EPIDEMIOLOGICAL AND MOLECULAR STUDIES ON INFECTIOUS BURSAL DISEASE VIRUS INFECTION IN LUXOR PROVINCE

Authors

1 Reference Laboratory of Veterinary Quality Control on Poultry Production (RLQP), Animal Health Institute, Luxor, Egypt.

2 Department of Poultry and Rabbit Disease, Faculty of Veterinary Medicine, South Valley University, 83523, Qena, Egypt

3 Reference Laboratory for Veterinary Quality Control on Poultry Production (RLQP), Animal Health Institute, Dokki, Giza 12818, Egypt.

Abstract

The infectious bursal disease (IBD) is a continuing serious problem facing poultry industry in Egypt. In this study, 500 bursae samples were collected from different broiler flocks in different localities of Luxor Governorate. The flocks were suffering from mortality and bursal lesions during Dec.2014 to Jan. 2016. The samples were tested by AGPT and the result was 12 flocks only were positive for IBD and then the positive samples were isolated in SPF embryonated chicken eggs. All the inoculated embryos died within 2-3 days. The embryos were smaller than normal, congested with haemorrhagic head, and necrotic foci of liver. Then the presence of virus in embryonated eggs was confirmed by convential PCR. Furthermore, molecular characterization was performed by direct sequencing of a 620-bp cDNA corresponding to the VP2 variable domain of the polyprotein gene synthesized by PCR. With deduced amino acid analysis found that all examined isolates are very virulent strains. four local strains used for nucleotide sequence, percent identity and phylogenetic tree analysis revealed that four isolates (F21,F23,F24,F26) were very close to very virulent old Egyptian strains Giza 2008

Keywords


Assiut University web-site: www.aun.edu.eg

 

EPIDEMIOLOGICAL AND MOLECULAR STUDIES ON INFECTIOUS BURSAL DISEASE VIRUS INFECTION IN LUXOR PROVINCE

 

ENAS M. IBRAHIM1; NABILA OSMAN2; AHMED I. AHMED2 and SOAD A. NASEF3

1 Reference Laboratory of Veterinary Quality Control on Poultry Production (RLQP), Animal Health Institute, Luxor, Egypt.

2 Department of  Poultry and Rabbit Disease, Faculty of Veterinary Medicine, South Valley University, 83523, Qena, Egypt.

3 Reference Laboratory for Veterinary Quality Control on Poultry Production (RLQP), Animal Health Institute, Dokki, Giza 12818, Egypt.

 

Received: 2 February 2017;       Accepted: 27 February 2017

 

 

ABSTRACT

 

The infectious bursal disease (IBD) is a continuing serious problem facing poultry industry in Egypt. In this study, 500 bursae samples were collected from different broiler flocks in different localities of Luxor Governorate. The flocks were suffering from mortality and bursal lesions during Dec.2014 to Jan. 2016. The samples were tested by AGPT and the result was 12 flocks only were positive for IBD and then the positive samples were isolated in SPF embryonated chicken eggs. All the inoculated embryos died within 2-3 days. The embryos were smaller than normal, congested with haemorrhagic head, and necrotic foci of liver. Then the presence of virus in embryonated eggs was confirmed by convential PCR. Furthermore, molecular characterization was performed by direct sequencing of a 620-bp cDNA corresponding to the VP2 variable domain of the polyprotein gene synthesized by PCR. With deduced amino acid analysis found that all examined isolates are very virulent strains. four local strains used for nucleotide sequence, percent identity and phylogenetic tree analysis revealed that four isolates (F21,F23,F24,F26) were very close to very virulent old Egyptian strains Giza 2008.

 

Key Words: IBDV; PCR; VP2; Pathotyping

 

 

 

INTRODUCTION

 

Infectious bursal disease (IBD) is an acute highly contagious viral disease of young birds characterized mainly by sever lesions in bursa of fabricious and immunosuppression in chickens (Eterradossi and Saif, 2008).

 

Infectious bursal disease has a great concern in Egyptian poultry industry for a long time but particularly for the past decade. Infectious bursal disease virus is a member of the genus Birnavirus family Birnaviridae which has the potential of immunizing the chicks even in the presence of moderately higher levels of maternally derived antibodies (MDA) (Delmas et al., 2011). Firstly reported as severe kidney lesions; later it was termed as Infectious Bursal Disease virus (IBDv) referring to the specific lesions caused by the disease in the bursa of fabricious, and severe renal damages (Eterradossi and Saif, 2008).

 

 

 
   
 

 


Corresponding author: Dr. ENAS M. IBRAHIM

E-mail address:enas_vet2017@yahoo.com

Present address: Reference Laboratory of Veterinary Quality Control on Poultry Production (RLQP), Animal Health Institute, Luxor, Egypt.

The IBDV genome has two segments designated A and B segments A (3.4 kb) and B (2.8kb). The segment A encodes 4 viral proteins, the two capsid proteins VP2 (48 kDa) and VP3 (32 -35 kDa) and viral protease VP4 (24 kDa) and nonstructural protein VP5 (17-21 kDa). The smaller segment B encodes RNA-dependent RNA polymerase VP1 (90 kDa) (Xu et al., 2011).

 

Infectious bursal disease virus (IBDV) infection destroys the bursa of Fabricius, causing immunosuppression and rendering chickens susceptible to secondary bacterial or viral infections(Lee et al., 2015).

 

Sever acute disease of 3-6 week-old birds is associated with high mortality, but a less acute or subclinical disease is common in 0-3-week-old birds. This can cause secondary problems due to its effect on the bursa of Fabricius. IBD virus (IBDV) causes lymphoid depletion of the bursa, and if this occurs in the first 2 weeks of life, significant depression of the humeral antibody response may result. Two distinct serotypes of infectious bursal disease virus (IBDV) are known to exist. Serotype 1 virus causes clinical disease in chickens younger than 10 weeks. Older chickens usually show no clinical signs. Antibodies are sometimes found in other avian species, but no signs of infection are seen. Serotype 2 antibodies are very widespread in turkeys and are sometimes found in chickens and ducks. There are no reports of clinical disease caused by infection with serotype 2 virus(Lasher and Shane, 1994).

 

In spite of the most commercial broiler chicken flocks that are vaccinated against IBD, severe outbreaks were reported in Egypt, caused high mortalities, and have become a priority problem (El-Batrawi, 1990 and Bekhit, 1998).

 

MATERIALS AND METHODS

 

1. Field samples

Five hundred (n=500) samples were collected from fifty commercial poultry flocks (3-6 weeks of age) in different localities of Luxor governorate during the period (December 2014 to January 2016) suspected of having IBD. Post mortem examination was performed on a variable number of freshly dead birds which succumbed to the disease after onset of mortalities on the examined farm, Gross lesions were recorded from birds with typical IBD lesions.

2. Detection of IBDV antigen in bursal homogenates by AGPT

Pooled bursal homogenates were prepared from the affected chicken farm  and were checked by the AGPT, using reference IBD serotype 1 antiserum, and known reference positive and negative bursal homogenates antigen as control were performed. Reaction appeared as 2-3 precipitation lines within 48 hours after setting the test.

 

3. Isolation of IBDV using egg inoculation by CAM route

All positive samples from AGPT were isolated in SPF ECE via CAM route. The inoculated embryos showed 100% mortalities within 3 days.

 

4. Confirmation of positive Isolates from egg inoculation by Convential PCR:

All isolated positive samples were confirmed for presence of IBDV using convential PCR. RNAs were extracted from the bursal homogenates using QIAamp Viral RNA Mini Kit (Qiagen, Valencia, Calif. USA) according to the manufacturer's instruction.

 

 

A set of primers were used for RT-PCR reaction using forward and reverse PCR primer

 

Forward primer

AUS GU:5’TCA CCG TCC TCA GCT TAC CCA CAT C-3'

Reverse primer

AUS GL5’GGA TTT GGG ATC AGC TCG AAG TTG C-3;

 

- Reverse Transcriptase-Polymerase Chain Reaction (RT-PCR): using Qiagen one step RT-PCR Kit. (According to the manufacturer's instruction).

 


- Agarose Gel Electrophoresis

 

The PCR products were inoculated in 1.5 % agarose gel placed in the electrophoresis chamber and covered with electrolyte solution in I X TBE buffer with allowing running the PCR product in the gel at constant volt for 40 minute, to determine the base pairs of the PCR product which could be visualized by the presence of marker (Qiagen) Gene ruler 100 bp plus DNA ladder and using Gel documentation system.

 

5. Sequence for the purified PCR product:

Gel containing DNA band of the expected size (620 bp) was excised and purified with the QIA quick Gel Extraction Kit (Qiagen) according to the manufacturer instruction. The purified PCR products were sequenced directly using the ABI PRISM. Big Dye TM Terminators v3.1 Cycle Sequencing Kit (Applied Biosystems,  Foster city, CA,USA), The products of the sequencing reactions were cleaned –up using Centrisep purification kit Analyzer (Applied Biosystems, Foster city, CA,USA) and the purified products were sequenced directly using the ABI (Applied Biosystems, Foster city, CA,USA) and the ABI PRISM 3130 genetic analyzer (Applied Biosystems).

 

The phylogram was drawn using MEGA 5 software. The alignment of the viruses in the study was done using DNA star – Meg Align software. Egyptian viruses and other international reference strains from the Genbank were available from the National Center for Biotechnology Information (NCBI). Finally the identity percent and divergence between all viruses was carried out.

 

RESULTS

 

1. Detection of IBDV antigen in bursal homogenates by AGPT: The result recorded twelve farms out of fifty farms were positive for IBD by AGPT.

 

2. Isolation of IBDV using egg inoculation by CAM route: The result of isolation revealed ten farms were positive for virus isolation.

3. Confirmation of positive samples from inoculation by convential PCR:

The presence of virus in embryonating eggs was confirmed by convential PCR. All PCR positive samples showed specific bands at 620 bp on agarose gel.Fig 1.


 

 

Figure 1: Gel electrophoresis of RT-PCR showing 620 bpbands in the positive samples.

 


4. Phylogenetic characterization

Phylogenetic tree of Nucleotide sequences of VP2 gene: There were four new Egyptian isolates (F21, F23, F24, F26) characterized as very virulent and were very close to old Egyptian viruses Giza 2008.Fig 2.

 

Four  samples were selected from positive isolates for sequencing (F 21, F 23, F 24, F 26) .And a sequence of 33 nucleotides were used for nucleotides analysis and deduced amino acid analysis. Sequence analysis and comparison of 620 bp of the hypervarible region of VP2 for the four local isolates with various reference IBD strains revealed that F 21,F 23, F 24, F26 are very virulent and  more closer to The Egyptian VVIBDV strain (Giza 2008). F21 had a highest nucleotide identity to VVIBDV strain Giza 2008 (91.1 %). F 23 had a highest nucleotide identity to VVIBDV strain Giza 2008 (92 %). F 24 had a highest nucleotide identity to VVIBDV strain Giza 2008 with Percentage (85.7%). F 26 had a highest nucleotide identity to VVIBDV strain Giza 2008 with percentage (89.3%). Fig 3.


 

Figure 2: Phylogenetic analysis tree of the studied IBDV strains (F 21, F23, F24, F26) and other references classical, very virulent, variant and vaccine strains of IBDV.

 

 

 

Figure 3: The similarity between IBDV isolates and other Egyptian and representative reference strains.

 


DISCUSSION

 

The clinical signs include sudden onset, ruffled feathers, prostration, diarrhea, and death. Disseminated muscular hemorrhages, the kidneys were swollen and enlargement with edema in BF, sometimes with bloody exudates were observed at postmortem examination. Our results were agreed with (Paula et al., 2004; Richard and Miles, 2004; Okoyo and Uzonkwu, 2005 and Rajaonarison et al., 2006).

 

Ten farms were positive from fifty farms with percentage 20%, these similar tothe results of Roussan et al. (2012) that used 80 bursa fabricius samples were examined from 20 commercial broiler chicken flocks in Jordan with clinical symptoms of IBD. However, 20%of local IBDV strains were positive using a specific primer for vvIBDV. While Jackwood and Nielsen. (1997) revealed only 48 bursal samples out of 151 collected from the United States, Mexico, and Puetro Rico were detected to contain IBDV using RT-PCR assay.

 

In the present investigated outbreak, IBD was laboratory diagnosed, based on the demonstration of IBDV antigens (s) by the AGPT in bursal homogenates from fresh, acutely affected birds, which appeared as precipitation line. The successful use of the AGPT as a rapid diagnostic means for IBDV antigen detection in the bursa of acutely affected birds have been previously reported by Rosenberger et al. (2008).

 

Trial to isolate IBDV from AGPT- positive samples of bursal homogenates by chicken embryo inoculation via CAM in 10 days SPF embryonated chicken eggs resulted in embryo deaths during -5 days pi, associated with typical gross embryonic lesions recorded by Rosenberger et al. (2008).

 

In present study all ten positive homogenate samples from AGPT inoculated in chorioallantoic membrane (CAM) of 10 days SPF embryonated chicken eggs showed embryo lesions, they were  typical characteristic to IBDV infection (edema, distention of abdominal region, cutaneous congestion, mottled necrosis and ecchymotic hemorrhages on the liver).Similar lesions were recorded by (Lukert, 1992andAmer et al., 2007).

 

All positive samples from isolation were confirmed by convential PCR given amplicon size 620bp in the hyper variable region of the VP2 gene. (Fig1). These similar to result by Naglaa et al. (2015) that isolated IBDV from chicken broiler farms in different Egyptian Governorates and all isolated IBDV subjected to molecular detection by RT-PCR which showed amplification of a 620 bp fragment. The similar result were obtained by Mohammed (2013) who isolated IBDV from south valley area and the result by RT-PCR showed positive reaction and giving amplicon size at 620bp. These similar result were obtained by Metwally et al. (2009) who reported that bursa and proventriculus samples were RT-PCR tested using novel primers flanking VP2 region coding the two major and two minor hydrophilic peaks produced amplicons size 620bp.

 

Nucleic acid-based methods are useful tools for direct detection and sub typing without isolation and propagation (Stram et al., 1994). Reverse transcription polymerase chain reaction (RT- PCR) techniques on selected fragments of the genome, essentially the variable domain of VP2 followed by sequencing and phylogenetic comparison represents a valuable molecular alternative for the classification of IBDV strains (Van Den Berg., 2000). The significance of VP2 molecular analysis stems from that VP2 is responsible for virulence and pathogenicity (Garriga et al., 2006) as well as antigenic variations (Letzel et al., 2007). The VP2 gene is commonly studied because it encodes for the major protective epitopes, contains determinants for pathogenicity, and is highly variable among strains (Abdel-Alim, 2003; Jackwood and Sommer-Wanger, 2006).

 

A 620bp product was generated from an infected bursa, using simplified RNA extraction procedure and RT-PCR. It was used as template for automated sequencing. Ncleotide sequences of the hypervariable region of the VP2 gene of isolates. The examined isolates showed similarity and identity ranged from 92% to 85.7% with other reference (very virulent, classical and variant) strains. These results agree with (Kataria et al., 2001) who reported that none of the Indian isolates were 100% similar, But Kasanga et al. (2007) reported 17 nucleotides differences among 14 Tanzanian IBDVs sequences. Three of this sequence (KARS-53, KDSM-32 and KMRG-46) were identical even though they were isolated in different years and places and the other 11 were different from each other. The hyper variable region of the VP2 was chosen for our study because it has been shown to mutate frequently. Using more conserved regions of the genome for comparison of the isolates would not allow us adequate discrimination among the strains. Antigenic and molecular analysis of this part of the protein helped in understanding the nature and behavior of the isolated strains (Zierenberg et al., 2000).

 

The nucleotide sequence of the VP2 hypervaraible region of our four examined strains was compared with different reference strains and revealed that (F 21, F 23, F 24, F 26) more identity to Egyptian very virulent IBDVs (Giza 2008). F 21 revealed highest identity (91.1%) to Giza 2008. F 23 had highest nucleotide identity (92%) to Egyptian very virulent IBDV (Giza 2008). Also F 24 and F 26 had identity to Giza 2008 (85.7 % - 89.3%).

 

In this study phylogenetic tree showed that our isolated field viruses (F 21, F23, F24, F26) were close to each other and also were close to old Egyptian virus Giza 2008.

 

REFERENCES

 

Abdel-Alem, G.A; Awaad, M.H.H. and Saif, Y.M. (2003): Characterization of Egyptian field strains of infectious bursal disease virus. Avain Dis 47:1452-7.

Amer, M.M.; El-Bayomi, K.M.; Abd-A. Kotkat, M.;Waffa, A.; Abdel-Ghany; Shakal, M.A and Sherein, S. Abdel-Gaied (2007): Isolation, molecular characterization and pathogenicity studies of infectious bursal disease field virus isolates. BS.VET.MED.J.

Bekhit, A.B. (1998): Acute infectious bursal disease in poultry, isolation of very virulent strains, Alexandria Journal of veterinary Sciences, 11,pp.475-483.

Delmas, B.; Mundt, E.; Vakharia, V.N. and WU, J.L. (2011): Family birnaviridae. In: King, A.M.Q., Lefkowitz, E., Adams, M.J., Carstens, E.B. (Eds) Virus Taxonomy Ninth Report of the International Committee on Taxonomy of Viruses. Academic press Inc., San Diego, California: 499-07.

El-batrawi, A.M. (1990): Studies on sever outbreaks of infectious bursal disease. I. the natural and expremental disease. Proceedings 2nd scintefic conference of the Egyptian vetrenery poultry association. 12-14 march, Cairo: 239-252.

Eterradossi, N. and Saif,Y.M. (2008): Infectious bursal disease In: Saif, Y.M., Fadly, A.M., Glisson, J.R., McDougald, L.R., Nolan, L.K., Swayne, D.E. (Eds), Disease of Poultry, 12th ed. Black well Publishing, 185-208. Ames Iowa,USA.

Garriga, D.; Querol. Audi, J.; Abaitua, F.; Saugar, I.; Pous, J.; Verdaguer, N.; Caston, J.R. and Rodriguez, J.F. (2006): The 2.6 angstrom structure of infectious bursal disease virus derived T=1 particles reveals new stabilizing element of the virus capsid.j.virol.80:6895-6905.

Jackwood, D.J. and Nielson, C.K. (1997): Detection of infectious bursal disease viruses in commercially reared chickens using the reverse transcription polymerase chain reaction restriction endonuclease assay. Avian Dis.41:137-143.

Jackwood, D.J. and Sommer-Wanger, S. (2006): Molecular studies on suspect very virulent infectious bursal disease virus genomic RNA samples. AvainDisease, 49(2): 246-251.

Kasanga, C.J.; Yamaguchi, T.; Wambura, P.N.; Maeda-Maching'u, A.D.; Ohya, K. and Fukushi, H. (2007): Molecular characterization of infectious bursal disease virus (IBDV): Diversity of Very virulent IBDV in Tanzania. Arch Virol.152:783-790.

Kataria, R.S.; Tiwari, A.K.; Butchaiah, G.; Kataria, J.M. and Skinner, M.A. (2001): Sequence analysis of the VP2 gene hypervariable region of infectious bursal disease viruses from India. Avian Path. 30: 501-507.

Lasher, H.N. and Shane, S.M. (1994): Infectious Bursal Disease World's Poultry Science Journal, 50:133-166.

Lee, C.C.; Kim, B.S.; Wu, C.C.; Lin, T.L. (2015): Bursal transcriptome of chickens protected by DNA vaccination versus those challenged with infectious bursal disease virus. Archives of Virology; 2015. 160(1):69-80. 49 ref. Austria.

Letzel, T.F.; Coulibaly, F.A.; Rey, B.; Delmas, E.; Jagt, A.; Van Loon, and Mundt, E. (2007): Molecular and structural bases for the antigenicity of VP2 of infectious bursal disease virus. j.virol.81: 12827-12835.

Lukert, P.D. (1992): A history of an IBD Vaccine.Select laboratories Interlink 1: pp.2 and 4.

Metwally, A.M.; Youssif, A.A.; Shaheed, I.B.; Mohammed, W.A.; Samy, A.M. and Reda, I.M. (2009): Re-Emergence of very virulent IBDV in Egypt. International Journal of Virology, 5 (1):1-17.

Mohammed, A.S. (2013): Molecular characterization of infectious bursal disease virus isolates from chicken in south valley, Thesis, faculty of vet med, south valley university.

Naglaa, M.H.; Mohamed, A.S.; Abdel Satar, A.; Ali, Z.; Ahmed, M.E. and Mohamed, K.H. (2015): Genetic characterization of infectious bursal disease virus in EGYPT from 2012 to 2014. Assiut Vet. Med. J. Vol.61 No.147.

Okoye, J.O.A. and Uzoukwu, M. (2005): An outbreak of infectious bursal disease among chickens between 16 and 20 weeks old. Avian Dis. (25). 4: 1034-1038.

Paula, M.B.C.; Yokosawa, J.; Cout_Nho, M.D.; Silva, P.L.; Ferrez, R.A.; Oliverira, T.F. and QuirOz, D.A. (2004): Identification and molecular characterization of infectious bursal disease virus (IBDV) from an outbreak in a broiler flock in med western branch

Ragaonarison, J.J.; Rakotonindrina, S.M.; Rakotondramary, E.K. and Razafimangary, S. (2006): Gumboro diseased (infectious bursitis) in Madagascar. Rev Elev Med Vet Pays Trop.47(1):15-17.

Richard and Miles. (2004): Department of Dairy and Poultry Science, Cooperative Extension Service, IFAS, University of Florida, Gainesville-32616.

Rosenberger, J.K.; Saif, Y.M. and Jackwood, D.J. (2008):  Infectious bursal disease. In: A Laboratory Manual for The Isolation, Identification and characterization of avian pathogens. Fifth edition. American Association of Avian Pathologists: 188-190.

Roussan, D.A.; Al-Saleh, A.; Khawaldeh, G.Y. and Totanji, W.S. (2012): Characterization of infectious bursal disease virus field strain in Jordan using molecular techniques- ashort communication. VETERINARSKI ARHIV 82 (1), 115-124.

Stram, Y.; Meir, R.; Molad, Team; Blumenkrenz, R.; Malkinson, M. and Weismann, Y. (1994): Application of the polymerated chain reaction to detect infectious bursal disease virus in natural infected chicken. Avaindisease. 38: 879-884.

Van den berg, T.P. (2000): Acute infectious bursal disease in poultry: a review. Avian Pathology. 29: 175-194.

Xu, X.G.; Tong, D.W.; Wang, Z.S.; Zhang, Q.; Li, Z.C.; Zhang, K.; Li, W. and Liu, H.J. (2011): Baculovirus virions displaying infectious bursal disease virus VP2 protein protect chickens against infectious bursal disease virus infection . Avain disease 55 (2), 223-9.

Zierenberg, K.; Nieper, H.; Van den Berg, T.P.; Ezeokoli, C.D.; VoB, M. and Muller, H. (2000): The VP2 variable region of African and German isolates of infectious bursal disease: comparison with virulent, ''classical'' virulent, and attenuated tissue culture adapted strains. Archives of Virology; 145, 113-125.

 

 

دراسات وبائية وجزيئية علي مرض التهاب کيس فبريس المعدي في محافظة الأقصر

 

إيناس محمد إبراهيم , نبيلة عثمان ، أحمد إبراهيم , سعاد عبد العزيز ناصف

 

Email: enas_vet2017@yahoo.com         Assiut University web-site: www.aun.edu.eg

 

يعتبر مرض التهاب جراب فابريشيا مشکله خطيرة مستمرة تواجه صناعه الدواجن في مصر. وخلال هذه الدراسة تم فحص 500 عينه جراب فابريشيا من أصل خمسين مزرعة تم جمعها من مناطق مختلفة في محافظه الأقصر کانت تعاني من وفيات وإصابة في جراب فابريشيا وذلک في الفترة من ديسمبر 2014 إلي يناير 2016 وتم اختبار العينات بواسطة اختبار الترسيب في الأجار وکانت النتيجة 12 مزرعة ايجابيه وتم عزل العينات الايجابية الناتجة من اختبار الترسيب في الأجار عن طريق الحقن في الاجنه وکانت الإصابات الملحوظة عبارة عن نزيف في الرأس , ارتشاح مائي محيط بالجنين , احتقان ونزف علي القدمين والمناطق الدماغية وعلي الکبد وکانت الوفيات بنسبه 100%. وتم تأکيد وجود الفيروس في أجنة البيض المحقونة بواسطة تفاعل إنزيم البلمره التسلسلي, علاوة علي ذلک تم إجراء التوصيف الجزيئي بواسطة التسلسل المباشر 620 زوج من القاعدة في المنطقة شديدة التغير في جزيء البروتين الثاني للفيروس. وأشار تحليل تسلسل استخلاص الحمض الاميني من الجين في جزيء البروتين الثاني أن جميع المعزولات التي فحصها بين سلالات IBDV شديدة الضراوة. وکشفت الأربع سلالات المحلية المستخدمة لتسلسل النيوکليتيدات ونسبه التقارب وتحليل شجرة النشوء والتطور أن الأربع معزولات ((F21,F23,F24,F26 کانت قريبه جدا من السلالة المصرية شديدة الضراوة جيزة 2008 .

 
 
Abdel-Alem, G.A; Awaad, M.H.H. and Saif, Y.M. (2003): Characterization of Egyptian field strains of infectious bursal disease virus. Avain Dis 47:1452-7.
Amer, M.M.; El-Bayomi, K.M.; Abd-A. Kotkat, M.;Waffa, A.; Abdel-Ghany; Shakal, M.A and Sherein, S. Abdel-Gaied (2007): Isolation, molecular characterization and pathogenicity studies of infectious bursal disease field virus isolates. BS.VET.MED.J.
Bekhit, A.B. (1998): Acute infectious bursal disease in poultry, isolation of very virulent strains, Alexandria Journal of veterinary Sciences, 11,pp.475-483.
Delmas, B.; Mundt, E.; Vakharia, V.N. and WU, J.L. (2011): Family birnaviridae. In: King, A.M.Q., Lefkowitz, E., Adams, M.J., Carstens, E.B. (Eds) Virus Taxonomy Ninth Report of the International Committee on Taxonomy of Viruses. Academic press Inc., San Diego, California: 499-07.
El-batrawi, A.M. (1990): Studies on sever outbreaks of infectious bursal disease. I. the natural and expremental disease. Proceedings 2nd scintefic conference of the Egyptian vetrenery poultry association. 12-14 march, Cairo: 239-252.
Eterradossi, N. and Saif,Y.M. (2008): Infectious bursal disease In: Saif, Y.M., Fadly, A.M., Glisson, J.R., McDougald, L.R., Nolan, L.K., Swayne, D.E. (Eds), Disease of Poultry, 12th ed. Black well Publishing, 185-208. Ames Iowa,USA.
Garriga, D.; Querol. Audi, J.; Abaitua, F.; Saugar, I.; Pous, J.; Verdaguer, N.; Caston, J.R. and Rodriguez, J.F. (2006): The 2.6 angstrom structure of infectious bursal disease virus derived T=1 particles reveals new stabilizing element of the virus capsid.j.virol.80:6895-6905.
Jackwood, D.J. and Nielson, C.K. (1997): Detection of infectious bursal disease viruses in commercially reared chickens using the reverse transcription polymerase chain reaction restriction endonuclease assay. Avian Dis.41:137-143.
Jackwood, D.J. and Sommer-Wanger, S. (2006): Molecular studies on suspect very virulent infectious bursal disease virus genomic RNA samples. AvainDisease, 49(2): 246-251.
Kasanga, C.J.; Yamaguchi, T.; Wambura, P.N.; Maeda-Maching'u, A.D.; Ohya, K. and Fukushi, H. (2007): Molecular characterization of infectious bursal disease virus (IBDV): Diversity of Very virulent IBDV in Tanzania. Arch Virol.152:783-790.
Kataria, R.S.; Tiwari, A.K.; Butchaiah, G.; Kataria, J.M. and Skinner, M.A. (2001): Sequence analysis of the VP2 gene hypervariable region of infectious bursal disease viruses from India. Avian Path. 30: 501-507.
Lasher, H.N. and Shane, S.M. (1994): Infectious Bursal Disease World's Poultry Science Journal, 50:133-166.
Lee, C.C.; Kim, B.S.; Wu, C.C.; Lin, T.L. (2015): Bursal transcriptome of chickens protected by DNA vaccination versus those challenged with infectious bursal disease virus. Archives of Virology; 2015. 160(1):69-80. 49 ref. Austria.
Letzel, T.F.; Coulibaly, F.A.; Rey, B.; Delmas, E.; Jagt, A.; Van Loon, and Mundt, E. (2007): Molecular and structural bases for the antigenicity of VP2 of infectious bursal disease virus. j.virol.81: 12827-12835.
Lukert, P.D. (1992): A history of an IBD Vaccine.Select laboratories Interlink 1: pp.2 and 4.
Metwally, A.M.; Youssif, A.A.; Shaheed, I.B.; Mohammed, W.A.; Samy, A.M. and Reda, I.M. (2009): Re-Emergence of very virulent IBDV in Egypt. International Journal of Virology, 5 (1):1-17.
Mohammed, A.S. (2013): Molecular characterization of infectious bursal disease virus isolates from chicken in south valley, Thesis, faculty of vet med, south valley university.
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