Pneumonia from Angiostrongylus vasorum infection in a red panda (Ailurus fulgens fulgens)

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Pneumonia from Angiostrongylus vasorum infection in a red panda (Ailurus fulgens fulgens)

Janet C. Patterson-Kane¹, Lynda M. Gibbons, Ryan Jefferies, Eric R. Morgan, Nanny Wenzlow and Sharon P. Redrobe

Correspondence: ¹Corresponding Author: Janet C. Patterson-Kane, School of Veterinary Science, The University of Queensland, St. Lucia, Queensland 4072, Australia, e-mail: j.pattersonkane{at}uq.edu.au

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A 9-year-old, male, captive red panda (Ailurus fulgens fulgens)in an urban zoo in the United Kingdom presented with respiratorydistress and weight loss. The animal was euthanatized, and apostmortem examination was performed. The lungs were diffuselyconsolidated with extensive mineralization. Microscopically,there was extensive obliteration of normal pulmonary architectureby sheets and coalescing nodules of partially mineralized fibroustissue and granulomatous inflammation centered on large numbersof nematode larvae and eggs. First stage nematode larvae wereisolated from lung tissue and were characterized as Angiostrongylusvasorum on the basis of their morphology and sequencing of the18S ribosomal RNA gene and the entire second internal transcribedspacer. Although A. vasorum has previously been reported inred pandas in a zoological collection in Denmark, this studyis the first reported case in the United Kingdom and occursagainst a background of geographical spread and increased incidenceof disease in domestic and wild canids. Angiostrongylus vasorumshould be considered a differential diagnosis for respiratorydisease in the red panda and taken into account when planningparasite and pest control programs for zoological collections.

Key Words: Ailurus fulgens fulgens • Angiostrongylus vasorum • heartworm • pneumonia • red pandas • zoo

A 9-year-old, male, captive-bred red panda was presented tothe Bristol Zoo Gardens Veterinary Department (Bristol, UK)in February 2006 with marked paradoxical breathing, harsh lungsounds, and weight loss (1 kg over the past 2 years).Thoracic radiographs revealed a diffuse broncho-interstitiallung pattern with patchy alveolar filling throughout all lobes,in combination with foci of speckled mineralization (Fig. 1).These changes were not evident on radiographs taken 2 yearsearlier. A provisional diagnosis of chronic bronchopneumoniaof unknown etiology was made. A comparative tuberculin skintest in March 2004 had resulted in a reaction at the bovinetuberculosis site. However, a bronchoalveolar lavage specimenobtained in May 2004 was negative for Mycobacterium sp. by cultureand polymerase chain reaction (PCR) testing and was also negativefor parasites. Because of the poor prognosis for recovery andrenewed concern over possible tuberculosis, the animal was euthanatizedwhile still under general anesthesia.

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Figure 1 Thorax, red panda. Lateral radiographic view showing a diffuse broncho-interstitial lung pattern, with scattered small foci of mineralization (arrows).

At postmortem examination, which was performed by veterinariansat the Bristol Zoo Gardens, the lungs were noted to be consolidatedand mottled red and tan with areas of mineralization affectingall lobes, including at least 50% of the volume of the rightand left caudal lobes. Hemorrhage was noted in the enlargedbronchial lymph nodes. The gastrointestinal tract was emptywith no fecal material in the colon or rectum. Specimens fromthe lungs, bronchial lymph nodes, trachea, left eye, testis,skeletal muscle, spleen, heart, kidney, liver, pancreas, brain,thymus, and gastrointestinal tract were submitted in 10% neutralbuffered formalin to the Department of Pathology and InfectiousDiseases, The Royal Veterinary College, University of London(Hatfield, Hertfordshire, UK). Additional lung tissue was sectionedand frozen at –20°C. Tissue specimens for histologicalexamination were processed routinely, embedded in paraffin wax,sectioned at 5 µm, stained with hematoxylin and eosin,coverslipped, and examined microscopically. Further sectionswere stained with an acid-fast stain (Ziehl–Neelsen).

Histologically, normal pulmonary architecture was largely obliteratedby extensive, often nodular areas of partially mineralized fibroustissue centered on multiple cross sections and oblique sectionsthrough nematode eggs ( $~$ 20 µm x 30 µm)and coiled larvae (6–15 µm in diameter; Fig. 2).Small clusters of epithelioid macrophages and multinucleatehistiocytic giant cells were scattered within the fibrous tissue.In other fields, sheets of epithelioid macrophages and smallernumbers of histiocytic giant cells, granulocytes, plasma cells,and lymphocytes were also centered on large numbers of nematodeeggs and larvae. There were extensive areas of parenchymal necrosisand hemorrhage. Remnant alveolar spaces were dilated, with hyperplasiaof the smooth muscle of bronchiolar walls and alveolar ducts.Some of the remaining bronchioles contained larvae, which werefree within the lumen. Bronchial lymph nodes were hyperplastic,and the medullary region of one lymph node contained granulomascentered on nematode larvae. Acid-fast stains did not revealany bacteria. Microscopic lesions in other tissues includedtesticular and skeletal muscle atrophy, portal hepatitis, andinfiltration of the left ventricular myocardium by small numbersof macrophages.

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Figure 2 Lung, red panda. Most of the normal parenchymal architecture is obliterated by coalescing nodular areas of fibrous tissue that are partially mineralized (arrows) and surround numerous sections through nematode larvae (arrowheads) and eggs (asterisks). Hematoxylin and eosin. Bar = 100 µm.

Subsequent to the histological examination, larvae were removedfrom frozen lung tissue specimens by flushing with phosphate-bufferedsaline. The larvae (n = 21) measured 323 ± 18.0 µmin length (mean ± standard deviation) and 20 ±2.9 µm in diameter and terminated in a sinusoidalprojection with a pronounced dorsal notch, characteristic ofboth Angiostrongylus vasorum and Aelurostrongylus abstrusus(Fig. 3). The larvae were shorter and thicker than first-stagelarvae (L1) of A. vasorum described previously10 but fell withinthe range of lengths in a 1994 case1 and were shorter than A.abstrusus L1 described in a 1949 study.9 The dorsal caudal spinecharacteristic of A. vasorum was not visible in all specimens.

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Figure 3 Larva extracted from lung, caudal portion. Note the deep dorsal notch (arrowhead) and the sinusoidal kink in the tail tip (arrow). Bar = 10 µm.

To identify the L1 larvae by molecular characterization, DNAwas extracted from a 5-mg section of frozen lung tissue witha commercial extraction kit^a according to the manufacturer'sinstructions. A 1,708-bp region of the 18S ribosomal RNA (rRNA)gene was amplified with the primers NC18SF1 (5'-AAAGATTAAGCCATGCA-3')and NC5BR (5'-GCAGGTTCACCTACAGAT-3').6 The entire second internaltranscribed spacer (ITS-2) was amplified with the primers NC1(5'-ACGTCTGGTTCAGGGTTGTT-3') and NC2 (5'-TTAGTTTCTTTTCCTCCGCT-3').8Polymerase chain reaction assays were performed in a final reactionvolume of 25 µl that consisted of 2.5 µlof 10x polymerase buffer^a (TrisCl, KCl, [NH₄]₂ SO₄, 15 mmolMgCl₂, pH 8.7), 0.5 µl each of deoxyribonucleotidetriphosphate (dNTP; 10 mmol each), 0.625 µlof each primer (12.5 ng/ml), 0.125 µl of HotStarTaqDNA polymerase^a (5 U/ml), 19.625 µl of dH₂O, and2 µl of DNA. Targets were amplified following PCRconditions of 95°C for 15 min; followed by 40 cyclesof 95°C for 30 sec, 55°C for 30 sec, and 72°Cfor 1 min; followed by a final extension step of 72°Cfor 5 min. The PCR products were electrophoresed on a 1%(w/v) agarose gel and visualized with the use of ethidium bromideand ultraviolet illumination. The PCR products were purifiedwith a commercial purification kit^b and ligated into the pCR2.1-topoisomeraseI (TOPO) plasmid vector, then transformed into TOP10 One Shotchemically competent Escherichia coli with a TOPO Taq-amplifiedcloning kit.^c Cloned plasmids were purified and then sequencedwith the use of a kit^d with M13 forward and reverse primers.Sequences for the red panda sample were deposited in the GenBankdatabase under the accession numbers EU915247 and EU915248 forthe 18S rRNA gene and ITS-2, respectively. The 18S rRNA genesequence was 100% homologous with A. vasorum (GenBank EF514916and AJ920365), and the ITS-2 sequence was 99% identical to A.vasorum (GenBank EU627592).

The gross, microscopic, and parasitological findings indicatedthat A. vasorum infection was the cause of the respiratory signsand pulmonary inflammation in the red panda in this study. Angiostrongylusvasorum is a metastrongyloid nematode that is known to causecardiopulmonary disease in dogs, foxes, and other canids, withreports in a few other species, including Eurasian badgers.1,2,5,11,14,16Its geographical distribution is patchy but appears to be expandingin several parts of the world,13 and surveys of foxes revealthe parasite to be currently endemic in much of the southernhalf of the United Kingdom,14 with cases in dogs recently appearingin Bristol (unpublished data). In Copenhagen, also in an endemicarea, fatal disease has been reported in several red pandasin the city's zoo in recent years (Grøndahl C, MonradJ, Dietz HH, et al.: 2005, Angiostrongylosis in red panda [Ailurusfulgens fulgens]. Proceedings of the Institute for Zoo and WildlifeResearch, Berlin, 42:117–118; Jensen HE, Dietz HH, GrøndahlC, et al.: 2005, The pathology associated with Angiostrongylusvasorum infection in the red panda [Ailurus fulgens fulgens].Proceedings of the 23rd meeting of the European Society of VeterinaryPathology, pp. 70–71).

Ovoviviparous female worms are located in the cardiac rightventricle and pulmonary vasculature, depositing eggs that passvia the blood to the lungs. First-stage larvae hatch rapidly,penetrate into the alveoli, and are coughed up and swallowed,eventually being passed in the feces. Further development toinfective third-stage larvae (L3) occurs within a few weeksin snail or slug intermediate hosts. Definitive hosts are infectedby ingestion of the intermediate hosts or of paratenic hosts,including frogs.1 Disease is due to proliferative endarteritisand thrombosis in response to the adult worms in the pulmonaryarteries, and pneumonia is caused by the larvae and eggs.4 Infectedcanids can develop chronic right-sided heart failure, progressiverespiratory signs and failure, or both if untreated,1 and coagulationdisorders have also been reported.11 Histological lesions reportedin the lungs of canids with severe disease include granulomatousinflammation, variably severe interstitial fibrosis, thrombosisof pulmonary arteries with fibrin and parasites, arterial fibrosisand recanalization, arterial smooth muscle hyperplasia, andnecrosis.3,4 Granulomas associated with nematode eggs and larvaecan also occur in other tissues, including the tracheobronchiallymph nodes (as in this case), brain, kidney, spleen, and adrenalgland.3,4 The pathological lesions in the red panda in thisstudy were therefore similar to those reported in dogs and foxeswith severe disease, although pulmonary mineralization was moreextensive. Arterial lesions were not noted histologically, butunfortunately, only a few small specimens of lung tissue weresubmitted. Other cases of A. vasorum infection reported in redpandas also featured severe granulomatous inflammation in thelung parenchyma, including mineralization and some foci of osseousmetaplasia, associated with severe and sometimes lethal clinicaldisease (Grøndahl C, et al.: 2005, Angiostrongylosisin red panda).

How the red panda in this study became infected with A. vasorumis not known, but it is presumed that the animal ingested aninfected intermediate or paratenic host. Exposure could haveoccurred through entry of infected slugs or snails into theenclosure, either by their own movement or with food or othermaterial; slugs or snails caught through the enclosure wire;or infection of slug and snail populations within the enclosurefrom inadvertently introduced dog or fox feces. The red pandawas often observed hunting in the enclosure, and ingestion ofslugs or snails is therefore plausible. However, studies onhuman outbreaks of abdominal angiostrongyliasis caused by A.costaricensis suggest the source of infection was food contaminatedwith mucus from infected mollusks rather than the mollusk itself,which indicates another possible route.12,19 The prepatent periodfor A. vasorum in the normal definitive host is 38–57 days.1The pulmonary lesions in the red panda in this case, especiallythe extensive mineralization and fibrosis, indicated long-standinginfection with large numbers of parasites. Routine parasitologicfecal examinations had been conducted every 6 months. However,at the time, zoo policy was only to treat if results were positive,which they were not in this case. Detection of A. vasorum L1would require repeated fecal examination by smear, zinc sulfatecentrifugation–flotation, or, ideally, the Baermann technique.15No anthelmintics had been administered after a single dose ofivermectin^e in October 2004, the efficacy of which against A.vasorum infection is uncertain. Up to June 2003, treatment withfenbendazole had been periodic.^f Fenbendazole, although notlicensed for this purpose, is known to reduce A. vasorum burdensin dogs at a dose rate of 50 mg/kg daily, although up to21 days of treatment might be needed to eliminate infection.Milbemycin oxime and moxidectin are licensed for reduction ofA. vasorum infection in dogs, although treatment with moxidectinhas previously failed to prevent death of infected red pandas(Grøndahl C, et al.: 2005, Angiostrongylosis in red panda).

Several other metastrongyloid nematodes can infect red pandas,including Aelurostrongylus sp., which was diagnosed in 42% of31 animals in a fecal parasitological survey conducted at ChongqingZoo, China,18 as well as Crenosoma (Grøndahl C, et al.:2005, Angiostrongylosis in red panda) and Filaroides sp. (J.McGarry, personal communication, 2008). Larvae of these specieswould also be detected by Baermann extraction. However, identificationon the basis of morphology alone can be difficult, especiallyin distinguishing between A. vasorum and A. abstrusus. The morphologyof the larvae in this case differed subtly from those of A.vasorum typically found in dogs, being slightly larger in diameterand with a less obvious dorsal spine. Host-induced phenotypicvariation is possible in this species, or freezing of lung tissuepossibly altered larval morphology. Molecular analysis was requiredto identify the parasites definitively and suggests that incorrectconclusions can be reached if parasites are identified in unusualhosts on the basis of larval morphology alone (i.e., in theabsence of identification of adult worms in the pulmonary vasculature;Jensen HE, et al.: 2005, The pathology associated with Angiostrongylusvasorum infection in the red panda). Xenodiagnosis (i.e., infectingsnails and then feeding them to captive foxes followed by examinationfor evidence of parasitic infection; Grøndahl C, et al.:2005, Angiostrongylosis in red panda) is impractical as a routinediagnostic test.

The case in this report highlights the need for preventativehealth plans for captive red pandas in A. vasorum–endemicareas, of which zoo veterinarians should be aware. Opportunitiesfor exposure to slugs and snails should be limited as far asis practical, and feces should be routinely examined for L1,noting that routine salt flotation is not sufficient. No provenanthelmintic prevention protocol for red pandas exists; however,anecdotal reports suggest some success with milbemycin oxime(11.5 mg per 5 kg body weight PO [by mouth], monthly;Grøndahl C, et al.: 2005, Angiostrongylosis in red panda).This drug has been used successfully to treat infections indogs.7 Fenbendazole or moxidectin are also effective in eliminatinginfection in dogs17 and might have some prophylactic effects,but this is not yet proven. Angiostrongylus vasorum should beconsidered a differential diagnosis by clinicians and pathologistsin cases of respiratory disease in red pandas captive in endemicareas, and prompt treatment should be instigated where it issuspected.

Acknowledgments

The authors thank Dr. Mark Fox of the Department of Pathologyand Infectious Diseases, The Royal Veterinary College, for hisreview of the manuscript, and the Morris Animal Foundation forsupport through First Award D06CA-308 "Molecular epidemiologyof French heartworm infection in dogs and foxes," which enableddevelopment of the molecular diagnostics.

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From the Department of Pathology and Infectious Diseases, TheRoyal Veterinary College, University of London, Hatfield, Hertfordshire,United Kingdom (Patterson-Kane, Gibbons, Wenzlow), the Schoolof Biological Sciences, University of Bristol, Bristol, UnitedKingdom (Jefferies, Morgan), and the Bristol Zoo Gardens, Clifton,Bristol, United Kingdom (Redrobe).

DNeasy®, Qiagen GmBH, Hilden, Germany.

QIAquick®, Qiagen GmBH, Hilden, Germany.

TOPO® TA Cloning Kit, Invitrogen, Carlsbad, CA.

ABI PRISM^TM Dye Terminator Cycle Sequencing Core Kit, AppliedBiosystems, Foster City, CA.

Ivomec®, Merial Animal Health Ltd., Harlow, Essex, UnitedKingdom.

Panacur®, Intervet Inc., Walton, Milton Keynes, United Kingdom.

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