Attenuation of very virulent infectious bursal disease virus and comparison of full sequences of virulent and attenuated strains.

A very virulent strain of infectious bursal disease virus (IBDVks) was isolated from the bursae of Fabricius of IBDV-affected broiler chickens. Following 43 serial passages in specific pathogen-free embryonated eggs, an attenuated strain was established (IBDVmb). Dosages of IBDVmb in the range 10(2) to 10(4) embryo infective dose of 50% were found to be safe and protective for commercial chicks. Chickens vaccinated with live vaccine containing IBDVmb responded with precipitating and type-specific neutralizing antibodies, and were immune to subsequent challenge with a very virulent IBDV. IBDVmb has been used as an attenuated vaccine throughout the world since 1993. A comparison of the full sequences of the virulent and attenuated strains (IBDVks and IBDVmb, respectively) revealed seven nucleotides that were different, four of them leading to changes in the amino-acid sequence. Comparison of the protein sequence of these strains and published sequences of very virulent and attenuated phenotypes lead us to suggest that the novel difference responsible for virulence of the Israeli strains are: residue 272 (VP2, very conserved site) and residue 527 (VP4), both in segment A, and in segment B (VP1) residues 96 and 161 (both conserved). Our study strengthens the possibility that more than one protein is involved in IBDV attenuation. In all reports, including ours, virulence was reduced without affecting antigenicity of the neutralizing epitopes in VP2. This could have practical implications for attenuated-vaccine development.

Production and purification of melanoma gp100 antigen and polyclonal antibodies.

gp100 is a melanoma-associated antigen found to carry immunogenic epitopes that can induce a CTL response against tumor cells. Production and purification of large quantities of this polypeptide may be important in the context of diagnosis and vaccinating against melanoma. To overcome the hydrophobic nature of gp100, we cloned and expressed only a part of the protein, and obtained a hydrophilic recombinant polypeptide (HR-gp100) that contained most of the immunogenic peptides. High yield was achieved in an Escherichia coli expression system. The protein was purified by AKTA Prime using anionic-columns. Polyclonal antibodies developed in chicken against HR-gp100 were efficient at detecting gp100 in melanoma cells, as determined by Western blot analysis and by immunohistochemistry. HR-gp100 can be used to develop a vaccine against melanoma. Antibodies to HR-gp100 may be used to detect tumors of melanocytic origin or to determine the level of gp100 expression in tumors prior to immunotherapy with the protein or one of its peptides.

Storage of viruses on filter paper for genetic analysis.

The purpose of this study was to develop a method to store viruses on filter paper without the need for special conditions for future use of the genetic material. Two non-enveloped viruses were used as models. Infectious bursal disease virus (IBDV), a double-stranded RNA virus that infects chickens, belongs to the Birnaviridae family. Hemorrhagic enteritis virus (HEV), with double-stranded DNA, belongs to the Adenoviridae family. Three different solutions were found suitable for loading the virus. The viruses were stored at room temperature or at 37 degrees C for periods of 5-30 days. Direct reverse transcription-polymerase chain reaction (RT-PCR) (without previous extraction of the RNA) was carried out on filter paper loaded with IBDV, and fragments of the expected size were detected. HEV DNA was extracted from filter paper loaded with purified virus or crude tissue. PCR fragments were found to be of similar intensity to those of control virus that was kept in a tube at -20 degrees C. This method permits the storage and transport of viruses from the field or from clinics to a regional laboratory or any laboratory elsewhere, without the need for prior treatment or special environmental conditions.

Failure of viral protein 3 of infectious bursal disease virus produced in prokaryotic and eukaryotic expression systems to protect chickens against the disease.

In recent years, infectious bursal disease virus (IBDV) has become a serious economic problem as a result of the emergence of new and very virulent strains. Most of the antibodies produced against IBDV are for the structural proteins viral protein (VP) 2 (VP2) and VP3. The purpose of this study was to test the potential of recombinant VP3 to induce protective antibodies. The gene for VP3 was isolated from a virulent strain of the virus and cloned into prokaryotic (Escherichia coli) and eukaryotic (baculovirus) expression systems. The protein expressed by both systems was of the expected size (32 kD) and was detected by anti-IBDV antibodies. Following partial purification, the polypeptides were injected into intact birds and induced the production of high levels of anti-IBDV antibodies, as detected by immunoblot and enzyme-linked immunosorbent assay tests. These antibodies did not prevent changes in the bursa and mortality when birds were challenged with a virulent IBDV strain after vaccination with the recombinant VP3. The results show that VP3 polypeptide cannot be used as a subunit vaccine against IBDV and raise questions concerning the nature of the neutralizing epitope on this structural protein.

Coding region of segment A sequence of a very virulent isolate of IBDV--comparison with isolates from different countries and virulence.

We determined the sequence of the coding region of segment A, coding for the viral proteins (VPs) VP2, VP4, and VP3, of a very virulent (vv) infectious bursal disease virus (IBDV) isolated in Israel and named IBDVks. We compared the deduced amino acid sequences of the proteins of the new isolate with those of the same proteins from several IBDV isolates, as published in recent years. The amino acid sequences of VP3 and VP4 of the Israeli isolate were 1.9%-2.3% different from the sequences of their counterparts from classical strains. Thus, the stable region of VP2 of IBDVks was very similar (0-0.68% difference) to the same region of VP2 from vv strains from Europe and Japan but distinct from that of proteins from classical strains from Europe, the United States, and Australia (up to 9.42% divergence), showing that IBDVks is more closely related to the vv strains from Europe and Japan. We found that viruses isolated in recent years resemble each other more than isolates from the same areas isolated a few years earlier. Hence, IBDVks can be categorized in one group with vv new isolates from Europe and Japan. This group has been found to be distinct from new isolates in the United States and strains isolated before the IBDV epidemic during the late 1980s.

The complete DNA sequence and genome organization of the avian adenovirus, hemorrhagic enteritis virus.

Hemorrhagic enteritis virus (HEV) belongs to the Adenoviridae family, a subgroup of adenoviruses (Ads) that infect avian species. In this article, the complete DNA sequence and the genome organization of the virus are described. The full-length of the genome was found to be 26,263 bp, shorter than the DNA of any other Ad described so far. The G + C content of the genome is 34.93%. There are short terminal repeats (39 bp), as described for other Ads. Genes were identified by comparison of the DNA and predicted amino acid sequences with published sequences of other Ads. The organization of the genome in respect to late genes (52K, IIIa, penton base, core protein, hexon, endopeptidase, 100K, pVIII, and fiber), early region 2 genes (polymerase, terminal protein, and DNA binding protein), and intermediate gene IVa2 was found to be similar to that of other human and avian Ad genomes. No sequences similar to E1 and E4 regions were found. Very low similarity to ovine E3 region was found. Open reading frames were identified with no similarity to any published Ad sequence.

Identification of a starting point of breast skin tears during chicken plucking.

A site (STP) was identified on the skin of the chicken, during defeathering in the slaughter house, at which about 90% of breast skin tears started. This site is on the ventral side of the pectoral tract area. There was no difference in location of this site with respect to different commercial lines, sexes, flocks, or time of the day. In order to demonstrate the importance of a small skin tear to ultimate damage, defeathered chickens with a minor tear at a particular site and undamaged defeathered chickens were passed through the defeathering machine a second time. Thirty-six percent of the STP chickens were torn further, but only a small percentage (about 4%) of the undamaged chickens were harmed.

Insect cell-derived VP2 of infectious bursal disease virus confers protection against the disease in chickens.

Infectious bursal disease virus (IBDV) has become a major problem in recent years. Conventional vaccines make use of attenuated or inactivated viral strains, but these are gradually losing their effectiveness. We investigated the possibility of using purified VP2, a subunit of IBDV structural protein expressed in insect cells, as a vaccine. The VP2 gene was cloned into pAcYM1. The cloned gene was expressed in a baculovirus system, giving rise to a high quantity of recombinant VP2 (rVP2) protein. The length of the VP2 is 453 amino acids, and it contains two additional amino acids of the baculovirus at the carboxyl terminus. The molecular mass of the protein is about 48 kD. The rVP2 protein reacted with antibodies raised against viral VP2 and had a similar molecular weight. This protein was tested in a controlled vaccination experiment and compared with an inactivated commercial vaccine. High levels of antibodies were raised by the vaccinated birds. The vaccinated birds were challenged with a pathogenic viral strain. rVP2-vaccinated chickens exhibited high resistance to the virus. No mortality or weight changes in the bursa of Fabricius were observed in the vaccinated birds, whereas in the negative control birds, vaccinated with phosphate buffer, up to 50% mortality was found. Higher levels of antibodies were found by enzyme-linked immunosorbent assay in birds vaccinated with rVP2 compared with those vaccinated with the commercial vaccine. This study suggests the potential use of the isolated rVP2 as a subunit vaccine.