Indian Journal of Animal Research

  • Chief EditorK.M.L. Pathak

  • Print ISSN 0367-6722

  • Online ISSN 0976-0555

  • NAAS Rating 6.50

  • SJR 0.263

  • Impact Factor 0.4 (2024)

Frequency :
Monthly (January, February, March, April, May, June, July, August, September, October, November and December)
Indexing Services :
Science Citation Index Expanded, BIOSIS Preview, ISI Citation Index, Biological Abstracts, Scopus, AGRICOLA, Google Scholar, CrossRef, CAB Abstracting Journals, Chemical Abstracts, Indian Science Abstracts, EBSCO Indexing Services, Index Copernicus
Submit

Research Article

Indian Journal of Animal Research, volume 57 issue 1 (january 2023) : 102-107

Temporo-Spatial Sero-epidemiology of Fowl Adenovirus (FAdV) Infection Causing Inclusion Body Hepatitis-Hydropericardium Syndrome (IBH-HPS) in Broiler Population of Assam

Biswajit Dutta1,*, D.C. Pathak1, N.N. Barman2, Navalakhi Hazarika3, S. Goswami1
1Department of Veterinary Pathology, College of Veterinary Science, Assam Agricultural University, Guwahati-781 022, Assam, India.
2Department of Microbiology, College of Veterinary Science, Assam Agricultural University, Guwahati-781 022, Assam, India.
3Department of Mathematics, G.L. Choudhury College, Barpeta-781 315, Assam, India.
Cite article:- Dutta Biswajit, Pathak D.C., Barman N.N., Hazarika Navalakhi, Goswami S. (2023). Temporo-Spatial Sero-epidemiology of Fowl Adenovirus (FAdV) Infection Causing Inclusion Body Hepatitis-Hydropericardium Syndrome (IBH-HPS) in Broiler Population of Assam . Indian Journal of Animal Research. 57(1): 102-107. doi: 10.18805/IJAR.B-4224.

ABSTRACT

Background: Aviadenoviruses affect birds, particularly chickens, ducks, geese, turkeys and pheasants, which have total 12 serotypes. Inclusion body hepatitis (IBH) caused by aviadenovirus was has been reported in many countries worldwide. The diseases was first reported from Assam in 2017. Although there is increasing reports of the occurrence of IBH-HPS in the broiler population of North Eastern India, but its prevalence at different geoclimatic condition and at various seasons have not been carried out. Under these circumstances, the present study was envisaged to analyse the seroprevalence status of Fowl adenovirus infection in some broiler rearing districts of Assam. 

Methods: For the present study, blood samples were collected from 12 different districts of Assam including all agroclimatic regions during the period from June, 2016 to May, 2017. Association of various factors like age, season and health status with the prevalence of the affected birds were also studied. Indirect ELISA was performed by using commercially available FAdV ELISA kit. The results obtained were analyzed by the Statistical Package for Social Sciences (SPSS) version 26.0.

Result: A total of 460 serum samples were screened, of which 213 were found positive for FAdV antibodies with a sero-positivity of 46.38 per cent. FAdV antibodies were observed in all age grouped birds. Highest (64.28%) positivity was recorded in the birds of 4th week of age, followed by above 4th week (63.47%), 3rd week (32.03%), 2nd week (27.36%) and 1st week (10.0%). Health status-wise 68.97 percent sero-positivity was recorded in the affected flock, where as 32.51 percent in apparently healthy flock. Season-wise, highest (61.53%) sero-positivity was recorded in post monsoon season followed by monsoon (49.00%), winter (32.49%) and pre-monsoon (32.39%). 

INTRODUCTION

The avian adenovirus was first isolated from an outbreak of respiratory disease in quail (Olson, 1950). Aviadenoviruses affect birds, particularly chickens, ducks, geese, turkeys and pheasants. There are total 12 serotypes of Fowl adenovirus viz. FAdV-1, FAdV-2 FAdV-3, FAdV-4, FAdV-5, FAdV-6, FAdV-7, FAdV-8a, FAdV-8b, FAdV-9, FAdV-10 and FAdV-11 which were classified on the basis of restriction fragment length polymorphism (RFLP) profile and sequencing data (Benko et al., 2000). Inclusion body hepatitis (IBH) caused by aviadenovirus was first described in 1963 from USA (Helmboldt and Frazier, 1963). Thereafter, the disease has been reported in many countries worldwide.

In late eighties, a new disease in broilers with some similarities to classical inclusionbody hepatitis (IBH) was reported from Angara Goth near Karachi, Pakistan. The disease was mainly characterized by accumulation of clear straw coloured fluid in the pericardial sac along with hepatitis (Jaffery, 1988) and named as Hydropericardium syndrome (HPS)/ Angara disease. In India, HPS was first noticed in the poultry belt of Jammu and Kashmir, Punjab and Delhi during April-July, 1994 (Gowda and Satyanarayana, 1994). After a few months, the disease spread to Terai of Uttarakhand in November, 1994 (Kumar et al., 1997). Then several outbreaks were recorded in Uttar Pradesh, Maharastra, Andhra Pradesh, Karnataka, Tamil Nadu, Kerala, Odisha, West Bengal, Chattisgarh and Mizoram resulting in huge economic losses to the poultry industry (Gupta et al., 2007, Asthana et al., 2013, Suohu and Rajkhowa, 2021). The first outbreak of IBH-HPS in Assam was reported recently by Dutta et al., (2017).        

Various serological tests viz. AGID, counterimmune electrophoresis and various modifications of ELISA were used for studying the seroprevalence of fowl adenoviral infection in poultry (Kumar et al., 2003). The ELISA can be used for detecting both group and type specific antibodies against FAdV and proved to be more sensitive (Saifuddin et al., 1992). The indirect ELISA was found to be easier, accurate and appropriate for screening and monitoring large amount of samples (Junnu et al., 2014).

Although there is increasing reports of the occurrence of IBH-HPS in the broiler population of North Eastern India, but its prevalence at different geoclimatic condition and at various seasons have not been carried out. Under these circumstances, the present study was envisaged to analyse the seroprevalence status of Fowl adenovirus infection in some broiler rearing districts of Assam.

MATERIALS AND METHODS

The present investigation was carried out in the Department of Veterinary Pathology, College of Veterinary Science, Assam Agricultural University, Khanapara, Guuwahati, Assam.
 
Study area
 
Assam, the gateway of North Eastern states of India (78,438 km2 area, area rank 16th of the country), with latitude and longitude of 26.244156 and 92.537842 respectively having gps coordinates of 26o14¢38.9616² and 92o32¢16.2312². The state shares international boarders with Bangladesh and the Kingdom of Bhutan. The state has 33 revenue districts and can be divided into 6 agro-climatic zones viz. Lower Brahamaputra Valley, North Bank plain zone, Central Barak Valley zone, Upper Brahamaputa Valley zone, Barak Valley zones and Hill Zones.

For the present study, blood samples were collected from 12 different districts of Assam viz Kamrup (M), Karrup (R), Nalbari, Goalpara, Morigaon, Nagaon, Sonitpur, Lakhimpur, Dhemaji, Karbi-Anglong, Golaghat and Jorhat during the period from June, 2016 to May, 2017, to determine the sero-prevalence of Fowl adenovirus (Fig 1).

Fig 1: Map of Assam, showing the districts from where samples were collected.


 
Study design and sampling method
 
A structured questionnaire covering the age, health status, vaccination status, previous occurrence of any other diseases etc. of birds were prepared to collect epidemiological data.

The sample size required for the study was framed  according to the formula given by Thrustfield (1995) considering the 50% prevalence as expected prevalence 95% confidence interval and 5% absolute precision, the number of birds to be studied were 384 as calculated below and in order to improve the precision, the sample size was increased upto 460.
n= 1.962 x Pexp (1-Pexp)/d2
n= 1.962 x 0.5% (1-0.5)/0.052          1.96 - Z value of 95% CI
n= 384                                                  
n= Required sample size.
Pexp= Expected prevalence.
d2= Desired absolute precision.
 
Temporal and spatial distribution
 
Factor associated with Sero-prevalence of Fowl adenovirus

Season: To study the effect of season, a calendar year was divided into four (4) seasons viz. pre-monsoon (March - May), monsoon (June - September), post-monsoon (October-November) and winter (December -February). During the period of study, the meteorological data were collected from the Regional Meterological Centre, Barjhar, Guwahati, Assam.
 
Age: To study the effect of age on seroprevalence, the birds were divided into 5 groups as follows.

Health status
 
To study the effect of health-status on prevalence, the blood samples were collected from both from apparently healthy as well as diseased flock.
 
Sample collection
 
The sampling procedure was approved by institutional animal ethics committee. About 2 ml of blood was collected from each from the medial metatarsal vein in clot activator vial. The serum was separated from blood by centrifuging at 3000 rpm for 10 min. The separated serum was collected in a screw capped plastic vial and stored at -20oC until they were tested.
 
ELISA test
 
The seroprevalenceof fowl adenovirus was studied by using FAdV ELISA kit manufactured by BioCheck, UK (Xia et al., 2017). Briefly, 5 µl of test sample were taken into dilution plate and added 245 µl of sample diluents to make 1:50 dilution. 100 µl of negative control was added to the wells A1 and B1 and 100 µl of positive control was added to the wells C1 and D1. Then 50 µl of sample diluents were added to the rest of the well and then add 50 µl of 1:50 dilution test sample in the appropriate well to obtain 1:100 sample dilution. The plates were then incubated at room temperature for 30 minutes. Then plate was washed four times with wash buffer (350 µl each well). The plate was inverted and tap firmly on absorbent paper until no moisture was visible. The 100µl of conjugate reagent was added into the appropriate well and incubated at room temperature for 30 minutes. After incubation, the plate was again washed four times with wash buffer (350 µl each well) and 100 µl of substrate reagent was added and incubated at room temperature for 15 minutes. The reaction was stopped after 15 minutes by adding 50 µl of stop solution. The plate was observed for colour development and the reaction was read optically by using an ELISA reader (BioRad) at 405 nm wavelength.

The results are expressed as antibody units which were calculated as subtract the optical density of negative control serum NC (ODNC) from the optical density of positive control serum PC (ODPC) as well as from the optical density of tested serum samples (OD TS). The results were obtained as S:P (Serum: Positive) ratio, from the following formula:-
 
Sample with an S/P of 0.5 or greater were considered as positive.
 
Calculation of antibody titre
 
The following equation relates the S/P of a sample at a 1:100 dilution to an end point titre.
Log10 Titre: 1.1*Log10 (S/P) + 3.361
Antilog= Titre

 
Data analysis
 
The results obtained were analysed by the Statistical Package for Social Sciences (SPSS) version 26.0. The alpha level was set at 0.05 and 95% confidence interval (CI 95%) was calculated. Pearson’s Chi-square test was used to detect significant differences in the seropositivity between the districts, age season and health status. If the probability value (P value) is less than or equal to set alpha level (0.05) then the result was considered as statistically significant.
 
 

RESULTS AND DISCUSSION

Even though IBH-HPS has been reported in the survey zone as well as in the region, the sero-prevalence study of FAdV in this North Eastern Region of India was conducted for the first time.

During the period of study, out of a total of 460 sera samples were tested, out of which 213 (46.38%) were found positive. The spatial distribution of FAdV in different agro-climatic zones of Assam has been shown in Table 1 and Fig 2 (Dot Density Method). Highest (60%) and lowest (36.66%) sero-positivity was recorded in Kamrup (R) and Jorhat district respectively. The seroprevalence of FAdV antibodies have an insignificant association (c2= 8.4647, P=0.6711) between the districts. The increased in the prevalence of FAdV antibodies from Kamrup (R) district of Assam might be due to increased movements of poultry from in this area that could result in high rate of contact between birds.

Table 1: Sero-prevalence of fowl adenovirus antibodies in different districts of Assam.



Fig 2: Seroprevalence of Fowl adenovirus antibodies in different districts of Assam by Dot Density Method.



The study demonstrated that FAdV infection is endemic in the state on the basis of serological evidence of the virus activity in the broiler population. Since all the districts from where the samples were collected were well connected with the National Highways, so mechanical of transmission of the disease cannot be ruled out. The sub-clinically infected birds may act as a source of infection through their secretions and excretions and could pose a potential risk of virus dissemination. The preliminary findings of the present study suggested the need for strengthening the surveillance activities in large population at different districts of Assam.

Single dilution i-ELISA was found useful to screen the flock for FAdV antibodies. The test can be easily conducted, broad spectrum i.e not serotype specific and is considerably more sensitive than AGPT in early stages of infection (Philippe et al., 2007).

FAdV antibodies was observed in all age grouped birds (Table 2). Highest (64.28%) positivity was recorded in the birds of 4th week of age, followed by above 4th week (63.47%), 3rd week (32.03%), 2nd week (27.36%) and 1st week (10.0%). The seroprevalence of FAdV antibodies have significant difference (c2=89.1361, P<0.00001) among the age groups. Seroprevalence of FAdV-1 and FAdV-4 in broiler chick of < 2 weeks of age was recorded as 58.1% and 12.9% respectively by Chang and Tsai (2006), whereas Ito et al., (2007) recorded 6.5% seroprevalence in broiler chicken against serotype- 8. Rahman et al., (1997) titered the IHA antibodies against FAdV in the sera of chickens above 4th week of age. The present observations indicated that the parent stocks were not vaccinated against IBH-HPS, as no maternal antibodies against FAdV could be detected in the chicks of 1st week of age. Sero-positivity implies the picking up of infection by the birds from the premises or other risk factors associated in such situation. Immunologically, the chicks were naive against FAdV antibodies and highly susceptible to infection. Therefore the vaccination is utmost essential in these endemic areas to protect the birds from IBH-HPS.

Table 2: Seroprevalence of fowl adenovirus antibodies at different age groups.



Health status-wise 68.97 per cent sero-positivity was recorded in the affected flock, where as 32.51 per cent in apparently healthy flock (Table 3). There is insignificant association (c2=3.4784, P=0.6217) between the health groups In relation to the age group, 100 percent sero-positivity was recorded the birds of group-V i.e. above 4th weeks of age from infected flock. In apparently healthy flock, antibodies could be detected in group IV and Group V. Presence of FAdV antibodies in apparently healthy flock,indicated that the birds might be experienced the infection during their life (Hussain et al., 2003).

Table 3: Health status-wise sero-prevalence of fowl adenovirus antibodies.



The presence of the FAdV antibodies in apparently healthy birds is a suggestion that the disease might be endemic in this area but there is absence or lack of proper reporting system. Also, outbreak and clinical disease might occur but confused or mistaken for other diseases.

Season-wise, highest (61.53%) prevalence was recorded in post monsoon season followed by monsoon (49.00%), winter (32.49%) and pre-monsoon (32.39%). The seroprevalence of FAdV antibodies have significant difference (c2=68.9342, P<0.00001) among the different seasons (Table 4). Although the positive antibody titer was present in all the seasons, the occurrence of the disease could only seen in monsoon and post-monsoon. The effect of season in disease outbreak pattern was assured earlier (Yunus et al., 2009). The heavy rainfall, warm temperature and high humidity during monsoon season increased stress to the birds leading to occurrence of disease. The highest prevalence in the post monsoon season might be due to preceded infection in the monsoon season.

Table 4: Seroprevalence of fowl adenovirus antibodies in different season.

CONCLUSION

The evaluated commercial ELISA for the detection of FAdV antibodies in broiler chicken of twelve districts of Assam was successfully applied. The overall seropositivity was recorded as 46.38 per cent. The assay was found to be rapid and sensitive so that timely measures can be taken to prevent spread of the infection.

The high prevalence of FAdV antibodies suggests that the disease is endemic in the state. Since this is the first study on the prevalence of Fowl adenovirus infection, there is an urgent need of detail study with a large numbers of population throughout the state, which will be of helpful for formulation of control and eradication programmes.

ACKNOWLEDGEMENT

The authors are thankful to Dr. S.K. Das, Professor and Head, Department of Microbiology cum Principal Investigator, ADMaC (Core Lab-I), CVSc, AAU, Khanapara for financial support regarding purchase of chemicals and Kits.

Conflict of interest

The authors declared that they have no any conflict of interest.

REFERENCES


  1. Asthana, M., Chandra, R. and Kumar, R. (2013). Hydropericardium syndrome: Current status and future developments. Archives of Virology. 158(5): 921-931.

  2. Benko, M., Harrach, B and Russell, W. C. (2000). Adenoviridae, In: Virus Taxonomy: Classification and Nomenclature of Viruses. [M.H.V. van Regenmortel, C.M. Fauquet, D.H.L. Bishop, E.B. Carstens, M.K. Estes, S. M. Lemon, J. Maniloff, M.A. Mayo, D.J. McGeoch, C.R. Pringle and E.B. Wickner (ed.)], Seventh report of the International Committee on Taxonomy of Viruses. Academic Press, San Diego, California. pp 227-238.

  3. Chang, H.M. and Tsai, H.J. (2006). Isolation, characterization and prevalence of Serotype-1 and 4 Fowl Adenoviruses in chickens in Taiwan. Taiwan Veterinary Journal. 32(1): 7-16.

  4. Dutta, B., Deka, P., Gogoi, S.M., Sarmah, M., Bora, M.K. and Pathak, D.C. (2017). Pathology of Inclusion body hepatitis- Hydropericardium syndrome (IBH-HPS) in broiler chicken. International Journal of Chemical Studies. 3: 458-461.

  5. Gowda, R.N.S. and Satyanarayana, M.L. (1994). Hydropericardium syndrome in poultry. Indian Journal of Veterinary Pathology. 18: 159-161.

  6. Gupta, N., Ali, S.L. and Shakya, S. (2007). Pathology of spontaneous liver affections in chickens. Indian Journal of Animal Research. 41(4): 311-312.

  7. Helmboldt, C.F. and Frazier, M.N. (1963). Avian Hepatic inclusion bodies of unknown significance. Avian Diseases. 7: 446-450.

  8. Hussain, I., Rasool, M.H., Zahoor, M.A. and Mansoor, M.K. (2003). Indirect haemagglutination test based sero–prevalence of hydropericardium syndrome in commercial broilers. International Journal of Agriculture and Biology. 5(3): 292-294.

  9. Ito, H., Ohta, H., Nurakawa, Y., Jharanguchi, S. and Takse, K. (2007). A survey of chicken sera for antibody to fowl adenovirus serotypes 1 and 8, Isolated from Gizzard Erosion. Journal of Kagoshima University. 42: 1-4.

  10. Jaffery, M.S. (1988). A treatise on Angara disease (Hydropericardium pulmonary oedema – hepatonephritis syndrome). Journal of the Pakistan Veterinary Medical Association. 67: 1-33. 

  11. Junnu, S., Lertwathcharasarakul, P., Jala, S., Phattanakunanan, S., Monjit, P. and Songserm, T. (2014). Developing an Indirect ELISA based on Recombinant Hexon Protein for Serological Detection of Inclusion Body Hepatitis in Chickens. Journal of Veterinary Medicine Science. 76: 289-293.

  12. Kumar, R., Chandra, R. and Shukla, S.K. (2003). Isolation of etiological agent of hydropericardium syndrome in chicken embryo liver cell culture and its serological characterization. Indian Journal of Experimental Biololgy. 41: 821-26.

  13. Kumar, R., Chandra, R., Shukla, S.K., Agarwal, D.K. and Kumar, M. (1997). Hydropericardium syndrome (HPS) in India: A Preliminary study on the causative agent and control of disease by an autogenous inactivated vaccine. Tropical Animal Health and Production. 29: 158-164.

  14. Olson, N.O. (1950). A respiratory disease (bronchitis) of quail caused by a virus. Proceeding of 54th Annual Meet: US Livestock Sanit Association. pp 171-174. 

  15. Philippe, C., Grgic, H., Ojkic, D. and Nagy, E. (2007). Serologic monitoring of a broiler breeder flock previously affected by inclusion body hepatitis and testing of the progeny for vertical transmission of fowl adenoviruses. Canadian Journal of Veterinary Research. 71: 98-102.

  16. Rahman, S.U., Ashfaque, M., Anjum, A.D. and Sinfhu, T.A. (1997). Indirect Haemmagglutination test for detecting Angara disease (Hydropericardium) agent antibody. Proceedings of the International Conference and Trade Show on Poultry Production. pp 73-74.

  17. Saifuddin, M., Wilks, C.R. and Murray, A. (1992). Characterisation of avian adenoviruses associated with inclusion body hepatitis. New Zealand Veterinary Journal. 40: 52-55.

  18. Suohu, S. and Rajkhowa, T.K. (2021). Prevalence and Molecular Diagnosis of Hydropericardium Hepatitis Syndrome in the Poultry Population of Mizoram, India. Indian Journal of Animal Research. 55(1): 96-100.

  19. Trustfield, M. (1995). Sampling. In: Veterinary Epidemiology, 2nd Edition, Black Well Science Ltd., London. 179-285.

  20. Xia, J.,Yao, K.C., Liu, Y.Y., You, G.J., Li, S.Y., Liu, P., Zhao, Q., Xia, B.H., Cao, S.J.,Han, X.F. and Huang, Y. (2017). Isolation and molecular characterization of prevalent Fowl adenovirus strains in southwestern China during 2015-2016 for the development of a control strategy. Emerging Microbes and Infection. 6(11): 103.

  21. Yunus, A.W., Nasir, M.K., Aziz, T. and Bohm, J. (2009). Prevalence of poultry diseases in district Chakwal and their interaction with mycotoxicosis: Effects of season and feed. Journal of Animal and Plant Science. 19: 1-5.
Reviewed By

Download Article
In this Article
    Contact us
    Follow us

    Editorial Board

    View all (0)