Laboratory analysis of tularemia in wild-trapped, commercially traded prairie dogs, Texas, 2002.Oropharyngeal oropharyngeal /oro·pha·ryn·ge·al/ (-fah-rin´je-al) 1. pertaining to the mouth and pharynx. 2. pertaining to the oropharynx. tularemia tularemia (t  lərē`mēə) or rabbit fever, acute, infectious disease caused by Francisella tularensis (Pasteurella tularensis). was identified as the cause of a die-off in
captured wild prairie dogs at a commercial exotic animal facility in
Texas. From this point source, Francisella tularensis--infected prairie
dogs were traced to animals distributed to the Czech Republic Czech Republic, Czech Česká Republika (2005 est. pop. 10,241,000), republic, 29,677 sq mi (78,864 sq km), central Europe. It is bordered by Slovakia on the east, Austria on the south, Germany on the west, and Poland on the north. and to a
Texas pet shop. F. tularensis culture isolates were recovered (or made)
from 63 prairie dogs, including one each from the secondary distribution
sites. Molecular and biochemical subtyping indicated that all isolates
were F. tularensis subsp. holarctica (Type B). Microagglutination assays
detected antibodies against F. tularensis, with titers as great as
1:4,096 in some live animals. All seropositive seropositive /se·ro·pos·i·tive/ (-poz´i-tiv) showing positive results on serological examination; showing a high level of antibody. se·ro·pos·i·tive adj. animals remained culture positive, suggesting that prairie dogs may act as chronic carriers of F. tularensis. These findings demonstrate the need for additional studies of tularemia in prairie dogs, given the seriousness of the resulting disease, the fact that prairie dogs are sold commercially as pets, and the risk for pet-to-human transmission. ********** Francisella tularensis Francisella tu·la·ren·sis n. A bacterium of the genus Francisella that causes tularemia in humans. is the causative agent of the zoonotic disease Noun 1. zoonotic disease - an animal disease that can be transmitted to humans zoonosis animal disease - a disease that typically does not affect human beings tularemia (1,2). As few as 10 organisms are sufficient to cause severe disease and death, making F. tularensis one of the most infectious bacterial pathogens known. Thus, F. tularensis is considered to be a biological threat agent that poses a substantial risk to public health (3). Infections with F. tularensis are widely distributed Adj. 1. widely distributed - growing or occurring in many parts of the world; "a cosmopolitan herb"; "cosmopolitan in distribution" cosmopolitan bionomics, environmental science, ecology - the branch of biology concerned with the relations between organisms and occur in >100 wildlife species in the Northern Hemisphere (4,5). Two subspecies subspecies, also called race, a genetically distinct geographical subunit of a species. See also classification. of F. tularensis are most commonly associated with human and animal disease: tularensis (Type A) and holarctica (Type B) (6,7). Type A is found almost exclusively in North America North America, third largest continent (1990 est. pop. 365,000,000), c.9,400,000 sq mi (24,346,000 sq km), the northern of the two continents of the Western Hemisphere. and is associated with a severe form of disease in humans and rabbits (Lepus spp.). It is commonly differentiated from Type B by its ability to produce acid from glycerol glycerol, glycerin, glycerine, or 1,2,3-propanetriol (prō`pāntrī'ŏl), CH2OHCHOHCH2OH, colorless, odorless, sweet-tasting, syrupy liquid. . Type B is found throughout the Northern Hemisphere (holarctic region); it does not produce acid from glycerol and rarely causes death in humans. Type B is most frequently isolated from rodent species, including muskrats (Ondatra zibethicus), mice (Mus musculus), beaver (Castor canadensis Castor canadensis (syn. C. fiber) see beaver. ), voles (Microtus spp.), and water voles (Arvicola terrestris). Infections with F. tularensis also occur in the black-footed prairie dog (Cynomys ludovicianus Cynomys ludovicianus see prairie dog. ) (8). This finding has particular public health significance since wild-caught prairie dogs are sold as pets both domestically and internationally. Wild prairie dogs are found throughout the Great Plains of North America from southern Canada to just inside Mexico. Every year, pups are collected in the United States during April through July and are distributed to pet stores throughout the country as well as being exported internationally. The first literature report of tularemia in captive prairie dogs described F. tularensis infection in three wild-caught animals in 1986 (8). Subsequently, F. tularensis infection caused by Type B was confirmed by the Centers for Disease Control and Prevention Centers for Disease Control and Prevention (CDC), agency of the U.S. Public Health Service since 1973, with headquarters in Atlanta; it was established in 1946 as the Communicable Disease Center. (CDC See Control Data, century date change and Back Orifice. CDC - Control Data Corporation ), Fort Collins, Colorado The City of Fort Collins, a home rule municipality situated on the Cache la Poudre River along the Colorado Front Range, is the county seat and most populous city in Larimer County, Colorado. , in wild-caught prairie dogs, originating from a single animal exporter and shipped to research institutions in Boston and Houston from 1996 to 1997. In the summer of 2000, CDC again confirmed Type B infection in a wild-caught prairie dog. In this case, a family traveling from Ohio purchased two prairie dogs from a dealer in Kansas; one animal died during transport, while the second animal displayed disease and died after they arrived home. In August of 2002, an outbreak of tularemia was identified as the cause of a die-off among wild-caught, commercially traded prairie dogs at an exotic animal facility in Texas. We describe laboratory findings from this investigation. The epidemiologic findings of the investigation are reported separately (9). During this outbreak, many animals died of infection with F. tularensis. However, a small number of surviving animals developed antibodies against F. tularensis, suggesting that prairie dogs can survive an infection of tularemia. All seropositive animals were also found to harbor live infectious bacteria, suggesting that prairie dogs may be persistently infected. These findings have important public health implications in light of commercial prairie dog trade practices. Materials and Methods Outbreak Groupings On August 2, 2002, a total of 163 prairie dogs were found at the exotic animal facility in Texas. These animals were classified into four groups: group A (bin 1, dead), group B (bin 1, live), group C (escapees), and group D (bin 2 and cages, healthy). Group A animals (n = 46) were collected during the last week of July through August 2, 2002. All group A animals had been housed in an uncovered metal tub (bin 1). The live animals remaining in bin 1 were classified as group B (n = 23), with most of the animals being emaciated e·ma·ci·ate tr. & intr.v. e·ma·ci·at·ed, e·ma·ci·at·ing, e·ma·ci·ates To make or become extremely thin, especially as a result of starvation. , dehydrated de·hy·drate v. de·hy·drat·ed, de·hy·drat·ing, de·hy·drates v.tr. 1. To remove water from; make anhydrous. 2. To preserve by removing water from (vegetables, for example). , and lethargic. Group C (n = 36) comprised escaped prairie dogs that were running free throughout the facility. Group D prairie dogs (n = 58) were physically separated from both group B and C animals, and all group D animals were large, well-nourished, energetic, and noisy. Group D animals were housed in an uncovered metal tub (bin 2) and in several wire cages. Animals from the Texas facility that had been sent to other locations made up two additional groups. Group E animals comprised seven prairie dogs that originated from the Texas facility, were distributed to pet shops in Texas, and recalled once F. tularensis was identified as the cause of the outbreak. Group F comprised 100 prairie dogs shipped from the Texas facility to the Czech Republic. Culture Recovery of F. tularensis All prairie dogs at the Texas facility (n = 163) were necropsied on site, and tissues were surgically removed. Appropriate biosafety measures were adhered to, including the use of closed front gowns, N95 masks, glasses, and gloves. Spleen and liver samples were spread onto cysteine cysteine (sĭs`tēn), organic compound, one of the 20 amino acids commonly found in animal proteins. Only the l-stereoisomer participates in the biosynthesis of mammalian protein. heart agar supplemented with 9% sheep blood (CHAB). Plates were sealed with parafilm and transported in ice coolers (~15[degrees]C-20[degrees]C) until arrival at the CDC laboratory, Fort Collins, Colorado (~72 hours). Culture plates were then transferred to a biosafety level biosafety level Epidemiology A classification for the degree of caution required when working with specific groups of pathogens. See Maximum containment facility. (BSL (language) BSL - A variant of IBM's PL/S systems language. Versions: BSL1, BSL2. ) 3 incubator at 37[degrees]C for 5 days and checked daily for F. tularensis growth. Some tissues were also spread onto CHAB medium containing antibiotics (10), incubated at 37[degrees]C for 7 days, and checked daily for F. tularensis growth. A culture isolate from prairie dogs shipped to the Czech Republic was grown at the State Veterinary Administration, Prague, Czech Republic, and submitted to our laboratory. Spleen and liver tissues were injected into pathogen-free Swiss-Webster outbred out·breed tr.v. out·bred , out·breed·ing, out·breeds To subject to outbreeding. Adj. 1. outbred - bred of parents not closely related; having parents of different classes or tribes mice for culture recovery of F. tularensis (IACUC IACUC Institutional Animal Care and Use Committee Protocol 00-06-018-MUS). Tissues (~1g) from individual prairie dogs were ground with mortar and pestle A mortar and pestle is a tool used to crush, grind, and mix substances. The pestle is a heavy stick whose end is used for pounding and grinding, and the mortar is a bowl. The substance is ground between the pestle and the mortar. , resuspended in 2 mL of saline and 0.5 mL of the tissue suspension was injected subcutaneously per mouse. All injections were performed in a BSL2 animal facility, and appropriate biosafety measures were followed, including the use of closed front gowns, N95 masks, glasses, and gloves. Animals were euthanized when signs and symptoms of tularemia were evident. After euthanasia was performed, 0.5 to 1.0 mL of whole blood was removed by cardiac puncture with a 1.0 mL tuberculin tuberculin /tu·ber·cu·lin/ (-lin) a sterile solution containing the growth products of, or specific substances extracted from, the tubercle bacillus; used in various forms in the diagnosis of tuberculosis; see also under test. syringe. Liver and spleen tissues were surgically removed and spread onto CHAB with sterile wooden sticks. All healthy injected mice were euthanized 21 days after injection, and serum was tested for anti-F. tularensis antibody. Direct Fluorescent Assay (DFA DFA - Deterministic Finite-state Automaton. See Finite State Machine. ) Slide touch preparations of tissues were prepared and heat-fixed immediately after necropsy necropsy /nec·rop·sy/ (nek´rop-se) examination of a body after death; autopsy. nec·rop·sy n. See autopsy. necropsy examination of a body after death. See also autopsy. at the Texas animal facility. On arrival at the laboratory, all slides were incubated with FITC-labeled rabbit anti-F. tularensis subsp. tularensis (SchuS4 strain) antibodies (CDC) for 30 min at room temperature. Slides were washed twice in phosphate-buffered saline, followed by a final rinse with d[H.sub.2]O and viewed with a fluorescent microscope fluorescent microscope n. A microscope fitted with a source of ultraviolet radiation to aid in the detection and examination of fluorescent specimens. using the 40X objective and a 490 nm filter. Direct fluorescent activity was scored independently by two technicians experienced with F. tularensis DFA. Serologic se·rol·o·gy n. pl. se·rol·o·gies 1. The science that deals with the properties and reactions of serums, especially blood serum. 2. Findings For all group B, C, and D animals, blood samples were collected from euthanized animals by cardiac puncture. Blood was collected into Microtainer brand serum separator tubes (Beeton Dickinson, Franklin Lakes, NJ) and maintained at 4[degrees]C until arrival at the laboratory (~72 h). Serum was separated, heat-inactivated for 30 min at 56[degrees]C, and tested for F. tularensis specific antibodies by using a standard microagglutination assay (11). Briefly, serial dilutions of serum were incubated overnight with safranin-stained, formalin-killed F. tularensis subsp. tularensis (SchuS4 strain) cells at room temperature, and a titer titer /ti·ter/ (ti´ter) the quantity of a substance required to react with or to correspond to a given amount of another substance. was assigned reflecting the last well demonstrating full agglutination agglutination, in biochemistry agglutination, in biochemistry: see immunity. agglutination, in linguistics agglutination, in linguistics: see inflection. . Samples with a titer of 1:128 or greater were reported as positive. Confirming F. tularensis Prairie dogs were confirmed positive on recovery of an isolate with characteristic growth on CHAB and positive testing of the isolate by DFA or ISFtu2 polymerase chain reaction polymerase chain reaction (pŏl`ĭmərās') (PCR), laboratory process in which a particular DNA segment from a mixture of DNA chains is rapidly replicated, producing a large, readily analyzed sample of a piece of DNA; the process is (PCR PCR polymerase chain reaction. PCR abbr. polymerase chain reaction Polymerase chain reaction (PCR) ). Animals were considered presumptive pre·sump·tive adj. 1. Providing a reasonable basis for belief or acceptance. 2. Founded on probability or presumption. pre·sump positive if tissues tested positive by DFA or PCR, but no isolate was obtained. Prairie dogs were considered negative if all three diagnostic tests (culture, DFA, serologic testing) failed to detect any evidence of F. tularensis infection. For negative samples, recovery of culture included passage of the spleen and liver tissues through mice. F. tularensis Subtyping For molecular subtyping, DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. was prepared alter injection of a 1 [micro]L loop of culture into 200 [micro]L TE buffer. Cells were lysed by boiling at 95[degrees]C for 10 min. A differential PCR, based on the presence or absence of the ISFtu2 element (GenBank accession no. AY062040), was performed by using 1 [micro]L of the lysed bacterial supernatant supernatant /su·per·na·tant/ (-na´tant) the liquid lying above a layer of precipitated insoluble material. supernatant the liquid lying above a layer of precipitated insoluble material. and the primers TuF1705 (5'-GATAGATACACGCCTTGCTCACA-3') and TuBR431(5'-ACCCAGCCAATGCCTAAATA-3') (Y. Zhou, unpub, data). The amplification program included a denaturation denaturation, term used to describe the loss of native, higher-order structure of protein molecules in solution. Most globular proteins exhibit complicated three-dimensional folding described as secondary, tertiary, and quarternary structures. cycle at 95[degrees]C for 2 min, followed by 35 amplification cycles of 95[degrees]C for 30 s, 55[degrees]C for 30 s, and 72[degrees]C for 1 min, and a final elongation cycle of 72[degrees]C for 5 min. PCR products were analyzed by agarose gel electrophoresis Agarose gel electrophoresis is a method used in biochemistry and molecular biology to separate DNA, RNA, or protein molecules by size. This is achieved by moving negatively charged nucleic acid molecules through an agarose matrix with an electric field (electrophoresis). , followed by staining with EtBr and visualization with a Bio-Rad Gel Doc UV system (Bio-Rad Laboratories, Hercules, CA). For biochemical subtyping, the 96-well automated MicroLog MicroStation System with GN2 Microplates (Biolog Inc, Hayward, CA) was used. Microplates were set up and analyzed per the manufacturer's instructions. Statistical Analysis McNemar's test was used for statistical analysis. Sensitivities of different diagnostic tests were evaluated for their ability to detect F. tularensis in a given population of animals (either live or dead animals). Results Laboratory Findings F. tularensis-infected prairie dogs from the Texas animal facility were traced to Texas pet shops and animals shipped to the Czech Republic. From these three sources, 177 prairie dogs (1 animal whose illness initiated the investigation [12], 163 animals that remained on site at the Texas facility, 7 animals recalled from Texas pet shops, and 6 animals shipped to the Czech Republic) were tested. Of these animals, 63 were confirmed positive, 13 were identified as presumptive positives, and 101 were confirmed negative for F. tularensis infection (Table 1). F. tularensis Isolates from Infected Prairie Dogs Because prairie dogs were sold commercially as pets and the risk for pet-to-human transmission was unknown, determining which groups (A-D A-D Advance-Decline, or measurement of the number of issues trading above their previous closing prices less the number trading below their previous closing prices over a particular period. ) of animals were potentially infectious was important. Subtyping the F. tularensis isolates was also important, since this outbreak carried the threat of international dissemination. Therefore, our laboratory efforts focused on recovery of viable organisms. In total, 63 isolates were recovered (Table 1): 61 from prairie dogs at the Texas facility (groups A-C A-C Air Conditioning ), 1 isolate from prairie dogs recalled from Texas pet shops (group E), and 1 isolate from prairie dogs distributed to the Czech Republic (group F). Biochemical and Molecular Typing of F. tularensis Isolates For subtyping of the 63 F. tularensis isolates (63 isolates described here, including 1 isolate that initiated the investigation, TX021935 [12]), a combination of biochemical and molecular typing was used. Biochemical characterization was performed on 15 isolates representative of all five groups of F. tularensis-positive animals (groups A, B, C, E, F). All 15 F. tularensis isolates were unable to use glycerol as a carbon source and thus were classified as Type B (data not shown). In addition, six representative isolates were tested for antimicrobial susceptibilities and demonstrated MICs consistent with those published previously for Type B (data not shown, 13). To distinguish molecularly between Type A and Type B, a differential PCR based on the presence or the absence of the ISFtu2 element was performed (Y. Zhou, unpub. data). For Type A, a PCR product of 390 bp was amplified, whereas for Type B, a product of 1,249 bp was amplified. When ISFtu2 PCR subtyping was performed on all 63 isolates, all were shown to be Type B, including the single isolate received from the Czech Republic. Representative ISFtu2 PCR subtyping for the five groups (A, B, C, E, and F) of F. tularensis-positive animals is shown in Figure 1. Additional analysis with ISFtu2 restriction fragment length polymorphisms restriction fragment length polymorphism n. Abbr. RFLP Intraspecies variations in the length of DNA fragments generated by the action of restriction enzymes and caused by mutations that alter the sites at which these enzymes act, changing southern blotting demonstrated that the F. tularensis isolates were molecularly indistinguishable (data not shown). [FIGURE 1 OMITTED] Texas Facility Investigation (Groups A-D) The animals remaining at the Texas facility (groups A-D) provided insight into how tularemia was transmitted among the prairie dogs. When necropsies were performed on animals in groups A-D, cannibalization can·ni·bal·ize v. can·ni·bal·ized, can·ni·bal·iz·ing, can·ni·bal·iz·es v.tr. 1. To remove serviceable parts from (damaged airplanes, for example) for use in the repair of other equipment of the same , as indicated by partially eaten prairie dog carcasses, was noted among group A animals. In addition, all group A and most of group B animals displayed swollen submandibular lymph nodes The submandibular lymph nodes (submaxillary glands in older texts), three to six in number, are placed beneath the body of the mandible in the submaxillary triangle, and rest on the superficial surface of the submaxillary salivary gland. , suggesting that all animals ingested in·gest tr.v. in·gest·ed, in·gest·ing, in·gests 1. To take into the body by the mouth for digestion or absorption. See Synonyms at eat. 2. the bacteria. Because all prairie dogs from the Texas facility (groups A-D) were tested and classified as confirmed positive, presumptive positive, or negative (Table 1), diagnostic test sensitivities could be determined. From the 68 prairie dogs at the Texas facility that tested positive for F. tularensis by one or more diagnostic methods (culture, DFA, serologic testing), 61 isolates were recovered, yielding an overall culture recovery rate of 89.7%. Detecting F. tularensis in Live, Infected Animals For determining F. tularensis infection in live, infected animals, the sensitivities of culture versus DFA and serologic testing were compared (Table 2). Testing all 59 animals in groups B and C, confirmed 21 animals as F. tularensis-positive and 38 animals as F. tularensis-negative (Table 1). For the 20 animals confirmed positive by analysis of spleen and liver tissues, culture detected F. tularensis in 100% of cases. In contrast, both DFA and serologic testing detected F. tularensis in 10 of 20 animals, yielding a sensitivity of only 50% (Table 2). These differences were significant (p [less than or equal to] 0.05) and demonstrate that culture of spleen and liver tissues is more sensitive than DFA or serologic testing for detecting F. tularensis in live, infected prairie dogs. Since the outbreak was consistent with oropharyngeal tularemia, submandibular lymph nodes of group B animals were also analyzed. When lymph nodes Lymph nodes Small, bean-shaped masses of tissue scattered along the lymphatic system that act as filters and immune monitors, removing fluids, bacteria, or cancer cells that travel through the lymph system. were cultured, an additional case was confirmed by isolation of F. tularensis from animal B17 (Table 3). The bacterium was not cultured from the spleen and liver of this prairie dog even on passage of tissues through Swiss-Webster mice. This finding suggested that prairie dog B17 had recently ingested F. tularensis and that the infection was localized to the sub-mandibular lymph nodes. To determine if lymph node lymph node Small, rounded mass of lymphoid tissue contained in connective tissue. They occur all along lymphatic vessels, with clusters in certain areas (e.g., neck, groin, armpits). tissues were a better tissue source than either spleen or liver tissues for detection of F. tularensis, DFA was used for direct comparison of tissues from culture-positive group B animals (Table 3). When spleen and liver tissues were analyzed, the sensitivity of DFA was 50%, whereas for analysis of submandibular submandibular /sub·man·dib·u·lar/ (sub?man-dib´u-ler) below the mandible. submandibular (sub´mandib´y lymph node tissues the sensitivity of DFA was 89.5% (Table 2). This difference in sensitivities was significant (p [less than or equal to] 0.05) and demonstrates that for cases of oropharyngeal tularemia, submandibular lymph node tissues are the most appropriate source for detecting infection by DFA. Detecting F. tularensis in Fatal Cases of Tularemia For fatal cases of tularemia, the sensitivity of culture and DFA was also compared (Table 2). Of the 47 animals in group A, 40 were confirmed positive, and 7 were presumptive positive for F. tularensis (Table 1). Direct fluorescence analysis of spleen and liver tissues identified all 47 animals as F. tularensis positive, yielding a sensitivity of 100%. In contrast, 40 F. tularensis isolates were obtained, yielding a sensitivity of 85.1%. These results were significant and demonstrated that DFA was more sensitive than culture for detection of F. tularensis in carcasses (p [less than or equal to] 0.05). Seropositivity Seropositivity is the presence of a certain antibody in a blood sample. A patient with seropositivity for a particular antigen or agent is termed seropositive. and Decreased F. tularensis Levels in Live, Infected Animals To test for evidence of seroconversion seroconversion /se·ro·con·ver·sion/ (-con-ver´zhun) the change of a seronegative test from negative to positive, indicating the development of antibodies in response to immunization or infection. in live, infected animals, serum samples from group B prairie dogs were checked for anti-F. tularensis antibodies. Ten animals showed evidence of seroconversion, displaying titers against F. tularensis as great as 1:4,096 (Table 3). To our knowledge, this evidence is the first that prairie dogs can develop specific antibodies on infection with F. tularensis. In addition, F. tularensis was successfully recovered from the spleen of all 10 seropositive animals, suggesting that prairie dogs may become persistently infected. Comparison of DFA results for seropositive and seronegative seronegative /se·ro·neg·a·tive/ (-neg´ah-tiv) showing negative results on serological examination; showing a lack of antibody. se·ro·neg·a·tive adj. prairie dogs indicated that the levels of F. tularensis in liver and spleen were greatly decreased in seropositive prairie dogs. In 7 of 10 seropositive prairie dogs, F. tularensis was not detectable by DFA analysis of spleen and liver tissues (Table 3, Figure 2, panel b). Conversely, 7 of 10 seronegative animals were positive by DFA analysis of spleen and liver tissues (Table 3, Figure 2, panel a). These findings demonstrate that seropositivity in prairie dogs leads to decreased levels of F. tularensis and may suggest that seropositive prairie dogs can survive an acute infection of oropharyngeal tularemia. [FIGURE 2 OMITTED] Discussion In our study, we documented the laboratory results from an outbreak of oropharyngeal tularemia among wild-caught, commercially distributed prairie dogs. F. tularensis-infected prairie dogs from the Texas animal facility were traced to Texas pet shops and to the Czech Republic. Our findings indicate that the primary mechanism of transmission was ingestion ingestion /in·ges·tion/ (-chun) the taking of food, drugs, etc., into the body by mouth. in·ges·tion n. 1. The act of taking food and drink into the body by the mouth. 2. of F. tularensis, as all infected prairie dogs displayed enlarged submandibular lymph nodes, a hallmark of oropharyngeal tularemia. In addition, all prairie dogs (group D) physically separated from sick animals were negative for F. tularensis infection, demonstrating that the outbreak of tularemia at the Texas facility required contact with infected animals. While other modes of bacterial ingestion cannot be ruled out, this outbreak most likely resulted from cannibalism cannibalism (kăn`ĭbəlĭzəm) [Span. caníbal, referring to the Carib], eating of human flesh by other humans. of dead animals. Cannibalism, as evidenced by partially eaten carcasses, was observed at the Texas facility as well as in the shipment of animals to the Czech Republic. In nature, cannibalism occurs in rodents and has been previously documented as the cause for spread of tularemia (14,15). Studies of the black-tailed prairie dog The Black-tailed Prairie Dog (Cynomys ludovicianus), is a rodent of the family sciuridae found in the Great Plains of North America from about the USA-Canada border to the USA-Mexico border. Unlike some other prairie dogs, these animals do not truly hibernate. in nature have also documented cannibalism (16). At the Texas exotic animal facility, group A and B animals were placed together in a single metal bin, which allowed unnaturally close contact and conditions. Also, the use of wood chip bedding increased the likelihood that buried carcasses would not be seen, probably contributing to delayed removal of deceased animals, thereby increasing the opportunity for cannibalism. Since, F. tularensis in pet prairie dogs presented an unaddressed public health threat for their owners, we focused our efforts on the recovery of live organisms. We were able to culture infectious bacteria from both dead and live, infected animals. Moreover, our study is the first to provide evidence that prairie dogs can develop antibodies against F. tularensis. The seropositive prairie dogs might have survived long-term, since these animals had decreased levels of infecting bacteria and were blood-culture negative (unpub. data). These findings raise the possibility that persistent infection occurs in prairie dogs and suggests a potential role of prairie dogs as reservoirs of F. tularensis in nature. Our findings with prairie dogs are very similar to previous reports documenting chronic infection in seropositive voles infected orally with F. tularensis (17,18). In one of those studies, seropositive voles were shown to harbor live F. tularensis for as long as 313 days. Although culture is considered the standard criterion for identification, F. tularensis is a fastidious fas·tid·i·ous adj. 1. Possessing or displaying careful, meticulous attention to detail. 2. Difficult to please; exacting. 3. Having complex nutritional requirements. Used of microorganisms. organism making culture recovery a challenge, especially when analyzing animal carcasses. Tissues from dead animals are often overgrown overgrown said of a part that has not been kept trimmed. overgrown hoof overgrown hooves put unusual stresses on bones and tendons and allow for distortion of the wall and sole. with normal flora Normal flora The mixture of bacteria normally found at specific body sites. Mentioned in: Sputum Culture, Wound Culture and other environmental contaminants. Past studies with carcasses have had limited success, and the culture recovery rates were approximately 30% (19). We achieved a culture recovery rate of 89.7% from F. tularensis-infected animals (both live and dead animals), demonstrating the sensitivity and usefulness of culture. In light of our findings, we suggest that culture on CHAB media containing antibiotics be attempted more routinely for diagnosis of F. tularensis infection in animal and field specimens such as water, mud, and grass or hay. Additionally, when culture was used for detection of F. tularensis in animals that did not die of the disease, we found it more sensitive than either DFA (50%) or serologic testing (50%) and capable of detecting F. tularensis in all cases (100%). This high culture recovery rate is probably due to the freshness and relatively uncontaminated state of the specimens used for culture. The comparatively low detection levels of DFA and serologic testing were likely influenced by the fact that these animals were at varying stages of infection (acute phase and convalescent con·va·les·cent adj. Relating to convalescence. n. A person who is recovering from an illness, an injury, or a surgical operation. convalescent 1. pertaining to or characterized by convalescence. 2. phase), making diagnosis by either DFA or serologic testing less than optimal. This suggests that for surveillance studies of F. tularensis infection in wild rodent populations, culture of fresh tissues is the preferred diagnostic method. In contrast, in detecting F. tularensis in animals that died of the disease, DFA was more sensitive than culture (85.1%) and capable of detecting F. tularensis in all animals. For fatal cases of tularemia in prairie dogs, the levels of F. tularensis were extremely high in both spleen and liver, simplifying identification by DFA. Culture recovery of F. tularensis was probably more difficult because of deterioration of the samples and loss of bacterial viability over time. Indeed, F. tularensis in the tissues of the seven presumptive-positive animals was noncultivatable and noninfectious as shown by passage of the tissues through Swiss-Webster mice. Presumably pre·sum·a·ble adj. That can be presumed or taken for granted; reasonable as a supposition: presumable causes of the disaster. , one or more F. tularensis infected prairie dogs were among the thousands trapped and shipped to the Texas exotic animal facility. On arrival at the facility, the infected prairie dogs died. The bacterium was then transmitted throughout hundreds of prairie dogs at the facility most likely as the result of cannibalism. Several cases (Introduction and 7) of tularemia in prairie dogs have now been documented, suggesting that a proportion of wild prairie dogs harbor live F. tularensis. Environmental stresses, such as capture, transit, and crowding, may induce productive infection that manifests as severe disease and death. Given the seriousness of the resulting disease and the public health risk for pet-to-human transmission, long-term studies are needed to determine the length of time seropositive prairie dogs can harbor live F. tularensis and whether they are reservoirs of tularemia in nature.
Table 1. Laboratory results for outbreak of tularemia in wild-trapped,
commercially sold prairie dogs
Presumptive- Confirmed-
No. of positive positive
Group Prairie dogs animals samples (a) samples (b)
A Exotic animal 47 (d) 7 40
facility, Texas,
bin 1, dead
animals
B Exotic animal 23 0 1
facility, Texas,
bin 1, live
animals
C Exotic animal 36 0 1
facility, Texas,
escapees
D Exotic animal 58 0 1
facility, Texas
bin 2 and cages,
healthy
E Pet shop recalls, 7 1 1
originating from
exotic animal
facility, Texas
F Czech Republic, 100 5 1
originating from
exotic animal
facility, Texas
Confirmed-
Group Prairie dogs negative samples (c)
A Exotic animal 0
facility, Texas,
bin 1, dead
animals
B Exotic animal 3
facility, Texas,
bin 1, live
animals
C Exotic animal 35
facility, Texas,
escapees
D Exotic animal 58
facility, Texas
bin 2 and cages,
healthy
E Pet shop recalls, 5
originating from
exotic animal
facility, Texas
F Czech Republic, Not determined
originating from
exotic animal
facility, Texas
(a) Prairie dogs were confirmed positive on recovery of an isolate with
characteristic growth on cysteinc heart agar with 9% sheep blond and
positive testing of the isolate by direct fluorescent assay (DFA) or
ISFtu2 polymerase chain reaction (PCR).
(b) Prairie dogs were considered presumptive positive if primarily
tissues tested positive by DFA or PCR but no isolate was obtained.
(c) Prairie dogs were confirmed negative if all three diagnostic tests
(culture, DFA. serologic testing) failed to detect any evidence of
Francisella tularensis infection.
(d) 46 animals that remained on site August 2, 2002, plus 1 animal that
initiated the outbreak investigation (TX021935).
Table 2. Comparison of diagnostic sensitivities of culture and direct
fluorescent assay (DFA) for detection of Francisella tularensis in
live versus dead prairie dogs (groups A-C)
No. (%) of samples positive for:
Direct Direct
Culture fluorescence fluorescence
Prairie dogs (a) (spleen/liver) (spleen/liver) (lymph node)
Groups B, C; live, 20 (100) 10 17 (89.5) (b)
infected animals
(n=20)
Group A, dead 40 (85.1) 47 Not tested
animals (n=47)
No. (%) of samples
positive for:
Prairie dogs (a) Serologic testing
Groups B, C; live, 10 (50)
infected animals
(n=20)
Group A, dead Not tested
animals (n=47)
(a) All 67 prairie dogs tested positive for F. tularensis by at least
one diagnostic test (culture, DFA, or serologic testing).
(b) 19 F.tularensis-positive animals were tested.
Table 3. Diagnostic test results for culture-positive group B prairie
dogs (a)
DFA (microag
DFA (submandibular Serologic glutination
Prairie dog (spleen/liver) lymph node) testing assay)
B1 + + 1:512 Pos
B2 + + 1:32 Neg
B3 + + 1:8 Neg
B4 - + 1:1,024 Pos
B5 - + 1:4,096 Pos
B6 + + 1:512 Pos
B7 - + 1:5 12 Pos
B8 + No sample 1:8 Neg
B10 + + 1:4 Neg
B11 - + 1:256 Pos
B12 - - 1:1,024 Pos
B13 - - 0 Neg
B14 - + 1:128 Pos
B15 + + 1:64 Neg
B16 + + 1:16 Neg
B17 - + 0 Neg
B18 + + 1:512 Pos
B19 + + 1:4 Neg
B20 - + 1:128 Pos
B21 - + 1:16 Neg
(a) DFA, direct fluorescent assay: Neg, negative; Pos, positive.
Acknowledgments We thank Jessica Versage and Scott Bearden for technical assistance and Joe Piesman for critical comments on the manuscript. References (1.) Ellis J, Oyston CF, Green M, Titball RW. Tularemia. Clin Micro Rev 2002;15:631-46. (2.) Centers for Disease Control and Prevention. Tularemia--United States, 1990-2000. MMWR MMWR Morbidity & Mortality Weekly Report Epidemiology A news bulletin published by the CDC, which provides epidemiologic data–eg, statistics on the incidence of AIDS, rabies, rubella, STDs and other communicable diseases, causes of mortality–eg, Morb Mortal Wkly Rep 2002;51:182-4. (3.) Dennis DT, Inglesby TV, Henderson DA, Barlett JG, Ascher MS, Eitzen E, et al. Tularemia as a biological weapon. JAMA JAMA abbr. Journal of the American Medical Association 2001;285:2763-73. (4.) Hopla CE, Hopla AK. Tularemia. In: Beran GW, Steele JH, editors. 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New York New York, state, United States New York, Middle Atlantic state of the United States. It is bordered by Vermont, Massachusetts, Connecticut, and the Atlantic Ocean (E), New Jersey and Pennsylvania (S), Lakes Erie and Ontario and the Canadian province of : Springer-Verlag. 2004; in press. (8.) La Regina M, Lonigro J, Wallace M. Francisella tularensis infection in captive, wild-caught prairie dogs. Lab Anim Sci 1986;36:178-80. (9.) Avashia SB, Petersen JM, Lindley CM, Schriefer ME, Gage KL, Cetron M, et al. First reported prairie dog-to-human tularemia transmission, Texas, 2002. Emerg Infect Dis 2004;10:483-6. (10.) Johansson A, Berglund L, Eriksson U, Goransson I, Wollin R, Forsman M, et al. Comparative analysis of PCR versos culture for diagnosis of ulceroglandular tularemia. J Clin Microbiol 2000;38:22-6. (11.) Brown SL, McKinney FT, Klein GC, Jones WL. Evaluation of a safranin-O-stained antigen microagglutination test microagglutination test see microscopic agglutination test. for Francisella tularensis antibodies. J Clin Microbiol 1980;11:146-8. (12.) Centers for Disease Control and Prevention. Outbreak of tularemia among commercially distributed prairie dogs, 2002. MMWR Morb Mortal Wkly Rep 2002;51:688,699. (13.) Johansson A, Urich SK, Chu MC, Sjostedt A, Tarnvik A. In vitro in vitro /in vi·tro/ (in ve´tro) [L.] within a glass; observable in a test tube; in an artificial environment. in vi·tro adj. In an artificial environment outside a living organism. susceptibility to quinolones of Francisella tularensis subspecies tularensis. Scand J Infect Dis 2002;34:327-30. (14.) Jellison WL, Bell JF, Owen CR. Mouse disease studies. In: Beck JR, editor. The Oregon meadow mouse irruption ir·rup·tion n. The act or process of breaking through to a surface. of 1957-1958. Corvallis (OR): Federal Cooperative Extension Service/Oregon State College; 1958. p. 71-80. (15.) Vest ED, Marchette NJ. Transmission of Pasteurella tularensis Pasteurella tu·la·ren·sis n. Francisella tularensis. among desert rodents through infective carcasses. Science 1958;128:363-4. (16.) Hoogland, JL. The black-tailed prairie dog: social life of a burrowing animal. Chicago: University of Chicago Press The University of Chicago Press is the largest university press in the United States. It is operated by the University of Chicago and publishes a wide variety of academic titles, including The Chicago Manual of Style, dozens of academic journals, including ; 1995. (17.) Bell JF, Stewart SJ. Chronic shedding tularemia nephritis nephritis (nəfrī`təs), inflammation of the kidney. The earliest finding is within the renal capillaries (glomeruli); interstitial edema is typically followed by interstitial infiltration of lymphocytes, plasma cells, eosinophils, and a in rodents: possible relation to occurrence of Francisella tularensis in lotic lo·tic adj. Of, relating to, or living in moving water. [From Latin l waters. J Wildl Dis 1975;11:421-30. (18.) Olsufjev NG, Shlygina KN, and Ananova EV. Persistence of Francisella tularensis McCoy et Chapin tularemia agent in the organism of highly sensitive rodents after oral infection. J Hyg Epidemiol MicrobioI Immunol 1984;28:441-54. (19.) Morner T, Sandstrom G, Mattsson R, Nilsson PO. Infections with Francisella tularensis biovar palaearctica in hares (Lepus timidus, Lepus europaeus) from Sweden. J Wildl Dis 1988;24:10-4. Jeannine M. Petersen, * Martin E. Schriefer, * Leon G. Carter, * Yan Zhou, * Tara Sealy, * Darcy Bawiec, * Brook Yockey, * Sandra Urich, * Nordin S. Zeidner, * Swati Avashia, ([dagger]) Jacob L. Kool, * Jan Buck, ([double dagger]) Connie Lindley, ([double dagger]) Leos Celeda, ([section]) John A. Monteneiri, * Kenneth L. Gage, * and May C. Chu * * Centers for Disease Control and Prevention, Fort Collins, Colorado, USA; ([dagger]) Centers for Disease Control and Prevention, Atlanta, Georgia, USA; ([double dagger]) Texas Department of Health, Arlington, Texas, USA; and ([section]) State Veterinary Administration, Prague, Czech Republic Dr. Petersen is a research microbiologist with the Bacterial Zoonoses Branch, Division of Vector-Borne Infectious Diseases, Centers for Disease Control and Prevention, Fort Collins, Colorado. Her research interests focus on improving diagnosis of tularemia to gain a better understanding of the ecology and epidemiology of the disease in North America. Address for correspondence: Jeannine M. Petersen, Diagnostic and Reference Section, Bacterial Zoonoses Branch, Centers for Disease Control and Prevention, P.O. Box 2087, Rampart Road, Foothills Campus, Fort Collins, Colorado 80522, USA; fax: 970-221-6476; email: nzp0@cdc.gov |
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