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Memórias do Instituto Oswaldo Cruz
Fundação Oswaldo Cruz, Fiocruz
ISSN: 1678-8060 EISSN: 1678-8060
Vol. 91, Num. 6, 1996
Mem Inst Oswaldo Cruz, Rio de Janeiro, Vol. 91(6), Nov./Dec. 1996,

RESEARCH NOTE

Wild Birds as Reservoir of Thermophilic Enteropathogenic Campylobacter Species in Southern Chile

H Fernandez+, W Gesche%/*, A Montefusco*, R Schlatter**

Instituto de Microbiologia Clinica *Instituto de Salud Publica **Instituto de Zoologia, Universidad Austral de Chile, Casilla Postal 567, Valdivia, Chile

This work received financial support from Direccion de Investigacion y Desarrollo, Universidad Austral de Chile, Grants S-92-05 and S-95-45 and FONDECYT Grants 59-89 and 1930353.
% In memoriam, deceased 27 May 1995
+Corresponding author. Fax: +56-63-214475
Received 23 April 1996, Accepted 18 June 1996

Key words: Campylobacter - epidemiology - reservoirs - wild birds

Code Number: OC96125
Sizes of Files:
 Text: 8.4K
 Graphics: No associated graphics files 

Thermophilic Campylobacter species (C. jejuni subsp. jejuni, C. coli and C. lari) are zoonotic bacteria worldwide recognized as important enteropathogens for human beings (P Vandamme & H Goosens 1992 Zbl Bakt 276: 447-452, H Fernandez 1992 Cien Cult 44: 39-43). A wide range of domestic and wild animal species, including mammals and birds, have been identified as natural reservoirs of Campylobacter in industrialized as well as in developing countries and, they could be a source of contamination for human beings, other animals, food and environmental water bodies (G Kapperud & O Rosef 1983 Appl Environ Microbiol 45: 375-380, O Rosef et al. 1983 Appl Environ Microbiol 46: 855-859, M Blaser et al. 1983 Epidemiol Rev 5: 157-176, Fernandez loc. cit.).

In the present study, wild birds from southern Chile were surveyed for fecal carriage of the classical thermophilic Campylobacter species in order to assess the regional wildlife reservoir of these bacteria.

Cloacal swabs were collected from a total of 392 adult wild- living birds representing seven species (Table). The birds were sampled in several places of the province of Valdivia (39 degrees 28'-40 degrees 20' southern latitude, 71 degrees 30'- 73 degrees 45' western longitude) and the cloacal material collected was seeded into the transport-enrichment medium described by H Fernandez (1992 Rev Microbiol Sao Paulo 23: 149-151) and transported to the laboratory. Following an enrichment period of 24 hr at 42 degrees C under microaerobic conditions in a GasPak system without the catalyst, cultivation was performed by plating each sample onto Skirrow agar. Plates were incubated for 48 hr under the same conditions described above. Suspected colonies were identified morphologically (Gram stain), biochemically (oxidase, catalase, sensitivity to nalidixic acid and cephalotin, hippurate hydrolisis) and biotyped by Lior's scheme (1984 J Clin Microbiol 20: 636-640).

The results obtained are shown in the Table. From the 392 birds studied, 95 (24.2%) harbored thermophilic Campylobacter species being C. jejuni subsp. jejuni the most frequently isolated (69.5% - 66/95) followed by C. coli (23.1% - 22/95). C. lari was isolated only from waterfowl (7.4% - 7/95).

The frequency which Campylobacter was recovered from wild ducks (67.4%) is higher than that reported by N Luechtefeld et al. (35%) in northern Colorado (1980 J Cin Microbiol 12: 406-408) and similar to that reported by R Pacha et al. (73%) in central Washington (1988 Can J Microbiol 34: 80-82). In those birds, as well as in seagulls and cormorants, we found the three classical thermophilic species of Campylobacter. From the two swans that were included in this study, one harbored C. jejuni subsp. jejuni and the second, C. lari. These results support previous findings (Luechtefeld et al. loc.cit., Pacha et al. loc. cit.) and suggest that waterfowl are natural reservoirs that could play a role in the waterborne spread of these bacteria. Waterborne outbreaks of Campylobacter-associated gastroenteritis involving aquatic birds as possible contamination source have been reported (SR Palmer et al. 1983 Lancet 1: 287-290, A Borczyc et al. 1987 Lancet 1: 164-165).

The isolation rate of Campylobacter from pigeons and sparrows was higher than the one reported by S Matsusaki et al. in Japan (1985 3rd International Workshop on Campylobacter infection, Ottawa, Canada, Abstract N degrees 160) but slightly lower than the one reported in 1988 by H Fernandez (1988 Rev Inst Med Trop Sao Paulo 30: 357-360) for the same birds species from our geographical region. Pigeons and sparrows are birds that can live near human habitat and could be sources of contamination for water supplies and environment (Palmer loc.cit.).

The lowest isolation rate was obtained from chimango caracara hawks (3.5%), and as far as we know, this would be the first identification of members of the family Falconidae as reservoirs of thermophilic Campylobacter species.

Considering these results and previously published data (H Fernandez et al. 1994 Rev Inst Med Trop Sao Paulo 36: 433-436), we can conclude that there exists an extensive indigenous reservoir of thermophilic Campylobacter in southern Chile. However, we do not know the contribution of each of these identified reservoirs to human infection. O Rosef et al. (1985 Appl Environ Microbiol 49: 1507- 1510) and Y Weisman et al. (1986 Israel J Med Sci 22: 149) reported that wild birds carry Campylobacter serotypes that also occur in cases of human Campylobacter enteritis. Nevertheless, the potencial role of these birds in the epidemiology of human campylobacteriosis will require further studies involving antigenic, pathogenic and genotypic characterization of avian and human isolates.

TABLE

Isolation rates of thermophilic Campylobacter species and their biovars (Lior scheme) from different species of wild birds

Wild birds                N Positive   C. jejuni subsp. jejuni
                                       -----------------------
                                       biov     biov    biov
                                        I        II      III
--------------------------------------------------------------
Yellow-billed Pintail 
Anas georgica            46 31(76.4)  6(19.3)  8(25.8) 2(6.4)
Kelp Gull 
Larus dominicanus        15  8(53.3)  2(25.0)  1(12.5) 0(0)
Olivaceus Cormorant 
Phalacrocorax olivaceus  11  6(54.6)  1(16.7)  2(33.3) 1(16.7)
Black-necked Swan 
Cygnus melanocorypha      2  2(100)   0(0)     1(50.0) 0(0)
Feral Pigeon (intr.) 
Columba livia           104 11(10.6)  3(27.3)  4(36.4) 0(0)
Chimango Caracara 
Milvago chimango        114  4(3.5)   1(25.0)  2(50.0) 0(0)
European Sparrow (intr.) 
Passer domesticus       100 33(33.0) 11(33.3) 17(51.5) 4(12.1)
Total                   392 95(24.2) 24(25.3) 35(36.8) 7(7.4)


Wild birds                   C. coli          C. lari
                           -------------     ------------
                           biov     biov     biov    biov 
                            I        II       I       II 
-----------------------------------------------------------
Yellow-billed Pintail 
Anas georgica              7(22.6)  5(16.1)  2(6.4)  1(3.2) 
Kelp Gull 
Larus dominicanus          0(0)     3(37.5)  1(12.5) 1(12.5) 
Olivaceus Cormorant 
Phalacrocorax olivaceus    1(16.7)  0(0)     0(0)    1(16.7) 
Black-necked Swan 
Cygnus melanocorypha       0(0)     0(0)     0(0)    1(50.0) 
Feral Pigeon (intr.) 
Columba livia              1(9.1)   3(27.3)  0(0)    0(0) 
Chimango Caracara 
Milvago chimango           1(25.0)  0(0)     0(0)    0(0) 
European Sparrow (intr.) 
Passer domesticus          0(0)     1(3.0)   0(0)    0(0) 
Total                     10(10.5) 12(12.6)  3(3.2)  4(4.2) 

N= number of birds studied; biov= biovar; ( ) = %.

Copyright 1996 Fundacao Oswaldo Cruz

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