitor binds to the β-lactamase enzyme preventing it from cleaving
the β-lactam ring. β-lactamase inhibitors have no activity against the organism itself
o combination drugs now seen in our AST panels:
 amoxicillin/clavulanic acid (Augmentin) & ticarcillin/clavulanic acid (Timentin)
 piperacillin/tazobactam (Tazocin or Zosyn) & ceftolozane/tazobactam
 ampicillin/sulbactam
 ceftazidime-avibactam
 imipenem-relabactam
 meropenem-vaborbactam
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Classification of beta-lactamases

Ambler system (1980)
is based on molecular structure and amino acid
sequence
A, C, and D Class β-lactamases utilize serine for β-
lactam hydrolysis
Class B metallo- β-lactamases require divalent zinc
ions for substrate hydrolysis

Bush system (1995)
is based on the substrates that a β-lactamase
hydrolyses and which compounds can inactivate it
o specifically: beta-lactamase inhibitor drugs,
EDTA, azthreonam or cloxacillin
takes into account substrate and inhibitor profiles in an attempt to group the enzymes in ways that
can be correlated with their phenotype in clinical isolates.
these major groupings generally correlate with the more broadly based molecular classifications.
o Group 1 (Ambler class C) are cephalosporinases
o Group 2 (Ambler classes A and D), which is divided further into 8 subgroups includes:
 broad-spectrum, inhibitor-resistant β-lactamases
 extended-spectrum β-lactamases (ESBLs)
 serine carbapenemases
o Group 3 (Ambler class B) are the metallo-β-lactamases.
o Group 4 is yet undetermined

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Gram Positive β-lactamases
are exoenzymes: they are secreted by the organism and diffuse into the external medium
most are in molecular class A or Group 2a and are generally inhibited by clavulanic acid

Beta-lactamases in Staphylococci

Penicillinase:
by simple definition, staphylococci that are “S” to penicillin should be susceptible to other
penicillins, cephalosporins and carbapenems
the first penicillin resistant strain of staphylococci was reported in 1944
 just 2 yrs after the introduction of the drug
 this β-lactamase is called penicillinase.
today approx. 90% of staphylococci produce penicillinase - are therefore considered “R” to
penicillin.
these strains are “R” to the penicillinase-susceptible penicillins: penicillin, amoxicillin, ampicillin
and piperacillin
but, are generally “S” to the penicillinase-resistant penicillins: oxacillin, cloxacillin & methicillin.
(these are also called penicillinase-stable penicillins)
and are also “S” to
 the cephalosporins
 the β-lactam/β-lactam inhibitor combination drugs: e.g. amoxicillin/clavulanate,
 the relevant cephems and carbapenems
the penicillinase-resistant penicillins are NOT affected by normal levels of beta-lactamase
Inducible β-lactamases:
 if a strain of staphylococci tests “S” to penicillin, we must test for inducible β-lactamase
 exposing the strain to a beta-lactam agent first (penicillin, oxacillin or cefoxitin), and then
performing a direct β-lactamases test (test method below):

Direct β-lactamase testing of staphylococci (for both S. aureus & CoNS)
Required: growth from the edge of a zone of inhibition around either a
penicillin or cefoxitin disc OR from the ellipse edge of a penicillin or oxacillin
MIC strip
Culture must be fresh (overnight incubation)
Apply the test organism to a moistened nitrocefin test disc or strip
Incubate at room temperature (RT), following the manufacturer’s
instructions for timing – most recommend a 1 hour incubation period for
staphylococci
Observe for the development of an orange/red colour
This test is also available in liquid form – trade name is Cefinase

Penicillin Edge-Zone Test (for strains of S. aureus ‘S’ to penicillin)
Only for strains of S. aureus with penicillin zone sizes ≥ 29mm or MIC’s ≤ 0.12 ug/ml [test “s” to penicillin]
This test is NOT applicable to strains that test “R” to penicillin
Method:
Mueller Hinton Agar, #0.5 McFarland, 10 unit Penicillin disc
incubate in ambient air @ 35±2°C, 16-18 hrs
result: sharp zone edge (‘cliff’) = β-lactamase POSITIVE
result: fuzzy zone edge (‘beach’) = β-lactamase NEGATIVE

The first paper on this was published in Oct 1982 in The Journal of Clinical Microbiology. These researchers had 100% correlation for S. aureus and
97% for CoNS. CLSI updated their Tables and added this test to the M100 publication in 2013, over 30 yrs later!

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Beta-lactamases in Enterococci:

all enterococci exhibit decreased susceptibility to penicillin and ampicillin, as well as high level
resistance to semi-synthetic penicillins and most cephalosporins.
resistance to ampicillin and penicillin due to β-lactamase production cannot be reliably predicted
by AST: we must test specifically for it using the direct nitrocefin test.
the nitrocefin method as described previously, but prior exposure to the beta lactam agent is
NOT necessary (this is not an inducible beta-lactamase in enterococci)
 incubation is just 5 minutes, [a few manufacturers say 15 minutes]
 in any case, it’s less incubation time than staphylococci
if determined to be a non-β-lactamase producer, then the isolate is predictably susceptible to
ampicillin, amoxicillin, and piperacillin.
all labs will test isolates from critical specimens: blood cultures, body fluids and CSF’s
 some labs test all enterococci isolates
only reported if the result is positive
remember, they are very rare

The Gram-negative β-lactamases

these β-lactamases exist in the periplasmic space of the cell wall
o they become concentrated in that space and are always available
they vary markedly:
o may have penicillinase and/or cephalosporinase activity
o may or may not be bound by inhibitors
o may be constitutive or can be inducible
o may be chromosomal or plasmid encoded
detection is difficult – many cannot be detected by standard AST methods. For clues, we can look
at the resistance/susceptibility patterns in the antibiogram.
for the above reasons, direct β-lactamase testing is rarely done on Gram-negative organisms
o the exceptions:
 Haemophilus influenzae
 Neisseria gonorrhoeae
 Moraxella catarhalis
 and some Bacteroides species
o same test procedure as described on Pg 3
o no previous exposure to a beta-lactam
agent is required
o BUT the reaction (colour change) is
almost immediate
 why this difference from Gram-
positive organisms? beta-
lactamases produced by gram-
negative organisms are held
within the cell, they are not
secreted and therefore open the
beta-lactam ring of the
Nitrocefin very quickly.
Gram-negative cell wall

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Altered Target Resistance:
Some resistant bacteria evade antimicrobials by reprogramming or camouflaging the antimicrobial’s target.

This strategy has been observed these areas:

staphylococci against methicillin and other beta-lactam agents, i.e., MRSA (ORSA)
o ORSA (Oxacillin Resistant S. aureus) is the more accurate term
inducible resistance to clindamycin in staphylococci, BH streptococci and S. pneumoniae
enterococci against vancomycin (VRE)
vancomycin resistance in S. aureus (VISA & VRSA)
increasing resistance to penicillin in Streptococcus pneumoniae (PRSP)

A Quick Review of Penicillin-Binding Proteins (PBPs)

penicillin-binding proteins (PBPs) are a group of proteins in bacterial cell walls that are
characterized by their affinity for and binding of penicillin.
are a normal constituent in most bacteria
o the name just reflects the way by which the protein was discovered.

PBPs are members of a subgroup of enzymes called transpeptidases
o they are used in the building of the bacterial peptidoglycan layer of the cell wall
o are bound to the inner plasma membrane

each PBP has a different function in building the cell wall.
the loss of some PBPs is bactericidal (lethal), while the loss of others is less critical.
each organism possesses several PBPs.
They are numbered according to molecular weight (MW)
o the smallest PBP number has the highest MW.
o tPBP1’ in one species is different from ‘PBP1’ in another species

PBP’s can be altered in one step, or it may take several:
o in MRSA, the mecA gene alters PBP2 to PB2a in a one-step process
 (Note: you’ll also see PBP2a noted as PBP2')
o in S. pneumoniae, high level resistance to beta-lactam agents requires several successive
alterations in essential PBPs.
altered PBPs are rare in enteric Gram-negative bacilli and Pseudomonas
resistance to β-lactams in Haemophilus influenzae, Neisseria gonorrhoeae and Neisseria
meningitidis is usually by β-lactamase, but in rare cases is due to altered PBP.
o one example: BLNAR Haemophilus influenzae = beta-lactamase negative ampicillin
resistant. The direct beta-latamase test is negative, but the testing of ampicillin = I or R.
This is due to an amino acid substitutions in PBP3

most beta-lactam agents have some affinity for both gram positive and gram negative organism,
exception: aztreonam is the only β-lactam drug that has no affinity for Gram-positive PBPs

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Methicillin (Oxacillin) Resistant S. aureus – MRSA (ORSA)
Methicillin (oxacillin) resistant S. aureus are defined as strains that have MICs to oxacillin ≥ 4 ug/mL.
another way to say this: strains that have MICs to oxacillin > 2 ug/mL. (4, 8, 16, 32 and so on)
most true MRSA’s (ORSA) actually have MICs well above 16 ug/mL.
their resistance is due to an altered penicillin binding protein (PBP):
o PBP2 which is altered to PNP2a (a.k.a PBP2’).
the mecA gene is responsible for coding for this protein.

Border-line oxacillin resistant S. aureus or BORSA’s
MICs from 4-16 ug/mL
DO NOT carry the mecA gene.
resistance is due to the hyper-production of beta-lactamase.
strains test:
o “R” to oxacillin, but
o “S” to amoxicillin/clavulanic acid.
Research: OX disc testing on MHA @ 30C can detect BORSA’s (Zones 10-13 mm)*

Modified S. aureus (MODSA) – emerging group.
Similar to MRSA strains, MODSA do not become susceptible to penicillinase resistant penicillins (PRPs) after the addition
of a beta-lactamase inhibitor. These modifications typically involve PBP3 and/or PBP4, and result from the selective pressure
of beta-lactam antibiotics.**

the first step in determining whether a strain of S. aureus is a true MRSA (ORSA), is to first
confirm that the organism is indeed Staphylococcus aureus
o our usual ID battery of colony morphology, smear, catalase, slide coagulase and tube
coagulase or Latex coagulase testing (Staphaurex, etc.) is not acceptable for confirming
the ID of S. aureus when we suspect it to be an MRSA (ORSA)
o a full biochemical/phenotypic ID is required,
 Microscan panel, Vitek or Phoenix card or API strip are all acceptable
 Maldi ID acceptable, but is usually confirmed with TC
o other species of staphylococci can be TC POS and R to oxacillin – e.g., S. intermedius
latex testing kits specific for PBP2a have been developed and are in use in most clinical labs
o are rapid and can be done from primary plates
o on the first day that S. aureus is suspected, are a quick screen for MRSA (ORSA)
o these can also be used with coagulase negative staphylococci
o if POS, strain has PBP2a = mecA gene

Antimicrobial Susceptibility Testing:

determining an isolate’s susceptibility to oxacillin is done for both patient treatment and Infection
Control reasons
o hospitals are always looking for MRSA (ORSA) clusters and outbreaks
all clinically significant isolates of S.aureus require testing for resistance to oxacillin
o test oxacillin OR test just cefoxitin (a surrogate drug for oxacillin)
o oxacillin MIC from instrument panels is not valid (CLSI) – time & temperature issues
as most MRSA strains are R due to mecA mediated resistance, determining whether or not a strain
has the mecA gene is critical (remember that resistance is not always expressed)
the two most accurate methods for predicting mecA mediated resistance to oxacillin are:
o testing for the mecA gene by PCR &
o using a latex kit to detect the PBP2a protein products of the mecA gene

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MRSA strains are hetero-resistant: have both “S” and “R” subpopulations
o heteroresistance issue: the resistant subpopulation is slower growing
o this is why we have to use the direct inoculum method to set up all AST for
staphylococci, and cannot use the growth/log phase method.

three AST methods are available to determine resistance to oxacillin in strains of S. aureus:
1. broth dilution, both macro and micro methods
2. gradient diffusion - Etest
3. agar dilution method – OX screening medium

Method 1: Broth Dilution

disc diffusion testing is not reliable for oxacillin – has been for about a decade
therefore an MIC method is required
broth dilution:
o CAMHB (cation adjusted Mueller Hinton broth) with 2% NaCl
o incubate: ambient, 33-35°C, full 24 hrs,
o reminder 1: temperatures above 35C can inhibit the resistant sub-population
o reminder 2: drugs other than oxacillin can be read at 16 – 20 hrs, incubation temperature
35 ± 2°C and extra NaCl is not required
micro-broth results from automated instruments are not valid – testing must be done off-line.
Why? incubation times & temperature.

Method 2: Gradient Diffusion

MIC strips – Etest (Biomerieux) or MICEvaluator (Oxoid)
MHA with 2% salt (the higher salt content pushes expression of the mecA gene without affecting
the susceptible sub-population)
#0.5 McFarland, colony suspension method only – never use the growth method.
o Note: a #1.0 McFarland is used in laboratories that use EUCAST standards. CLSI will
most likely move to this at some point in the coming years
incubate: ambient, 33-35°C, for a full 24 hrs – note the slightly lower temperature

a – oxacillin disc diffusion (note tiny colonies in zone) – disc diffusion is no longer CLSI approved
b – oxacillin Etest MIC strip: shows heteroresistance: some cells test as R, while others test S
c– oxacillin Etest MIC strip: a fully resistant strain

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Method 3: Oxacillin resistance screening – agar dilution

this method screens for strains of S aureus that have an MIC above 4 ug/mL ( ≥ 8)
o Note: CLSI breakpoints:
 S. aureus: ≤ 2 is ‘S’ ≥ 4 is ‘R’ [no ‘I’ breakpoints]
 CoNS: ≤ 1 is ‘S’ ≥ 1 is ‘R’ [no ‘I’ breakpoints]
procedure:
o a #0.5 McFarland standard colony suspension inoculum
o spotted onto a MHA plate with 4% NaCl and 6ug/mL of oxacillin
o incubation is at 33-35°C for a full 24 hours (note temperature & time)
interpretation:
o any growth (even 1 colony): sub to a BAP and test conventionally – MIC strip, etc…
o no growth: oxacillin “S”
detection of MRSA is optimized with increased salt and the lower temperature
o slightly lower temp helps us find R subpopulations
o MRSA strains grow well at the higher salt concentration
 it pushes the expression of the mecA gene
 non-MRSA strains are also slowed down a bit by the high salt concentrations
this method is used for S. aureus only
used primarily by larger volume labs testing many strains of S. aureus in a day
o to avoid having to do an MIC strip on each strain - which is expensive.
some recent reports indicate that up to 6% of MRSA are missed with this screening
o strains with mic’s of 4 ug/mL are not detected
o suggestion has been made to move to 2 ug/mL screen
 but this would also pick up many BORSA’s – so confuses the issue
o remember: most true MRSA have MIC’s above 16 ug/mL

Agar dilution plates after 24 hrs incubation:

Left MHA w/4% NaCl only (Growth Controls) – 52 strains tested on one plate (too many IMO!)
Right MHA w/4% NaCl & 6ug/mL oxacillin: 4 strains are R to oxacillin, 48 are S

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Treatment of infections with MRSA

since the altered PBP affects the ability of all beta-lactam agents to bind to staphylococcal
cells, all penicillins, cephalosporins, carbapenems and beta-lactam/beta-lactamase inhibitor
combinations should be reported as resistant, regardless of the in vitro testing results
most MRSAs are multi-resistant, e.g. resistant to macrolides, quinolones and aminoglycosides
community-acquired MRSA (CA-MRSA) were at one time fairly susceptible to other classes
of antibiotics but are becoming as resistant as the hospital strains
o notably isolates possessing genes for the Panton-Valentine leukocidins (PVL) toxin
vancomycin and teicoplanin are most commonly used, IV only
ceftaroline – a new cephalosporin subclass (a Test/Report Group B drug or 2nd line for us)

Vancomycin
has long been the drug of choice to treat MRSA infections
its efficacy is now being questioned:
o slow bactericidal activity
o emerging resistant strains
o possible ‘MIC creep’ among susceptible strains
o tissue penetration is variable (affected by inflammation); limited penetration into bone,
lung and CNS

Teicoplanin
a glycopeptide, similar activity as vancomycin
not approved for use by the FDA or Health Canada – used extensively in Europe
effective against MRSA
fewer side effects than vancomycin – less nephrotoxicity, less ‘red man’ syndrome

Ceftaroline
CLSI categorizes this drug as a cephem
a new subclass of cephalosporin: cephalosporins with anti-MRSA activity
has a high affinity for PBP2, including PBP2a
side effects: diarrhea, nausea and headache
not yet approved for use in Canada, USA & Europe only (2020)

Other treatment options
the tetracyclines and SXT are seen as viable alternatives for treating MRSA infections,
particularly if it’s community-acquired and non-invasive
clindamycin , although not specifically approved for MRSA, is used extensively as it is
efficient with S. aureus
rifampin is also often used, but due to rapid development of resistance, is not recommended
for monotherapy
newer drugs have been developed to treat serious infections:
o linezolid, daptomycin and tigecycline: costly and have serious side effects

Linezolid (Zyvoxam)
an Oxazolidinone, inhibits protein synthesis
used for MRSA, VISA, E. faecium VRE, and PRSP
ineffective for Gram-negative infections, mixed infections
toxic effects: bone marrow suppression
Note - in 2007 the FDA issued an alert that linezolid should NOT be used for catheter-related
infections; a Feb. 2009 article in IDSA News (Infectious Disease Society of America News)
states that studies to date are still insufficient to lift this warning and advises that vancomycin
continue to be the first-line choice

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Daptomycin
a lipopeptide, it disrupts the Gram-positive organism’s cell membrane by the formation of
transmembrane channels
cannot permeate the outer membrane of Gram-negative organisms
rapid – bactericidal activity against
o staphylococci (MRSA, VISA, and VRSA)
o enterococci, including VRE
o streptococci including drug-resistant S. pneumoniae
o most other aerobic and anaerobic Gram-positive bacteria
toxic effects: myopathies (affects muscle function)

Tigecycline (Tygacil)
a new class = glycylcyclines, similar to the tetracyclines
received FDA approval in June 2005
bacteriostatic, inhibits protein synthesis – binds to the 30s ribosomal subunit
effective against both Gram positive, gram negative organisms and anaerobes
MRSA, Stenotrophomonas maltophilia, Haemophilus influenzae, N. gonorrhoeae, and multi-
drug resistant strains of Acinetobacter baumanii
has no activity against Pseudomonas aeruginosa or Proteus species
IV only
side effects: diarrheae, nausea, vomiting
not for children or pregnant women: affects teeth and bones as do the tetracyclines

Screening Patients for MRSA carriage
done to detect carriage = colonization in the absence of infection
done for purposes of Infection Control and possibly for decontamination
patients are screened directly for carriage of MRSA
screened patients include:
 in-patients transferred from another hospital
 patients in ward outbreaks
 patients with a previous admission to an out-of-Canada hospital
MRSA is increasingly seen as community-acquired (CA-MRSA)
the big question: should we screen all admitted patients?
the move in many hospitals is to pre-screen all elective surgery patients about one week before
admission = if POS  treatment with mupirocin gel (applied topically for 4 days)
light therapy becoming the norm: methylene blue solution + UV light
critical surgeries are the priority for now:
 open heart and other cardiac
 thoracic
 orthopedic
real-time PCR is available for ER admissions
specific anatomical sites are screened:
 anterior nares: if both Lt and Rt nares are swabbed, inoculate both swabs on to one plate.
 axillae (as above “bilateral”)
 wounds, drain sites, etc.
o especially if the patient was previous MRSA positive

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Screening Procedures

traditional: mannitol salt agar
o contains 2mg/L oxacillin (MSAO)
o mannitol fermenters: yellow colonies =
possible MRSA
o CoNS produce white or pink colonies
o note: there are rare mannitol fermenting
CNS
o further workup is required to confirm ID
o BAP often inoculated along w/MSAO

common today: MRSA chromogenic agar
o inoculate chromogenic agar directly with specimen swab, streak for isolation
o incubate at 35ºC, check daily for up to 72 hours
o some formulas are read at 24 - 28hrs – no re-incubation required
o the detection colour varies by manufacturer
o use antimicrobials & chromogenic substrates
 formulas are proprietary

 MRSA Smart Agar
(Biomerieux)

MRSA Select II 
(BioRad)

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Example of the workup of suspect MRSA colonies from screening agars

growth on CHROM agar → smear, catalase, slide coag, tube coagulase w/BAPpp
if TC + at 4hrs notify Infection Control (asap if this is a new patient)
if TC – from the CHROM agar, it must be repeated from the BAPpp
BAP is also used for susceptibility testing
o full ID panel is also required – to verify the identification
perform susceptibility testing (AST)
mecA molecular testing may be done at this point to confirm MRSA
o or latex PBP2a kit
AST testing may also be performed to test the decontamination drugs
o the efficacy of these antibiotics is debatable
o patients will re-colonize
o typical agents: rifampin, mupirocin (e.g. Bactroban™ applied to the skin or
nares), fusidic acid
o in Jan 2009, CLSI added high-level mupirocin resistance testing to AST
guidelines for S. aureus (uses a 200-μg disk).

A few notes on other Staphylococcus spp. and screening tests:

Staphylococcus lugdenensis
 CLSI Tables: is included in the S. aureus Group
 cefoxitin: follow the procedures for S. aureus
 use MHA w/2% NaCl for oxacillin testing – all staphylococci
 but, the agar dilution screen method (MHA w/ 4% NaCl and 6 ug/mL oxacillin)
that is used to detect oxacillin resistance applies to S. aureus only

CoNS (coagulase-negative staphylococci)
 procedures for CoNS do not include S. lugdenensis
 testing for oxacillin resistance for mecA-mediated oxacillin resistance in the
CoNS is only done by cefoxitin disk diffusion.
see CLSI Table 3E – broth dilution only lists S. aureus & S.
lugdunensis
but, incubation time and zone diameters for other CoNS differ from the
S. aureus Group
o full 24 hrs incubation is still required
 use MHA w/2% NaCl for oxacillin testing – used for all staphylococci
 but, the agar dilution screen method (MHA w/ 4% NaCl and 6 ug/mL oxacillin)
used to detect oxacillin resistance applies to S. aureus only
WHY?
CoNS breakpoints for oxacillin are: S 20 mm), no other beta-lactams need to be tested.
o if the screening result is < 20 mm, all beta-lactam agents are tested by MIC method.
others that may be tested and reported: and vancomycin, as well as erythromycin, SXT,
tetracycline, clindamycin and even cefepime (a fourth gen cephalosporin) and telithromycin ( the
first ketolide antibiotic, similar to the macrolides).
for CSF isolates: only penicillin, cefotaxime, ceftriaxone, meropenem & vancomycin should be
reported
o oxacillin disc screening method is never done for isolates from CSF → MIC right away
o most clinical labs treat blood culture and body fluid isolates the same as CSF isolates
o both the MIC value and the interpretation should be reported (not just S, I or R)
o for example: for an MIC of 0.32 μg/mL, the report might read something like this:

“Penicillin MIC = 0.32 μg/mL Interpretation: Intermediate (I) resistance”

For isolates of S. pneumoniae isolated from CSF, only the meningitis breakpoints need be reported.
For isolates recovered from non-CSF isolates, meningitis, non-meningitis plus the oral Pen G results are all
reported. This is due to concerns over these infections seeding to the meninges.

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Vancomycin-Binding Proteins
vancomycin binds to the pentapeptide peptidoglycan precursor molecule as it exists in the
cytoplasmic membrane. When this occurs, transpeptidation, the cross linking needed to build the
cell wall, cannot occur. A normally functioning cell wall cannot be built.

the vancomycin resistance gene cluster in enterococci codes for the precursor proteins that modify
the vancomycin target binding site from D-ala:D-ala to D-ala:D-lac.. The altered pentapeptide
structure is functional for the organism, but will not bind vancomycin. This makes the drug
ineffective

the most important genes involved in vancomycin resistance are vanA, vanB and vanC.

o vanA - altered cell wall precursor molecules confer high-level vancomycin resistance in
Enterococcus spp. with the vanA gene - they don’t bind vancomycin OR teicoplanin.
 the first VRE isolates were found in the US and Canada in the 1980’s
 in 2014 – there were 294 reported cases in Canada.
o the vanB cluster produces a carboxypeptidase that acts on the pentapeptide and produces
similar changes, but confers only intermediate resistance to vancomycin, and does not
confer any resistance to teicoplanin

o vanC codes for an intrinsic, low level resistance that is not transfereable.

o vanA and vanB both code for a high level resistance that is transferable within the species
and across genera.

VISA: vancomycin intermediate S. aureus
o MIC’s of 8 – 16 ug/mL
o first isolated in Japan in 1997, in the US in 2020
 Michigan, a patient on peritoneal dialysis: a S. aureus that was both MRSA &
VISA.
o 17 confirmed US cases as of 2007, 1 case confirmed in Canada to date
o mechanism of resistance is not completely understood.

VRSA: vancomycin resistant S. aureus.
o MIC > 32 ug/mL
o resistance coded by vanA
o VRSA was first documented in the US in 2002
o 13 confirmed US cases to 2014, no cases in Canada to 2014

Watching for this resistance in S. aureus is the reason we are now doing an MIC method for
testing strains of S. aureus to vancomycin.

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Vancomycin Resistant Enterococci (VRE)
The enterococci, as a group, tend to be resistant to a number of antibiotics: cephalosporins,
aminoglycosides, clindamycin, oxacillin and trimethoprim-sulfamethoxazole, regardless of testing results.

enterococci are not a major cause of infection in the outpatient population
are an increasing cause of nosocomial infections – immunocompromised patients
o urinary tract infections, endocarditis, wound and intra-abdominal infections
o most infections are endogenous but cross infection between patients can occur
vancomycin is one of the few drugs that can be used to treat these infections.
since their first appearance in 1988, the vancomycin-resistant enterococci (VRE) have emerged
worldwide and are becoming an increasing problem in clinical settings.

Acquired high-level vancomycin resistance
genes are carried on plasmids, which make them easy to spread.
seen most commonly in E. faecalis and E. faecium
o but can occur in other species (rare).
the genes of concern:
o vanA gene, which produces an MIC of >128 mg/L
o vanB, with MIC’s of 64-128 mg/L
the vanA gene has been transferred to S. aureus (VRSA).

Intrinsic low-level resistance to vancomycin
is seen in the species E. casseliflavus, E. mundtii and E.gallinarum.
gene responsible for low level, intrinsic resistance is vanC,
o typically produces MICs of 2-16 mg/L.
VanD, vanE and vanG have only recently been characterized.

Enterococci of significance
it is important to distinguish between the Enterococcus spp. for infection control purposes and to
guide treatment
Enterococcus faecalis and E. faecium are the most commonly isolated
o are the most likely to carry the vanA and vanB genes
intrinsically resistant enterococci are usually not clinically significant
o have not been implicated in outbreaks
o vanC genes are not transferable between organisms
full ID to the species is not necessary if preliminary tests point to one of the intrinsically resistant
enterococci
the following chart provides test reactions that are used to screen vancomycin resistant enterococci

E. faecalis E. faecium E. gallinarum E. casseliflavus E. mundtii E. raffinosis

Motility - - + + - -

Pigment - - - + + -
Sorbitol ferm
- - - - - +
Arabinose ferm
- + + + + +
Pyruvate ferm
+ - - V - +
2 hr xylose
- - +

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use a a swab to detect the yellow-orange pigment of E. casseliflavus and E. mundtii
o if pigment test is NEG, these two are ruled out
o if pigment is POS = not a clinically significant VRE

pigment NEG  proceed to the 2 hour xylose test:
o if POS = E gallinarum,
o if NEG = proceed to other tests or full ID

motility tests may be done by one of :
o motility media (overnight incubation) or
o direct microscopy = fresh growth: after 2 hr incubation at 30°C

all clinically significant isolates of Enterococcus spp. are screened for vancomycin resistance

disk diffusion is still used – but we read vancomycin with transmitted light!
o and a full 24 hr incubation is required

vancomycin resistance is not be easily detected in all automated systems
o incubation time required for microbroth dilution is a full 24 hrs – but most instruments
read and discard the panel at 16hrs [or even earlier].
 16 – 20 hrs for the other drugs

agar dilution screening is used: 6 µg/mL vancomycin in brain heart infusion (BHI) agar
o a #0.5 McFarland suspension is spotted ont a BHIA w/6ug/mL vancomycin
o read only after a full 24 hours of incubation.
o all positive screen results must be confirmed by an MIC method
o in serious infections/critical sires, beta-lactamase and synergy testing is also performed.
o why 6 µg/mL? Breakpoint for S is ≤ 4 µg/mL
o why BHI and not MHA? a few reasons:
o studies conducted in the ‘90’s showed that most strains of E. galiinarum did not
grow on the MHA, so were missed
 MHA was often more difficult to read – enterococci are very transluscent on
MHA, and incubation to 48hrs was often required.
 on BHI, enterococcus produces more ‘opaque’ growth at 24hrs - easier to read.
 paper published in 1994 in the Journal of Clinical Microbiology

Screening Patients for VRE Carriage
purpose: to detect VRE carriage = colonization in the absence of infection

done for Infection Control purposes only
o patients identified VRE POS by screening are considered colonized, NOT infected
o why screen?
 VRE can contaminate the environment around a patient
contamination increases with diarrheae
 can survive on hard surfaces for days even weeks
commodes, shower chairs, patient lockers, bedtables, handrails, etc.
o hospital wide screening is not recommended
 selective admission and/or interval screening of high-risk inpatient groups only

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risk factors for VRE carriage:
o severe underlying disease (e.g., long term dialysis patients)
o recent hospitalization
 particularly admission to an intensive care unit
o prolonged or broad spectrum antibiotic use – particularly vancomycin
o long duration hospital stay
o indwelling urinary catheter
o close contact with a VRE carrier – caregiver handling soiled diapers, linens, etc
patient factors that increase the risk of transmission of VRE
o diarrhea or uncontained fecal incontinence
o discharging wounds that cannot be contained by the dressings
o enterostomy
o poor personal hygiene (compliance or inability to manage)
risk factors for VRE infection in a health care setting
o patients with severe neutropenia
o patients undergoing a solid organ transplant
o patients requiring admission to ICU’s or neonatal units
o presence of an indwelling urinary catheter
anatomical sites screened :
o stool, perineum/rectum: most common
o neck & groin folds in neonates
o less common sites: urine, open wounds, drain sites
procedures

1. BEAV: Bile Esculin Azide Agar with 6 mg/L Vancomycin
bile inhibits Gram-positives other than enterococci
esculin differentiates
azide (sodium azide) inhibits Gram-negative organisms
vancomycin inhibits gram positives & selects for VRE
incubate in ambient air at 35ºC
examine daily for 72 hours
VRE on BEAV: brown-black colonies with a dark halo
work up suspect colonies :
o cs/ gpc, catalase (-) = possible enterococci → PYR
 if PYR (+) → speciate
 sub to BAP for other tests including AST

2. VRE Selective Broth: a selective enrichment broth
inoculated with ‘pea sized’ stool sample or rectal swab
incubate no more than 18hrs, look for evidence of back/grey growth
then subculture to VRE selective agar
a. formulas can be customized:
i. vancomycin only
ii. vancomycin + added meropenem: suppresses gram
negatives and E. gallinarium
iii. vancomycin + added gentamicin: added recovery of
HLAR enterococci
Perform further susceptibility testing (and or vanA/vanB PCR
testing)
o Vancomycin resistant: MIC ≥ 32 μg/mL

3. a variety of Chromagar plates are commercially available:
o most identify E faecalis & E. faecium
o a few also show E. galinarium

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Example of Workflow for VRE Detection from Screening Cultures
(from the Guidelines for the Testing and Reporting of Antimicrobial Susceptibilities of VRE)

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Treatment of VRE:
Patients who test positive for VRE, are often only colonized and do not have an active infection.
Colonization is not usually treated, but if there is an infection is present, treatment is required.
Enterococci that are vancomycin resistant may still be susceptible to ampicillin.
linezolid & daptomycin: see the MRSA notes
notes on quinupristin-dalfopristin (Synercid) are below.
there have been enterococci reported that are resistant to all known antibiotics.
 Quinupristin-dalfopristin (Synercid)
a Streptogramin, interferes with protein synthesis
 suitable for all Gram-positives
 good activity against E. faecium VRE (-cidal)
 only-static against others – (so, not suitable for E. faecalis VRE)
 not considered a good choice for MRSA because of loss of efficacy if MRSA is
macrolide-lincosamide-streptogram resistant constitutively
 Teicoplanin
 a glycopeptides
 is a somewhat less toxic alternative to vancomycin
 suitable for serious infections due to vanB E. faecalis VRE and MRSA

FYI: a synergy between oxacillin and vancomycin is being researched in strains of S. aureus that are
MRSA and exhibit high level vancomycin resistance. This has been documented in strains of MRSA
recovered from patients who are also VRE carriers. Thought to be due to lateral transmission of the gene
clusters for VRE to these staphylococci. See below:

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High Level Aminoglycoside Resistance (HLAR) in Enterococci
Enterococci are characteristically resistant to a wide variety of antimicrobial agents making single-drug
therapy often ineffective.

All enterococci naturally have some low-level resistance to aminoglycosides
o this invalidates AST with the usual concentrations of antimicrobial agents
Many isolates of E. faecalis and E. faecium have acquired high-level resistance to one or more of
the aminoglycosides.
Systemic infections, such as endocarditis, are usually treated with a combination of two
antimicrobial agents:
o one specific for action against the cell wall, such as a beta-lactam or a glycopeptide (i.e.,
penicillin, ampicillin or vancomycin) and
o an aminoglycoside, which inhibits bacterial protein synthesis (i.e., gentamicin or
streptomycin).
o these agents act synergistically to enhance killing of the bacteria, since the
aminoglycoside has increased uptake into the cell after the cell wall is damaged by the
beta-lactam agent.
When an enterococcal strain has high-level resistance to aminoglycosides (HLAR), synergism will
not occur, and combination therapy with a beta-lactam drug will not be effective.
Therefore, it’s important to detect the presence of this HLAR in order to predict this synergy.
Strains that show HLR to gentamicin, the most commonly used and best aminoglycoside against
enterococci, possess one or more aminoglycoside-modifying enzymes.
o these enzymes may make them resistant to one or more of a variety of other
aminoglycosides, including tobramycin, netilmicin, and amikacin, but not streptomycin.

Other HLAR enzymes are active against streptomycin, but not gentamicin.
Thus, testing both gentamicin and streptomycin provides information on the two most active of the
aminoglycosides.
If a strain has high-level resistance to both gentamicin and streptomycin, tobramycin will not be
effective. There are some strains that will still be amikacin or netilmicin susceptible, however, and
testing for high-level resistance in these agents may be indicated.

Three routine methods for the detection of HLAR:
o agar dilution
 500 μg/mL gentamicin and 2,000 μg/mL streptomycin
 BHI agar, ambient incubation, 35°C ± 2°C, 24 hrs

o broth microdilution
 500 μg/mL gentamicin and 1,000 μg/mL streptomycin
 BHI broth, ambient incubation, 35°C ± 2°C, 24 – 48 hrs
CLSI recommends re-incubation if testing is ‘S’ after 24 hrs
this is not done with agar dilution or disc diffusion
 commercial automated systems are considered reliable
 testing is included in most Gram positive AST panels

o disk diffusion.
 standard gentamicin and streptomycin disks (10mcg each) used for routine disk
diffusion testing cannot be used for HLAR detection.
 120 μg gentamicin and 300 μg streptomycin
 MHA, ambient incubation, 35°C ± 2°C, 16 -18 hrs

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