Development of an antigen-capture ELISA for beak and feather disease virus.

Psittacine beak and feather disease (PBFD) is characterised by degenerative feather, feather dystrophy, and beak deformity. Sometimes acute forms can lead to fatal cases in nestlings. The worldwide distribution of this disease affects numerous species of parrots with an average prevalence of 40%, including in Taiwan. The pathogen of PBFD is beak and feather disease virus (BFDV), which is a single-stranded circular DNA virus, circovirus. To date, hemagglutination and PCR assays have been routinely used to detect this virus. In this study, both the replication-associated protein (Rep) and the structural capsid protein (Cap) were expressed and then used as antigens for the production of monoclonal antibodies. Conserved epitopes recognised by the anti-Cap and anti-Rep monoclonal antibodies were determined to be NFEDYRI and LSALKKM, respectively. Clinical samples collected from different species of parrots were tested by hemagglutination, PCR, and anti-Cap antigen-capture ELISA assays and the positive rates were the same at 49%. Thus, this anti-Cap antigen-capture ELISA is able to be used for the rapid identification of BFDV-infected birds in a non-invasive manner.

The phylogenetic and recombinational analysis of beak and feather disease virus Taiwan isolates.

Beak and feather disease virus (BFDV) is an avian circovirus, and it has a single-stranded DNA genome. It causes a fatal disease in parrots called psittacine beak and feather disease (PBFD). After screening of samples collected from Taiwan using PCR, complete genome sequences of isolates from 21 samples from various species of parrot were obtained. The nucleotide sequences of the replication-associated protein gene (rep) and the amino acid sequences of the replication-associated protein (Rep) were more conserved than the nucleotide sequences of the capsid protein gene (cp) and the amino acid sequences of the capsid protein (CP). In Bayesian phylogenetic analysis, the topology of the complete genome sequence was similar to that of the rep gene alone. Recombination events were identified in Taiwan isolates. Recombination hot spots were mainly located in the intergenic region between the 3' ends of the rep and cp genes and at the 5' end of the cp gene. The 5' end and the middle of the rep gene were found to be recombination cold spots. Despite the overall negative selection that was observed for the rep and cp genes, one and 18 positive selected sites were found for the rep and cp gene, respectively.

Dual ATPase and GTPase activity of the replication-associated protein (Rep) of beak and feather disease virus.

BACKGROUND: Psittacine beak and feather disease affects parrots resulting in an immunosuppressive disease that is often characterized by an abnormal shape and growth of the animal's beak, feathers, and claws. Beak and feather disease virus (BFDV) is a single-stranded circular DNA virus and is classified as a member of the Circoviridae family. Two major open reading frames (ORFs) are known to encode the replication-associated (Rep) protein and the capsid-associated (Cap) protein. METHODS: The Rep and Cap genes of BFDV were fused with tags and then expressed and purified, respectively. Both the ATPase and GTPase activities of the recombinant Rep protein are measured. The substrate and ion preference, the optimal conditions, the effects of ATPase and GTPase inhibitors and the presence of Cap protein on the ATPase and GTPase activity of the Rep protein are examined. Finally, the effects of the Walker A motif, the Walker B motif, and a novel GYDG motif of the Rep protein on the ATPase and GTPase activities are studied by various mutants. RESULTS: The recombinant Rep protein could display ATPase activity and GTPase activity. The Rep protein was able to hydrolyze both deoxyribonucleotides and ribonucleotides. Among nucleoside triphosphates and deoxynucleoside triphosphates, the substrate preference orders were found to be ATP>GTP>CTP≥UTP and dATP>dGTP>dTTP>dCTP, respectively. Both the ATPase and GTPase activity of the BFDV Rep protein required magnesium ions and the presence of calcium ions significantly inhibited the ATPase and GTPase activity of the Rep protein. The optimal temperatures for ATPase activity and GTPase activity were both 56 °C, while their optimal pH values were both pH 7.5. Both the ATPase activity and GTPase activity of the BFDV Rep protein were significantly down-regulated by polynucleotides and the dsDNA of 36 bp (located in origin of replication) of BFDV genome. The ATPase activity of the BFDV Rep protein was found to be more sensitive to sodium azide than sodium orthovanadate and N-ethylmaleimide. Linoleic acid more strongly inhibited the GTPase activity of the Rep protein than dynasore. This suggested the Rep protein of BFDV should be classified as an F-type ATPase and polyunsaturated fatty acid-sensitive GTPase. In the presence of 10 ng of the Cap protein, the ATPase activity and GTPase activity of the BFDV Rep protein were significantly increased. Furthermore, the BFDV Rep protein contains the Walker A motif, the Walker B motif and a novel GYDG motif. Both the ATPase activity and the GTPase activity of various deletion and site-directed mutants of the Rep protein affecting these motifs were significantly reduced, suggesting all the three motifs contribute to the ATPase and GTPase activities; specifically. In addition, the ATPase activity and GTPase activity of the deletion mutants of the Rep protein were reversed in the presence of the Cap protein. This is the first example of dual ATPase and GTPase activity being reported in the Rep protein of BFDV.

The genotyping of infectious bronchitis virus in Taiwan by a multiplex amplification refractory mutation system reverse transcription polymerase chain reaction.

Infectious bronchitis virus (IBV; Avian coronavirus) causes acute respiratory and reproductive and urogenital diseases in chickens. Following sequence alignment of IBV strains, a combination of selective primer sets was designed to individually amplify the IBV wild-type and vaccine strains using a multiplex amplification refractory mutation system reverse transcription polymerase chain reaction (ARMS RT-PCR) approach. This system was shown to discriminate the IBV wild-type and vaccine strains. Moreover, an ARMS real-time RT-PCR (ARMS qRT-PCR) was combined with a high-resolution analysis (HRMA) to establish a melt curve analysis program. The specificity of the ARMS RT-PCR and the ARMS qRT-PCR was verified using unrelated avian viruses. Different melting temperatures and distinct normalized and shifted melting curve patterns for the IBV Mass, IBV H120, IBV TW-I, and IBV TW-II strains were detected. The new assays were used on samples of lung and trachea as well as virus from allantoic fluid and cell culture. In addition to being able to detect the presence of IBV vaccine and wild-type strains by ARMS RT-PCR, the IBV Mass, IBV H120, IBV TW-I, and IBV TW-II strains were distinguished using ARMS qRT-PCR by their melting temperatures and by HRMA. These approaches have acceptable sensitivities and specificities and therefore should be able to serve as options when carrying out differential diagnosis of IBV in Taiwan and China.

The utilization of a commercial soil nucleic acid extraction kit and PCR for the detection of Clostridium tetanus and Clostridium chauvoei on farms after flooding in Taiwan.

Clostridial diseases are zoonoses and are classified as soil-borne diseases. Clostridium chauvoei and Clostridium tetani cause blackleg disease and tetanus, respectively. Since bacteria and spores are re-distributed by floods and then, subsequently, contaminate soils, pastures and water; the case numbers associated with clostridial diseases usually increase after floods. Because Taiwan is often affected by flood damage during the typhoon season, possible threats from these diseases are present. Thus, this study's aim is to apply a combination of a commercial nucleic acid extraction kit and PCR to assess the prevalence of Clostridia spp. in soil and to compare the positivity rates for farms before and after floods. The minimum amounts of Clostridium tetanus and Clostridium chauvoei that could be extracted from soils and detected by PCR were 10 and 50 colony forming units (cfu), respectively. In total, 76 samples were collected from the central and southern regions of Taiwan, which are the areas that are most frequently damaged by typhoons. Noteworthy, the positive rates for Clostridium tetanus and Clostridium chauvoei in Pingtung county after the severe floods caused by a typhoon increased significantly from 13.73 and 7.84% to 53.85 and 50.00%, respectively. This study for the first time provides the evidence from surveillance data that there are changes in the environmental distribution of Clostridium spp. after floods. This study indicates that screening for soil-related zoonotic pathogens is a potential strategy that may help to control these diseases.