1.Genomic analysis of Sheldrake origin goose hemorrhagic polyomavirus, China
Chunhe WAN ; Cuiteng CHEN ; Longfei CHENG ; Rongchang LIU ; Guanghua FU ; Shaohua SHI ; Hongmei CHEN ; Qiuling FU ; Yu HUANG
Journal of Veterinary Science 2018;19(6):782-787
Goose hemorrhagic polyomavirus (GHPV) is not a naturally occurring infection in geese in China; however, GHPV infection has been identified in Pekin ducks, a domestic duck species. Herein, we investigated the prevalence of GHPV in five domestic duck species (Liancheng white ducks, Putian black ducks, Shan Sheldrake, Shaoxing duck, and Jinyun Sheldrake) in China. We determined that the Jinyun Sheldrake duck species could be infected by GHPV with no clinical signs, whereas no infection was identified in the other four duck species. We sequenced the complete genome of the Jinyun Sheldrake origin GHPV. Genomic data comparison suggested that GHPVs share a conserved genomic structure, regardless of the host (duck or geese) or region (Asia or Europe). Jinyun Sheldrake origin GHPV genomic characterization and epidemiological studies will increase our understanding of potential heterologous reservoirs of GHPV.
China
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Ducks
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Epidemiologic Studies
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Geese
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Genome
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Polyomavirus
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Prevalence
2.Chewing Lice of Swan Geese (Anser cygnoides): New Host-Parasite Associations.
Chang Yong CHOI ; John Y TAKEKAWA ; Diann J PROSSER ; Lacy M SMITH ; Craig R ELY ; Anthony D FOX ; Lei CAO ; Xin WANG ; Nyambayar BATBAYAR ; Tseveenmayadag NATSAGDORJ ; Xiangming XIAO
The Korean Journal of Parasitology 2016;54(5):685-691
Chewing lice (Phthiraptera) that parasitize the globally threatened swan goose Anser cygnoides have been long recognized since the early 19th century, but those records were probably biased towards sampling of captive or domestic geese due to the small population size and limited distribution of its wild hosts. To better understand the lice species parasitizing swan geese that are endemic to East Asia, we collected chewing lice from 14 wild geese caught at 3 lakes in northeastern Mongolia. The lice were morphologically identified as 16 Trinoton anserinum (Fabricius, 1805), 11 Ornithobius domesticus Arnold, 2005, and 1 Anaticola anseris (Linnaeus, 1758). These species are known from other geese and swans, but all of them were new to the swan goose. This result also indicates no overlap in lice species between older records and our findings from wild birds. Thus, ectoparasites collected from domestic or captive animals may provide biased information on the occurrence, prevalence, host selection, and host-ectoparasite interactions from those on wild hosts.
Animals
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Bias (Epidemiology)
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Birds
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Far East
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Geese*
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Lakes
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Mastication*
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Mongolia
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Phthiraptera*
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Population Density
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Prevalence
3.Chewing Lice of Swan Geese (Anser cygnoides): New Host-Parasite Associations.
Chang Yong CHOI ; John Y TAKEKAWA ; Diann J PROSSER ; Lacy M SMITH ; Craig R ELY ; Anthony D FOX ; Lei CAO ; Xin WANG ; Nyambayar BATBAYAR ; Tseveenmayadag NATSAGDORJ ; Xiangming XIAO
The Korean Journal of Parasitology 2016;54(5):685-691
Chewing lice (Phthiraptera) that parasitize the globally threatened swan goose Anser cygnoides have been long recognized since the early 19th century, but those records were probably biased towards sampling of captive or domestic geese due to the small population size and limited distribution of its wild hosts. To better understand the lice species parasitizing swan geese that are endemic to East Asia, we collected chewing lice from 14 wild geese caught at 3 lakes in northeastern Mongolia. The lice were morphologically identified as 16 Trinoton anserinum (Fabricius, 1805), 11 Ornithobius domesticus Arnold, 2005, and 1 Anaticola anseris (Linnaeus, 1758). These species are known from other geese and swans, but all of them were new to the swan goose. This result also indicates no overlap in lice species between older records and our findings from wild birds. Thus, ectoparasites collected from domestic or captive animals may provide biased information on the occurrence, prevalence, host selection, and host-ectoparasite interactions from those on wild hosts.
Animals
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Bias (Epidemiology)
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Birds
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Far East
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Geese*
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Lakes
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Mastication*
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Mongolia
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Phthiraptera*
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Population Density
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Prevalence
4.Effects of cysteamine on the plasma levels of SS and some metabolic hormones in adult geese.
Xiao-Jie AI ; Yuan-Lin ZHENG ; Wei-Hua CHEN ; Zheng-Kang HAN
Chinese Journal of Applied Physiology 2004;20(1):88-90
AIMTo know the effect of cysteamine (CS) on the plasma levels of somatostatin (SS) and some metabolic hormones in adult geese.
METHODSFourteen adult crossbred geese (Chuan white x Tai lake) fitted with chronic wing vein cannulas were used in this study to evaluate the effect of CS on SS, TSH, T3 and T4 levels. The experiment was consisted of control and treated phase. The diet was added CS at dosage of 100 mg/kg bw on the first day of the treated phase. The blood samples were collected from the cannulas and analyzed by radioimmunoassay.
RESULTSThe plasma SS concentration was (1.87 +/- 0.10) microg/L in control phase. Whereas SS concentrations on day 1, 3, 5, 7 of treated phase were decreased markedly (P < 0.05 or P < 0.01). Thereafter it was rose on the seventh day, however it was still lower than that of control. The thyroid stimulating hormone (TSH) content (2.45 +/- 0.31 mIU/L) was significantly decreased by 21.63% (P < 0.01) on day 1, and 18.37% (P > 0.05) on day 3 and day 5. Comparing with control phase (5.41 +/- 0.98 microg/L), T4 contents were elevated by 60.26% (P < 0.01), 43.25% (P < 0.01), 37.15% (P < 0.01) and 16. 82% (P < 0.01) respectively on day 1, 3, 5, 7. T3 level was (1.05 +/- 0.06) microg/L in control phase, whereas the levels was significantly increased by 36.19% (P < 0.01) on day 3. Also, the insulin concentration was higher than that of control (4.43 +/- 0.41 mU/ L) by 18.28% (P < 0.05) on the day 5.
CONCLUSIONThese results indicate that CS can decrease the plasma SS and TSH levels, whereas increase the levels of T4, T3 and insulin, therefore change metabolism, improve the nutrition transform and accelerate the growth in geese.
Animals ; Cysteamine ; pharmacology ; Diet ; Geese ; Insulin ; blood ; Somatostatin ; blood ; Thyrotropin ; blood ; Thyroxine ; blood ; Triiodothyronine ; blood
5.Effect of cysteamine on the pancreatic secretion and enzymatic activity in geese.
Chinese Journal of Applied Physiology 2002;18(3):297-300
AIMTo know the effect of cysteamine on the pancreatic secretion and enzyme activity in geese.
METHODSEight adult geese fitted chronic pancreatic and duodenal cannulas were used to evaluate the effect of cysteamine (CS) on the pancreatic secretion and enzyme activity. The experiment was consist of control and treated phase. CS was added in the diet at the dosage of 100 mg/kg bw on the first day of treated phase. The birds were free fed at daytime (8:00-20:00) and fasted at nighttime (20:00-8:00). The pancreatic juice samples were collected continuously for three days in each phase.
RESULTSCS increased the average rate of pancreatic secretion by 240.16% (P < 0.01), in which that of daytime was elevated by 234.45% (P < 0.01), while that of nighttime elevated by 253.70% (P < 0.01). The secretion volume at daytime was more than that of night. CS increased trypsin activity by 49.05% (P < 0.01), whereas lipase and amylase activity was reduced by 25.44% (P < 0.01) and 21.95% (P < 0.01) separately. The one hour total activity of trypsin, lipase and amylase were elevated by 406.88% (P < 0.01), 153.58% (P < 0.01) and 166.59% (P < 0.01) respectively. Ratios of pancreatic secretion were different between day and night.
CONCLUSIONThese results indicate that CS can affect the pancreatic juice secretion and pancreatic enzyme activity by depleting the somatostatin, so that benefits to improve the digestive foundation and supply more nutrition for quickly growing in geese.
Animals ; Cysteamine ; pharmacology ; Geese ; physiology ; Pancreas ; drug effects ; enzymology ; secretion ; Pancreatic Juice ; secretion ; Pancreatin ; metabolism
6.Construction and transfection experiment of a goose circovirus infectious clone.
Ya-Ping XU ; Jing TIAN ; Hai-Xia YUAN ; Jing GUO ; Hong-Xia SUN ; Wen-Wen LI ; Wei-Hu CHEN ; Xu-Ping YU
Chinese Journal of Virology 2012;28(1):29-34
A pair of primers with BamH I restriction site were designed to amplify the complete genome of goose circovirus. Two copies of the genome were ligated in tandem and cloned into pGEM-T Easy vector to construct an infectious clone named as pGEMT-2GoCV. The pGEMT-2GoCV linearized with EcoR I was transfected to negative embryos and gosling with Lipfectamine. PCR detection verified the proliferation of GoCV in geese. Some sera of the embryo transfected group were detected to be positive at 2 and 4 weeks after hatching and one bursa was detected to be positive at 4 weeks. Some sera of the gosling transfected group were also detected to be positive at 2 weeks after transfection. Furthermore, the mark in the PCR products were identified by BamH I digestion and the GoCV in positive tissue and sera were quantitated by Real-time PCR. The results showed that the virus load in positive bursa was 1.57 x 10(6) copies/mg, the virus load in positive sera were 3.52 x 10(4)-5.92 x 10(5) copies/microL. In conclusion, the infectious DNA clone constructed with two copies of full-length GoCV genome in tandem can transfect embryo and gosling and propagate the marked goose circovirus.
Animals
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Circovirus
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genetics
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Geese
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virology
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Real-Time Polymerase Chain Reaction
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Transfection
7.Surveillance of wild birds for avian influenza virus in Korea.
Dong Hun LEE ; Chang Seon SONG
Korean Journal of Veterinary Research 2013;53(4):193-197
Avian influenza viruses (AIV) have been isolated from a wide range of domestic and wild birds. Wild birds, predominantly ducks, geese and gulls form the reservoir of AIV in nature. The viruses in wild bird populations are a potential source of widespread infections in poultry. Active surveillance for AIV infection provides information regarding AIV distribution, and global AIV surveillance can play a key role in the early recognition of highly pathogenic avian influenza (HPAI). Since 2003 in Korea, there have been four H5N1 HPAI outbreaks caused by clade 2.5, 2.2 and 2.3.2. Therefore, improvement of AIV surveillance strategy is required to detect HPAI viruses effectively. This article deals with the major events establishing the role of wild birds in the natural history of influenza in Korea. We highlighted the need for continuous surveillance in wild birds and characterization of these viruses to understand AIV epidemiology and host ecology in Korea.
Animals
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Birds*
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Charadriiformes
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Disease Outbreaks
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Ducks
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Ecology
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Epidemiology
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Geese
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Influenza in Birds*
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Influenza, Human
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Korea*
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Natural History
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Poultry
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Viruses*
8.Immunogenicity of recombinant Lactobacillus plantarum NC8 expressing goose parvovirus VP2 gene in BALB/c mice.
Yu Ying LIU ; Wen Tao YANG ; Shao Hua SHI ; Ya Jie LI ; Liang ZHAO ; Chun Wei SHI ; Fang Yu ZHOU ; Yan Long JIANG ; Jing Tao HU ; Wei GU ; Gui Lian YANG ; Chun Feng WANG
Journal of Veterinary Science 2017;18(2):159-167
Goose parvovirus (GPV) continues to be a threat to goose farms and has significant economic effects on the production of geese. Current commercially available vaccines only rarely prevent GPV infection. In our study, Lactobacillus (L.) plantarum NC8 was selected as a vector to express the VP2 gene of GPV, and recombinant L. plantarum pSIP409-VP2/NC8 was successfully constructed. The molecular weight of the expressed recombinant protein was approximately 70 kDa. Mice were immunized with a 2 × 109 colony-forming unit/200 µL dose of the recombinant L. plantarum strain, and the ratios and numbers of CD11c⁺, CD3⁺CD4⁺, CD3⁺CD8⁺, and interferon gamma- and tumor necrosis factor alpha-expressing spleen lymphocytes in the pSIP409-VP2/NC8 group were higher than those in the control groups. In addition, we assessed the capacity of L. plantarum SIP409-VP2/NC8 to induce secretory IgA production. We conclude that administered pSIP409-VP2/NC8 leads to relatively extensive cellular responses. This study provides information on GPV infection and offers a clear framework of options available for GPV control strategies.
Agriculture
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Animals
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Geese
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Immunization
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Immunoglobulin A, Secretory
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Interferons
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Lactobacillus plantarum*
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Lactobacillus*
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Lymphocytes
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Mice*
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Molecular Weight
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Parvovirus*
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Spleen
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Tumor Necrosis Factor-alpha
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Vaccines
9.Cross-reactivity between Hen's Egg from Goose, Duck and Domestic Birds in Children with Egg Allergy.
Jeong Hoon KIM ; Tai Young HAM ; Sung Yeon CHOI ; Kyung Eun LEE ; Byeong Chul KWON ; Myung Hyun SHON ; Kyu Earn KIM
Pediatric Allergy and Respiratory Disease 2003;13(4):248-254
PURPOSE: Birds' eggs have been a major source of food for mankind since the time unknown. Among them, chicken eggs have been the most important food source. We examined the allergenic properties of eggs from varying birds on patients with known allergy to chicken eggs, to find out whether they can replace the chicken eggs for the source of nutrient. METHODS: Samples were selected from patients who visited the allergy clinic of the Department of Pediatrics at Yonsei University Medical Center. The serum specific IgE for eggs were measured and allergy skin tests were performed. The serum of the patients with proven egg allergy was then tested for reactivity with eggs from wild and domestic ducks, geese, seagulls, quails, yellow-shelled and white-shelled eggs employing SDS-PAGE and IgE immunoblotting. RESULTS: All the egg protein showed similar molecular sizes ranging from 24-100 kDa. Their expressions, however, were different, with white eggs, yellow eggs, and quail eggs showing strong reaction, while ducks, geese, and mallard eggs presented with weak reaction. Immunoblotting exhibited reactivity in 35-50 kDa and 25-35 kDa groups. Quail eggs and shells from chicken eggs showed a protein banding of 75-80 kDa. Geese, wild and domestic ducks, quail did not exhibit any cross-reactivity with chicken eggs. CONCLUSION: Among patients with egg allergy, cross-reactivity between different chicken eggs was present, but no cross-reactivity was apparent between chicken eggs and other birds' eggs. Therefore, we suggest theses eggs as alternative source of food in patients with egg allergy. However further study with larger patient population is still required.
Academic Medical Centers
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Animals, Domestic
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Birds*
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Chickens
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Child*
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Ducks*
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Egg Hypersensitivity*
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Eggs
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Electrophoresis, Polyacrylamide Gel
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Geese
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Humans
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Hypersensitivity
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Immunoblotting
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Immunoglobulin E
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Ovum*
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Pediatrics
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Quail
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Skin Tests
10.Characterization of Lentogenic Newcastle Disease Virus Isolated in Jeju, Korea during 2007~2008 Surveillance.
Eun Kyoung LEE ; Woo Jin JEON ; Jin Won KIM ; Mi Ja PARK ; Sung Hwan MOON ; Sang Hun LEE ; Jun Hun KWON ; Kang Seuk CHOI
Journal of Bacteriology and Virology 2009;39(4):383-393
To expand the epidemiological understanding of Newcastle disease in Jeju Province, Korea, active surveillance was extensively performed through a virological examination for poultry farms and wild birds in Jeju Province during 2007~2008. Samples (swabs or fresh feces) were collected from a total of 6,485 birds including 6,405 domestic birds (chickens, ducks, pheasants, geese, quails, turkeys, and ostriches) and 80 wild birds. A total of 24 hemagglutinating agents were isolated from domestic birds on fourteen farms including five Korean native chicken, one layer chicken, two broiler chicken, four duck and two pheasant farms. The hemagglutinating agents were all identified as lentogenic NDV based on the reverse transcriptase polymerase chain reaction, sequence analysis of amino acids on the F cleavage site and mean death time in chicken embryos. The F gene-based phylogenetic analysis revealed that the NDV isolates were classified into genotypes 1 or 2 of class II. These lentogenic viruses were closely related to NDV vaccine strains used in Jeju Province. Active surveillance conducted for Newcastle disease indicates no scientific evidence of virulent NDV infection in chickens in Jeju Province, Korea since 2005.
Amino Acids
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Animals
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Birds
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Chickens
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Ducks
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Embryonic Structures
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Geese
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Genotype
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Korea
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Newcastle Disease
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Newcastle disease virus
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Poultry
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Quail
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Reverse Transcriptase Polymerase Chain Reaction
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Sequence Analysis
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Turkeys