Master of Public Health Veterinary Public Health Specialization Environmental surveillance for extended spectrum β - lactamase genes in Enterobacteriaceae in an urban municipal wastewater treatment plant influent Christy King, B.S. Thomas Wittum, MS, PhD, Joshua Daniels, DVM, PhD Diplomate –ACVM, Jiyoung Lee, MS, PhD Submitted in Partial Completion of Requirements for the Master of Public Health Degree at The Ohio State University April, 2016
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Master of Public Health Veterinary Public Health Specialization
Environmental surveillance for extended spectrum β-lactamase genes in Enterobacteriaceae in an urban
Table 1. Summary of carbapenemase producing coliform bacteria recovered from untreated wastewater influent showing the total number of isolates that grew on MacConkey agar with reduced susceptibility to meropenem.............................................................................................30
Table 2. Carbapenemase producing bacteria recovered from untreated wastewater influent listed by species and separated by Modified Hodge Test, Carba NP test, confirmed carbapenemase producers, and KPC .......................................................................................................................31
Table 3. KPC PCR test results sorted by species...........................................................................32
Table 4. Kirby Bauer susceptibility results using Meropenem discs sorted by date and species for coliform bacteria recovered from untreated wastewater influent. .................................................33
6
Introduction
Antimicrobial resistance has become an issue of great public health importance. The
availability of appropriate and effective antibiotics in human and veterinary medicine can mean
life or death for patients with invasive bacterial infections (Roberts et al., 2009). When
antibiotics lose their ability to debilitate microbial growth, the patient that is affected may suffer.
This can result in adverse health outcomes such as the loss of milk production in dairy cattle or
even severe illness or death of a family member. Typically, carbapenem antimicrobials are
reserved as the last line of defense against severe bacterial infections in human beings because
they are active against almost all aerobic or anaerobic gram-positive or gram-negative cocci or
rods (Craig, 1997). Therefore, resistance against these types of drugs as well as the extended-
spectrum cephalosporin antimicrobials that are more commonly used, is a serious public health
threat.
Several bacterial genes are known to encode the ability to produce carbapenemase, a β-
lactam-hydrolyzing enzyme that can hydrolyze penicillins, cephalosporins, monobactams, and
carbapenems (Queenan and Bush, 2007). Carbapenemases are divided up into several different
classes, consisting of Class A, B, and C (Poirel et al., 2007). Class A carbapenemases of note
include IMI-1, IMI-2, SME-1, SME-2, SME-3, KPC-1, KPC-2, KPC-3, SHV-1, and TEM-1
(Poirel et al., 2007). All Class A carbapenemases are inhibited by clavulanic acid making them
readily identifiable using double-disk synergy testing with imipenem (Poirel et al., 2007). Class
B carbapenemases consist of a mixture of beta-lactamases and metallo-beta-lactamases (Poirel et
al., 2007). Class B carbapenemases of note include IMP-1, VIM-1, and VIM-2. Class B
carbapenemases typically work against a broad spectrum of antimicrobials including expanded-
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spectrum cephalosporins and carbapenems (Poirel et al., 2007). Metallo-beta-lactamases are
susceptible to EDTA inhibition and are not inhibited by clavulanic acid (Poirel et al., 2007).
Class D carbapenemases consist of carbapenem-hydrolyzing beta-lactamases or oxcillinases
(Poirel et al., 2007). Some Class D carbapenemases of note include OXA-23 and OXA-27. OXA
carbapenemases have been reported worldwide and demonstrate carbapenemase activity mainly
in Acinetobacter baumanii (Poirel et al., 2007).
The most well-known and widely disseminated genes include blaKPC, blaNDM-1, blaIMP,
blaVIM, and blaOXA. One of the very first Class A carbapenemases found was a KPC in 1996
which was isolated from a hospital in North Carolina (Yigit et al., 2001). This particular K.
pneumoniae isolate expressed high levels of resistance to imipenem and meropenem (Yigit et al.,
2001). Since that finding, bacteria harboring KPC genes have been found all along the eastern
coast of the United States, typically isolated from hospital patients. These findings are important
because it suggests that there is a reservoir of resistance genes in the healthcare environment and
that these genes can be easily disseminated.
Because blaKPC has been identified and isolated from hospital patients in the United
States, we hypothesized that the same resistance gene is present in hospitalized patients in
Columbus, OH. If present in patients, then these bacterial resistance genes could easily enter the
sanitary sewer system at the hospitals, and be transported to the local sewage treatment facility.
Therefore, our main objective was to sample raw sewage from the Jackson Pike Wastewater
Treatment Plant, which directly collects sewage from hospitals in Columbus, OH, and screen the
sewage for carbapenemase-producing coliform bacteria.
8
Review of the Literature: β-Lactamase Mediated Antimicrobial Resistance
Antimicrobial resistance has become an issue of great public health importance. The
availability of appropriate and effective antibiotics in human and veterinary medicine can mean
life or death for patients with invasive bacterial infections. When antibiotics lose their ability to
debilitate microbial growth, the patient that is affected may suffer. This can result in unwanted
health outcomes such as the loss of milk production in dairy cattle or even severe illness or death
of a family member. Because of this, it is important to know the epidemiology, characteristics,
and history of bacteria that contain genes that confer resistance to important antimicrobial drugs.
Antimicrobials play a critically important role in both human and veterinary medicine.
They are commonly applied therapeutically when bacterial infections are diagnosed, or applied
prophylactically when bacterial infections are expected but not yet present, as is common in
some populations of agricultural animals. The Food and Drug Administration (FDA) compiles an
annual report estimating the amount of antimicrobials sold or distributed for use in food-
producing animals. The most recent report based on information collected in 2011, reports that
about 13.8 million kilograms of antimicrobials were sold or distributed in the US for use in food-
producing animals (FDA, 2011). This indicates that veterinary antimicrobial use is extremely
common in livestock populations, and certainly warranted under appropriate medical
circumstances. This area of practice is of particular importance because there is overlap with
some antibiotic classes that are used in both human medicine and for animals intended to enter
the food supply. Because there is real concern of bacterial resistance to some of these classes of
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antibiotics that may be transmitted through food, strict, judicial use of pharmaceuticals must be
used in livestock animals as well as surveillance of antimicrobial use.
One class of antimicrobials that is frequently used in both human and veterinary medicine
are the cephalosporins. Cephalosporins are β-lactam antimicrobials which act “by inhibiting the
bacterial wall synthesis i.e. the inhibition of the transpeptidation reaction of the peptidoglycan
synthesis” (Shahid et al., 2009). Cephalosporins are often classified into four different
“generations” based on their antimicrobial properties. First-generation cephalosporins are
effective against most gram-positive cocci except for enterococci, and methicillin-resistant S.
aureus (MRSA) (Shahid et al., 2009). Second-generation cephalosporins target a wide range of
gram-negative bacteria while still boasting modest activity against gram-positive species (Marsh,
1984). Third-generation cephalosporins work well against Enterobacteriacea, including some β-
lactamase-producing strains (Shahid et al., 2009). Fourth-generation cephalosporins are active
against both gram-positive and gram-negative species, which are attributed to their “poor affinity
for and increased stability to the Bush group 1 β-lactams [cephalosporin-hydrolyzing β-
lactamases not inhibited by clavulanic acid], and to their more rapid penetration across the outer
membrane of bacterial cells” (Fung-Tomc, 1997). Together, third- and fourth-generation
cephalosporins are defined as extended-spectrum cephalosporins. There is also a fifth,
unrecognized group of cephalosporins that includes the drugs ceftaroline-fosamil and
ceftobiprole, which exhibit broader activity against gram-positive organisms such as MRSA
(Bassetti et al., 2013). Carbapenems are a related group of β-lactams that are more resistant to β-
lactamase inactivation than are other cephalosporins (Shahid et al., 2009).
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The use of cephalosporins is common in both human and veterinary medicine.
Cephalosporins can be used to treat “respiratory tract infections, skin infections, urinary tract
infections, joint infections and some bone infections caused by susceptible gram-positive
bacteria” in humans (Hornish and Kotarski, 2002). In veterinary medicine, first generation
cephalosporins, including cephalexin, cephalothin, and cefazolin, are commonly used to treat
mastitis in cows. First generation cephalosporins have narrow-spectrum activity and are effective
in treating infections caused by E. coli, Haemophilus influenzae, Klebsiella spp., or Proteus
mirabilis (Hornish and Kotarski, 2002). First generation cephalosporins are also useful in
companion animal medicine for treatment of canine S. intermedius Group skin infections and
urinary tract infections (Giguère, S., Prescott, John F., Dowling,Patricia M., 2013). Second
generation cephalosporins, such as cefuroxime, can also be used to treat mastitis (Hornish and
Kotarski, 2002). Cefoxitin, another second generation cephalosporin, is commonly used to treat
mixed aerobic-anaerobic infections which may be present in cases of aspiration pneumonia,
severe bite infections, gangrene, peritonitis, and pleuritis (Giguère, S., Prescott, John F.,
Dowling,Patricia M., 2013). Third and fourth generation cephalosporins are typically reserved
for use in human and veterinary medicine for bacterial infections resistant to earlier generations
of cephalosporins.
Ceftiofur, a third-generation cephalosporin used only in veterinary medicine, is indicated
by label for use in swine, ruminants, and horses for respiratory disease (Hornish and Kotarski,
2002). It can also be used to treat metritis and foot rot in cattle (Hornish and Kotarski, 2002).
Extralabel ceftiofur use for “pasteurellosis in sheep and early mortality in chicks and turkey
poults” was common practice (Hornish and Kotarski, 2002). In 2008, the US FDA proposed
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legislation to limit the use of ceftiofur in food producing animals to exclude extralabel use.
However, this rule was withdrawn and a new rule was put in place in 2012 to prohibit the use of
cephalosporins for the use of disease prevention, inappropriate dosage levels and routes of
administration, and the use of products not approved in the major food species (FDA, 2012). The
American Veterinary Medical Association (AVMA) released a response to this ruling
specifically addressing the importance of antimicrobials for preventative use which stated,
“prevention of an infectious disease with antimicrobial therapy can potentially impact resistance
trends by decreasing the need and use of antimicrobials for herd-level treatment of disease at
higher doses, for longer duration, and with higher-potency classes” (AVMA, 2012).
Severely immunocompromised patients admitted to intensive care units in hospitals serve
as the most common infection source in human medicine (Giguère, S., Prescott, John F.,
Dowling,Patricia M., 2013). Because of this, extended-spectrum cephalosporins, especially 3rd
and 4th generation cephalosporins, are typically used to treat life-threatening diseases such as
serious infections caused by food-borne pathogens like Salmonella, Shigella and E. coli (Powers,
2015). The most common uses for cephalosporins in general in human medicine are for the
treatment of pneumonia, skin and soft tissue infections, sinusitis, urinary tract infections, and
otitis (Powers, 2015).
Meropenem, a carbapenem antibiotic, is commonly used to treat meningitis, urinary tract
infections, skin infections, septicemia, lower respiratory tract infections, and intra-abdominal
infections, because it is a highly effective broad-spectrum antibiotic (Bradley, 1997). Typically,
carbapenems are reserved as the last line of defense against severe bacterial infections because
they are active against almost all aerobic or anaerobic gram-positive or gram-negative cocci or
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rods. The World Health Organization (WHO) described carbapenems as “critically important
antimicrobials” due to their “limited therapy for infections due to multi-drug resistance” and
because it “may result from transmission of Enterobacteriaceae including E. coli and Salmonella
spp. from non-human sources.” Therefore, resistance against these types of drugs as well as
cephalosporins that are more commonly used, is a serious public health threat. In 2013, the CDC
released a report concerning antibiotic resistance threats in the United States. In this report, the
CDC identified carbapenem-resistant Enerobacteriaceae (CRE) as one of three urgent threats
(CDC, 2013).
Antimicrobial resistance can occur by three different mechanisms; target/receptor
alteration, enzymatic modification, and/or restriction of drug accumulation (Poole, 2001). Target
modification varies widely depending on the specific organism and the corresponding antibiotic.
One such example of target modification is that of Streptococcus pneumoniae resistance to β-
lactam drugs. β-lactams target the penicillin binding proteins (PBPs) that help to catalyse murein
biosyntheis which is specific to bacteria (Hakenbeck et al., 1999). Because of this specificity to
murein biosyntheis, β-lactams can be effective against a wide range of bacteria due to the
similarity in the biosynthesis pathway. However, β-lactam resistance in S. pneumoniae is
propagated by the alteration of PBPs, acquired through point mutations (Hakenbeck et al., 1999).
Mutations in PBPs, specifically in the transpeptidase-penicillin binding domain, diminish affinity
to β-lactams. An increase in the number of mutations in one PBP directly contributes to the level
of resistance shown – the more mutations, the higher the resistance.
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The second type of bacterial resistance to antibiotics is restriction of drug accumulation.
There are several different ways that bacteria are able to limit the amount (or restrict entirely) of
antibiotic that enters through the cell wall. The most common method is through the use of an
efflux pump. Efflux pumps are active transporters that lie in the cytoplasmic membrane of most
cells. Efflux systems are capable of transporting and excreting antibiotics, biocides, dyes,
detergents, fatty acids, organic solvents and homoserine lactones in and out of the cell (Poole,
2001). E. coli use multidrug efflux systems that are part of the resistance-nodulation-division
(RND) family, which allow many drugs to enter the cell. This type of resistance mechanism is
intrinsic rather than mutationally-gained or through the acquisition of extrachromosomal DNA
(Poole, 2001). Some bacteria, including, E. coli, and P. aeruginosa, can have mutations within
local repressor genes which result in the over-expression of efflux pumps (Webber and Piddock,
2003). Over-expression of efflux pumps leads to resistance to various antimicrobials of clinical
importance such as fluoroquinolones.
Alternatively, bacteria can utilize another method to restrict drug accumulation instead of
through the use of an efflux pump. Normally, the cell wall of gram-negative bacteria works as an
effective barrier to both hydrophilic and hydrophobic (Alekshun and Levy, 2007). However,
some species of bacteria have porin proteins, a result of genetic mutation. These porin proteins
act as a channel that can allow the entry/exit of antibiotics and other small molecules (Alekshun
and Levy, 2007). E. coli and P. aeruginosa are both examples of bacteria that have these porin
proteins (OmpF and OprD, respectively) (Alekshun and Levy, 2007). Both imipenem and
meropenem have the ability to enter and exit OprD (Alekshun and Levy, 2007).
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The third mechanism of bacterial resistance to antimicrobials is enzymatic modification
or elimination. β-lactamases are the primary mode of resistance to β-lactams. β-lactamases are
enzymes that inactivate antibiotics through the hydrolysis of the β-lactam ring (Thomson and
Smith, 2000). There are four classes of β-lactamases; Class A penicillinases, Class B metallo-β-
lactamases, Class C cephalosporinases and Class D oxacillinases (Thomson and Smith 2000).
This type of resistance is acquired through evolutionarily advantageous mutations or through the
collection of extrachromosomal DNA from the outside environment through transposons or
plasmids (Thomson and Smith 2000).
Bacterial acquisition of antimicrobial resistance genes can occur through two primary
routes: mutations or horizontal gene transfer. Spontaneous chromosomal mutations that
contribute to antibiotic resistance occur frequently in the microbial world. Spontaneous
mutations can be the result of mutagenesis with subsequent failure of DNA polymerase to correct
errors in the DNA strand. Accumulation of point mutations can lead to resistance, which is the
case for E. coli showing resistance to fluoroquinolones (Coates, 2012). E. coli accumulating
mutations in the Quinolone Resistance Determining Region (QRDR) are more likely to become
resistant to fluoroquinolones (Coates, 2012). Bacteria become stressed when exposed to
antimicrobials and this stress actually increases the genome mutation rate due to bacterial self-
damage (Kaufmann and Hung, 2010). This is significant because it exhibits the importance of
selective pressure in the evolution of antibiotic resistance. Mutations can also lead to over-
expression of resistance genes. Over-expression of the efflux pump is an example of how this
can contribute to antibiotic resistance. Mutations in the genome are important to consider
because these selected resistant elements can be passed vertically through bacterial progeny or
15
passed laterally to susceptible bacteria through horizontal gene transfer. Vertical transmission of
resistant bacteria has been recorded in several instances in broiler operations. Enrofloxacin-
resistant E. coli clones were isolated from dead broilers and embryonated eggs during an
outbreak of colibacillosis in a Danish broiler production in 2006, suggesting that vertical
transmission of resistant E.coli clones in food animal populations is possible (Peterson et al.,
2006).
Horizontal gene transfer accounts for the majority of resistance genotypes that are found
(Nakamura et al., 2004). Genes can be transferred from one independent organism to another by
three different mechanisms: transformation, transduction, or conjugation. Transformation is the
uptake of DNA from the environment into the cell that causes genetic alteration. E. coli is able to
rapidly take up R-factor DNA from the environment as shown by Cohen et al. in 1972.
Transduction is the transfer of genetic material from a bacteriophage into a bacterium. This has
been demonstrated in one such manner by bacteriophages that encode the virulence determinant
for toxin production in V. cholerae (Ochman et al., 2000). Conjugation occurs when bacterial
cells transfer DNA through direct contact (Amabile-Cuevas and Chicurel, 1993). One cell acts as
a donor, while the other acts as the recipient. Resistance plasmids (R plasmids) can be
transferred via conjugation between pathogenic bacteria, which was first shown in E. coli and
Shigella by Ochiai et al. and Akiba et al. in 1959 and 1960.
Mobile plasmids that harbor resistance genes (or R plasmids) that encode enzymes which
break down antibiotics have existed for many years. In 1966, one of the first enzymes recorded
was a plasmid-mediated β-lactamase found in Greece that is known as TEM (Hawkey, 2008).
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This enzyme was isolated from a gram-negative organism and the resistance gene that encodes it
has since disseminated worldwide. The TEM β-lactamase gene has spread amongst a variety of
Enterobacteriaceae species as well as Pseudomonas aeruginosa, Haemophilus influenzae, and
Neisseria gonnorhoeae (Brunton et al., 1986). TEM-1 β-lactamase confers resistance to
penicillins and early cephalosporins by hydrolyzing the β-lactam ring (Salverda et al., 2010).
TEM-1 β-lactamase now has over 170 variants described, making it still one of the most
important and widely disseminated bacterial resistance enzymes.
SHV-1 is a similar β-lactamase with narrow-spectrum activity against penicillins and
cephalosporins that also appeared in the 1960’s (Blagui et al., 2008). This β-lactamase occurs in
high frequency in K. pneumoniae and is often a plasmid-encoded gene (Chaves et al., 2001).
Like the TEM, SHV-1 has also disseminated worldwide, being reported in the United States,
Switzerland, the United Kingdom, and Africa (Shaokat et al., 1987).
One of the most widely reported β-lactamases, AmpC β-lactamase, “mediates resistance
to cefazolin, cefoxitin, most penicillins, and β-lactamase inhibitor-β-lactam combinations”
(Jacoby, 2009). P. aeruginosa, Acinetobacter spp., and several members of the
Enterobacteriaceae encode AmpC β-lactamase by chromosomal genes. Some organisms that
cannot encode AmpC β-lactamase in this manner have the ability to acquire genes through
horizontal transfer to produce the same effect (Shahid et al, 2009). Such is the case for several
different species of bacteria like Klebsiella spp., E. coli, and Salmonella, that can confer
resistance to antimicrobials by acquiring mobile genes (Hanson, 2003). The plasmid-mediated
AmpC β-lactamase, blaCMY-2, is the most widely distributed in the Enterobacteriaceae family and
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is the most common extended-spectrum β-lactamase in the US (Jacoby, 2009; Sidjabat et al.,
2009). CMY-2 is important because it can threaten therapeutic options due to its ability
configure multi-drug resistance to the following antimicrobials; trimethoprim, chloramphenicols,
sulfonamide, and amioglycosides, due to it’s ability to carry multiple resistance genes (Jacoby,
2009).
This mobile resistance gene, blaCMY-2, has been identified in isolates from both humans
and animals. In 2000, the National Antimicrobial Resistance Monitoring System (NARMS)
identified ceftriaxone-resistant Salmonella carrying blaCMY-2, isolated from human patients
across the US (Dunne et al., 2000). National surveillance by NARMS of Salmonella carrying
blaCMY-2 was sparked in part by another study done in 1998 that isolated ceftriaxone-resistant
Salmonella Typhimurium from a 12-year-old boy in Nebraska. The ceftriaxone-resistant isolate
was found to be indistinguishable from one isolate from a herd of cattle owned by the boy’s
father (Fey et al., 2000). This finding was significant because it brought into question the role of
livestock animals in the transfer of antibiotic resistant pathogens to humans.
Since then, many studies have reported finding MDR bacteria carrying blaCMY-2 isolated
from livestock species in the US. In July 2000, the Salmonella Reference Center (SRC) at the
University of Pennsylvania School of Veterinary Medicine confirmed that a Salmonella Newport
isolate from a bovine was resistant to cephalosporins. Rankin et al. further investigated this
finding by phenotypically and genotypically characterizing 42 MDR Salmonella Newport
isolates submitted to the SRC that were collected from Pennsylvania, Maryland, New York and
New Jersey. These isolates were mostly of bovine origin, but also included equine, canine, and
18
avian species and all isolates were found to be carriers of blaCMY-2 (Rankin et al., 2002). In 2005,
Alcaine et al. published a study that characterized 39 Salmonella isolates collected from cattle or
the environment in New York dairy herds. This study found 19 isolates that conveyed ceftiofur
resistance and also harbored blaCMY-2 (Alcaine et al., 2005). This mobile resistance genotype,
blaCMY-2, has also been identified in E. coli and Salmonella isolated form retail meat products
such as ground beef, beef steak, pork chops, and pork ribs purchased from grocery stores located
in Ohio and North Carolina (Mollenkopf et al., 2011).
Another β-lactamase gene that carries significant clinical interest belongs to the
extended-spectrum β-lactamase (ESBL) class and is identified as CTX-M. As a molecular class
A ESBL, CTX-M is active against extended-spectrum cephalosporins and monobactams, but not
cephamycins or carbapenems (Rossolini et al., 2008). This β-lactamase has been found in high
rates in K. pneumoniae and E. coli, isolated from hospital patients, among normal human
microflora, livestock populations, and even from companion animals (Rossolini et al., 2008).
“Typically, they derive from genes for TEM-1, TEM-2, or SHV-1 by mutations that alter the
amino acid configuration around the active site of these β-lactamases” (Paterson and Bonomo,
2005). CTX-M-type β-lactamases have been found in South America, Africa, the Far East,
Eastern Europe, Western Europe, and Northern America (Paterson and Bonomo, 2005). In fact,
clonal spread of CTX-M has been documented, specifically within Citrobacter freundii
(Gniadkowski et al., 1998). CTX-M-type β-lactamases are now considered to be the most
prevalent ESBL’s found in E. coli and K. pneumoniae isolated from humans (Rossolini et al.,
2008).
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Like blaCMY-2, blaCTX-M has been identified in MDR bacteria isolated from both humans
and animals. The first reported CTX-M resistance gene reported in the United States was
identified in a S. Typhimurium var. Copenhagen isolate from an infant recently adopted from
Russia (Zirnstein et al., 2000). In 2007, a paper published by Lewis II et al. looking at the
emergence of ESBLs at the University Health System in San Antonio, Texas stated, “CTX-M-
type ESBLs are now the most common ESBL type isolated from patients in our health care
system and may also be present but unrecognized in other U.S. locales.”
In livestock in the US, a similar phenomenon is occurring. CTX-M was first reported in
livestock in the US in 2010 from E. coli isolates harboring blaCTX-M-1 or blaCTX-M-79 (Wittum et
al., 2010). Another study screened 2,034 clinical isolates submitted for serotyping at the National
Veterinary Services Laboratory (NVSL) between October 2010 and June 2011 and identified 12
Salmonella isolates from turkeys, horses, and pigs from 6 US states that were harboring blaCTX-M-
1 (Wittum, Mollenkopf, and Erdman, 2012). Another published study reported finding blaCTX-M
in 1.6% of their samples from E. coli and K. pneumoniae originating from swine across 5 US
states (Mollenkopf et al., 2013). Also reported present in retail boneless chicken breasts
(Mollenkopf et al., 2014).
Several genes are known to encode the ability to produce carbapenemase. The most well-
known and widely dissemninated genes include blaKPC, blaNDM-1, blaIMP, blaVIM, and blaOXA.
NDM-1, IMP, and VIM are Class B carbapenemases, whereas KPC is Class A and OXA is Class
D. Class B carbapenemases are distinguished as metallo-β-lactamases. Class A carbapenemases
can be chromosome encoded or plasmid encoded (Nordmann, Patrice, 2011). They are partially
inhibited by clavulanic acid, but still hydrolyze carbapenems (Nordmann, Patrice, 2011). Class B
20
metallo-β-lactamases are usually integron-encoded and their activity is inhibited by EDTA
(Nordmann, Patrice, 2011). This class hydolyzes all β-lactams except aztreonam (Nordmann,
Patrice, 2011). Class D enzymes are plasmid encoded, weakly hydrolyze carbapenems, and their
activity is not inhibited by EDTA or clavulanic acid (Nordmann, Patrice, 2011).
One of the very first Class A carbapenemases found was a KPC in 1996 which was
isolated from a hospital in North Carolina (Yigit et al., 2001). This particular K. pneumoniae
isolate expressed high levels of resistance to imipenem and meropenem (Yigit et al., 2001).
Since that finding, bacteria harboring KPC’s have been found all along the eastern coast of the
United States. Through the Meropenem Yearly Susceptibility Test Information Collection
(MYSTIC) Program, a study was performed by Deshpande et al in 2006 looking at the past 6
years of data for surveillance of blaKPC. Researchers detected blaKPC in K. pneumoniae and C.
freundii from medical centers in New York and Delaware and in E. coli from hospitals in New
York and Ohio (Deshpande et al, 2006). KPC-1 has been identified in K. pneumoniae isolated
from a hospital in North Carolina (Yigit et al, 2001). KPC-2 and 3 were identified in K.
pneumoniae from hospitals in Massachusetts (Hossain et al., 2004). KPC findings have also been
reported in Greece, China, Israel, Puerto Rico, and Columbia (Nordmann et al., 2009; Navon-
Venezia et al., 2009).
NDM-1 (New Delhi Metallo-betalactamase-1), a class B metallo-β-lactamase, was first
discovered in a Swedish patient of Indian origin who was traveling to New Delhi, India (Yong et
al., 2009). A carbapenem-resistant K. pneumoniae strain carrying blaNDM-1 on plasmids of
varying sizes caused a urinary tract infection to develop (Kumarasamy et al., 2010). This
21
carbapenem resistance gene has since been found in Enterobacteriaceae in India, Pakistan, and
the United Kingdom, and has been widely disseminated in drinking water and the environment
(Kumarasamy et al., 2010).
Current literature on ESBLs cultured from sewage treatment plants in the US is limited.
In 2003, a study was performed looking at antibiotic-resistant bacteria isolated from wastewater
and river bank water from Mainz, Germany. The study identified vancomycin-resistant
enterococci and beta-lactam-hydrolysing Enterobacteriaceae harboring vanA and ampC
respectively (Schwartz et al., 2003). Another study published in 2007 identified E. coli resistant
to ampicillin, cephalothin, nalidixic acid, and tetracycline along the east coast of Australia, but
did not further characterize these isolates genotypically (Watkinson et al., 2007). However,
another study done in Australia in 2009 sampled 5 different sewage treatment plants and tested
for the presence of ESBL E. coli and found 61.1% of their isolates to be positive. From those
isolates, both blaCTX-M and blaTEM were identified (Reinthaler et al., 2010). In 2010, samples
were collected from wastewater in Algiers region, Algeria and screened for ESBL K.
pneumoniae. The study identified 84 isolates which all harbored blaCTX-M-1 and several virulence
factors such as entB, uge, and wabG, among others (Atmani et al., 2015). Because of the lack of
literature on Enterobacteriaceae harboring blaKPC isolated from wastewater treatment plants in
the US, this project will contribute significantly to the knowledge base of resistance genes
present in aquatic environments.
22
Materials and Methods
Source of the isolates. Samples were collected from the Jackson Pike Waste Water
Treatment Plant located in Columbus, OH from June and August of 2011 and 2012 and from
May to July of 2014. Incoming, untreated wastewater (influent) was the target for sample
collection. At the time of sample collection, two 50 mL falcon tubes were filled with primary
influent, transported at ambient temperature to our research laboratory, and separated into 6, 1
mL aliquots per 50 mL falcon tube creating a total of 12 samples per plant visit. The Jackson
Pike Waste Water Treatment Plant was visited 30 times over the span of 4 summers, giving a
total of 369 samples. Samples were initiated for processing the same day for culture and isolation
of extended-spectrum cephalosporin resistant coliform bacteria.
Bacterial culture. For the recovery of coliform bacteria resistant to extended-spectrum
cephalosporins, 1 mL of influent was added to 9 mL of MacConkey broth containing either
cefotaxime 4 ug/ml or meropenem 1 ug/ml. For each visit, half of the samples (6, 1 mL aliquots)
were processed in MacConkey broth containing cefotaxime 4 ug/ml, and the other half of the
samples (6, 1 mL aliquots) were processed in MacConkey broth containing meropenem 1 ug/ml.
In June of 2012, MacConkey broth containing cefotaxime 4 ug/ml was determined to be an
effective initial screening process for coliform bacteria resistant to extended-spectrum
cephalosporins and all samples processed after this time went through this initial screening
phase. After overnight incubation at 37°C, this broth was streaked to MacConkey agar
containing meropenem 1 ug/ml. In 2014, a new protocol for screening coliform bacteria resistant
to extended-spectrum cephalosporins was put into place. The new method starts with the same
initial screening phase of raw sewage into MacConkey broth containing cefotaxime 4 ug/ml.
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However, after overnight incubation at 37°C, this broth was streaked to Drigalski agar which
contains ertapenem, cloxacillin, and zinc sulfate which screens for carbapenemase-producing
members of the family Enterobacteriaceae (Nordmann et al., 2012). The new method was tested
alongside the old method to evaluate similarity in ability to screen for coliform bacteria resistant
to extended-spectrum cephalosporins and there was no difference after testing 20 samples.
Lactose positive and indole positive isolates were confirmed as E. coli by PCR (Bayardelle and
Zafarullah, 2002).
Isolate Characterization. Identification of bacterial pathogens was done by using the
Sensititre® ARIS 2X automated system at the Ohio Department of Agriculture as per their
protocols. Some of the isolates also underwent further genetic analysis by PCR, looking to
identify the presence of OXA or KPC genes (Gröbner et al., 2009)(Moland et al., 2003).
Conjugation experiments were performed in order to establish the transmissibility of plasmids
harboring blaCTX-M using donor E. colis: 2993 C, UPB 38 and UPB 41 and E. coli 29522 as a
negative control (Gebreyes, Thakur, 2005). Additionally, isolates that tested positive for the
OXA gene on PCR were bidirectionally sequenced to assess DNA-binding surface amino acid
substitutions (Genewiz, South Plainfield, NJ).
Antimicrobial susceptibility testing. Antimicrobial susceptibility of isolates to meropenem
and imipenem was performed on all samples up until 2014 by Kirby Bauer susceptibility testing,
following CLSI guidelines. Minimum inhibitory concentrations (MICs) to a panel of 26
antimicrobial drugs important to human and veterinary medicine were generated for some
isolates using a semi-automated broth microdilution system (V2AGNF and ESB1F MIC plates,
24
Sensititre Sensitouch, TREK Diagnostic Systems, Cleveland, OH) following Clinical and
Laboratory Standards Institute guidelines.
Carbapenemase Detection. A Modified Hodge Test was used to test for the production of
carbapenemase as set by guidelines provided by the CDC (Jesudason et al., 2005). Metallo-β-
lactamase detection was performed using the EDTA double disk diffusion method as outlined by
Arakawa et al. in 2000. In 2014, a newer test was used to identify carbapenemase production
called the Carba NP test (Nordmann et al. in 2012).
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Results
A total of 369 untreated wastewater influent samples were collected over a three-year
time period from the Jackson Pike facility, starting in June of 2011. Samples were collected from
June and August of 2011 and 2012 and from May to July of 2014. Table 1 summarizes the rate
of recovery of isolates with reduced susceptibility to meropenem from these samples, and the
proportion with confirmed carbapenemase production. From this table, of the total 369 samples,
194 (52.6%) produced isolates on MacConkey agar plates containing meropenem, indicating
reduced susceptibility to carbapenems. 78 (21.1%) isolates tested positive for carbapenemase
production via the Modified Hodge Test. In addition, 49 (13.3%) isolates tested positive for
carbapenemase production via the Carba NP test. Confirmed carbapenemase producers were
defined as isolates testing positive on both the Modified Hodge Test and the Carba NP test,
isolates collected in 2014 that were positive on just Carba NP, or isolates that were collected
prior to 2014 that had tested positive on only the Modified Hodge Test and are no longer viable
and unavailable for confirmation using CarbaNP. Therefore, the number of confirmed
carbapenemase producers was calculated to be 88 (23.8%). The highest prevalence of confirmed
carbapenemase producers was found in August of 2012 with a rate of 21 out of 24 (87.5%)
samples producing isolates confirmed positive for carbapenemase production.
In 2011, 225 samples were collected of which 93 (41.3%) contained isolates that
expressed reduced susceptibility to meropenem. Of those, 22 (23.7%) isolates were confirmed to
be carbapenemase producers, representing 9.8% of the 225 original samples. In 2012, 108
samples were collected and 65 (60.2%) contained isolates that expressed reduced susceptibility
to meropenem. Of those, 54 (83.1%) isolates were confirmed to be carbapenemase producers,
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representing 50% of the original samples. In 2014, 36 samples were collected and all contained
isolates that expressed reduced susceptibility to meropenem. Of those, 12 (33.3%) isolates were
confirmed to be carbapenemase producers. Table 2 depicts the confirmed carbapenemase
producing coliform bacteria sorted by species. Raoultella Ornithinolytica had the highest
proportion of isolates that produced carbapenemase with a prevalence of 29 out of 88 (33.0%)
total isolates. E. coli had the second highest prevalence of carbapenemase producers with 22 of
88 (25%) total isolates confirmed.
Table 3 summarizes the results of KPC gene identification using PCR. A total of 83
isolates that showed reduced susceptibility to meropenem were lost to further work-up due to
lack of viability, and so were not available for additional testing. Out of our 88 confirmed
carbapenemase producers, only 49 isolates were available for further genotypic characterization.
Out of these 49 isolates, 43 (89.6%) were positive for the KPC gene. The majority of these KPC-
positive isolates (14 of 43 (32.6%)) were identified as Klebsiella group 47 (now known as
Raoultella Ornithinolytica).
Table 4 shows the results of Kirby Bauer disk diffusion susceptibility testing sorted by
date of recovery and species of bacteria. Of the 155 isolates tested, 51 (32.9%) were resistant to
meropenem, 22 (14.2%) showed intermediate resistance to meropenem, and 82 (52.9%) were
susceptible to meropenem. The highest number of isolates shown to be resistant to meropenem
via Kirby Bauer Susceptibility testing was found in July of 2012, which corresponds to the
highest number of confirmed carbapenemase producers recovered in a month. E. coli was found
to be the most frequently resistant to meropenem out of all of the species tested with 19 of 51
(37.3%) isolates being classified as resistant.
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Discussion
From 2011 to 2014, 88 coliform bacteria recovered from 369 wastewater samples
(23.8%) tested positive for carbapenemase production. The frequency at which these isolates
were recovered suggests that there is a common source, such as a hospital, that is responsible for
the dissemination of these resistance genes, specifically in this case, blaKPC. Out of the 49
confirmed carbapenemase producers that were tested for the KPC gene, 43 (89.6%) isolates were
positive. This is not surprising as the first report of KPC was in a K, pneumoniae isolate from
patients in a North Carolina hospital in 1996 (Yigit et al, 2001). Since then, multiple reports of
KPC indicate that this carbapenemase gene has become endemic in many healthcare settings in
the United States.
Many reports of KPC-producing organisms have been pathogens isolated from clinical
submissions in medical centers. One study, performed by The Meropenem Yearly Susceptibility
Test Information Collection (MYSTIC) Program, recovered “51 strains of Enterobacteriaceae
over a five-year period (from 1999-2005) with increased imipenem and meropenem MIC values
(≥2 µg/mL)” (Deshpande et al, 2006). Each positive KPC-producing strain was collected at a
medical facility located across the US that included the following states; New York, Arkansas,
Delaware, and Ohio. Another study recovered KPC-producing K. pneumoniae from a medical
center in Texas from 3 different patients between 2009 and 2010 (Hirsch et al, 2011). KPC-
producing Enterobacteriaceae isolates have been recovered in at least 33 states and have been
reported across the world (Kitchel et al, 2009). Reports have surfaced for KPC-producing
Enterobacteriaceae from Brazil, China, Colombia, France, Greece, India, Israel, Norway,
Scotland, and Sweden (Kitchel et al, 2009). All KPC-producing isolates were recovered in
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medical facilities, suggesting that hospitals, intensive care units (ICUs), and other patient-
orientated facilities may actually serve as a common source for blaKPC. Because blaKPC has been
previously identified and reported in the US, environmental dissemination of blaKPC likely occurs
since we were also able to recover and isolate KPC-producing organisms from the Jackson Pike
Wastewater Treatment Plant in Columbus, Ohio.
We found that the KPC gene was present in a variety of gram-negative organisms, which
is consistent with reports from the current literature. In Puerto Rico, the KPC gene was detected
in E. coli, K. pneumoniae, P. aeruginosa, and Acinetobacter baumannii found in hospitals
(Robledo et al, 2011). The KPC gene as also been detected in C. freundii isolated from patients
in Shanghai, China (Li et al, 2011). K. pneumoniae, Enterobacter cloacae, and Enterobacter
aerogenes isolated from patients in hospitals located in Pakistan and the United States have been
shown to carry the KPC gene (Pesesky et al, 2015). The KPC gene has also been identified in
Raoutella ornithinolytica isolated from patients in Ontario, Canada (Tijet et al, 2014). Klebsiella
oxytoca and Serratia marcescens isolated from medical centers in Arkansas and New York,
respectively, have also been shown to carry the KPC gene (Deshpande et al, 2006). This suggests
that the KPC gene is on a plasmid that has a broad host range which is important when we
consider how it plays a role epidemiologically.
In addition to the KPC gene being found in gram-negative organisms, we were also to
recover a gram-positive organism, Streptococcus uberis, carrying this gene. S. uberis carrying
the KPC gene has not been previously reported in the literature. This finding suggests that there
is plasmid exchange between gram-positive and gram-negative species. However, this finding is
29
not too important clinically because we don’t often treat gram-positive infections with extended-
spectrum cephalosporins.
30
Tables
Table 1. Summary of carbapenemase producing coliform bacteria recovered from untreated wastewater influent showing the total number of isolates that grew on MacConkey agar with reduced susceptibility to meropenem. Classification N MacConkey w/
*Confirmed carbapenemase producers represent isolates that tested positive on both the Modified Hodge est and the Carba NP test, isolates collected in 2014 that were positive on just Carba NP, or isolates that were collected prior to 2014 that had tested posiive on only the Modified Hodge Test and are no longer viable. Dashes indicate that isolates were not tested using the Modified Hodge Test.
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Table 2. Carbapenemase producing bacteria recovered from untreated wastewater influent listed by species and separated by Modified Hodge Test, Carba NP test, confirmed carbapenemase producers, and KPC. Species N Modified Hodge
*Confirmed carbapenemase producers represent isolates that tested positive on both the Modified Hodge Test and the Carba NP test, isolates collected in 2014 that were positive on just Carba NP, or isolates that were collected prior to 2014 that had tested positive on only the Modified Hodge Test and are no longer viable. This table only includes gram-negative bacteria. There were 23 isolates that were either gram-positive or lacked identification that were not included in this table.
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Table 3. KPC PCR test results sorted by species. Species Total Samples
Tested for KPC via PCR
Total PCR KPC Positive Isolates
Total Samples 49, (100%) 43, (89.6%)
Citrobacter freundii 6, (12.2%) 5, (11.6%)
Escherichia coli 4, (8.2%) 4, (9.3%)
Raoultella Ornithinolytica
17, (34.7%) 14, (32.6%)
Raoultella terrigena 1, (2.0%) 1, (2.3%)
Serratia plymuthica 4, (8.2%) 4, (9.3%)
Streptococcus uberis 5, (10.2%) 3, (7.0%)
*12 isolates were not species identified and are not included in this table.
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Table 4. Kirby Bauer susceptibility results using Meropenem discs sorted by date and species for coliform bacteria recovered from untreated wastewater influent. Classification N Resistant Intermediate Susceptible
Total Samples 155 51, (32.9%) 22, (14.2%) 82, (52.9%)