Discrepancy in the diagnosis of avian Borna disease virus infection of Psittaciformes by protein analysis of feather calami and enzyme-linked immunosorbent assay of plasma antibodies.

The present study compares diagnosis of avian Borna disease virus (ABV) infection of psittacine birds by Western blot of bornaviral proteins in dried feather stems with the detection of anti-bornaviral protein antibodies to bornaviral proteins in plasma by enzyme-linked immunosorbent assay (ELISA). The detection of ABV proteins P40 and P24 in feather calami by Western blotting was possible even after storage of the dried feathers for several years at ambient temperature. Serological identification of anti-bornaviral antibodies may fail (e.g., in young birds, hatched from infected parents), whereas bornaviral P40 and P24 proteins were detected in feather stems. This failure can last at least 10 months after the birds are hatched. In some older birds (>5 years), ABV protein was only detectable in the brain, but not in some peripheral tissues, suggesting that the immune system had succeeded in removing the infecting ABV from tissues outside the brain. These results show that a combination of feather stem analysis for the presence of bornaviral proteins by Western blot combined with serological detection of anti-bornaviral antibodies by ELISA is the most reliable procedure for the detection of a bornaviral infection.

Vertical transmission of avian bornavirus in Psittaciformes: avian bornavirus RNA and anti-avian bornavirus antibodies in eggs, embryos, and hatchlings obtained from infected sun conures (Aratinga solstitialis).

Fertilized eggs were obtained from four pairs of sun conures (Aratinga solstitialis) infected with avian bornavirus (ABV) genotype 2, as determined by the sequence of the P24 gene. ABV RNA could be detected in early embryos of all four pairs. ABV RNA also was detected in brain, liver, and eyes of late-stage embryos of one of the pairs (Pair 4) and in blood of a 2-wk-old hatchling of this pair, demonstrating that vertical transmission can occur. ABV RNA could be detected in the liver but not in the brain or eyes of the late-stage embryos of another pair (Pair 3). Although it could be detected in the undeveloped eggs of the female parent and 8-day-old embryos, bornaviral RNA could not be found in the brain and liver of the late-stage embryos or in feathers and blood of young (5-9-wk-old) hatchlings of a third pair (Pair 2). At 11 wk, ABV RNA could be detected again in feathers and blood of these hatchlings and in the brain of one of the hatchlings of Pair 2 that suddenly died. ABV RNA could however be detected in throat swabs of the 5- and 9-wk-old hatchlings and their parents (Pair 2). Although the continued presence of ABV RNA in feathers and blood below the detection level of the reverse transcription-PCR used cannot be excluded, this result also may be attributable to feeding by the infected parents. Analysis by enzyme-linked immunosorbent assay showed that egg yolks and serum of late-stage embryos contain variable amounts of non-neutralizing anti-ABV-P40, -P10, -P24, and -P16 antibodies, the ratio of which reflected the antibody ratio in the serum of the female parent. Antibodies against the viral glycoprotein, which are considered neutralizing in mammals, and against ABV RNA polymerase were not detected. Whereas 5-wk-old hatchlings of the pair (Pair 2) that produced ABV RNA-free late-stage embryos were free of anti-ABV antibodies, such antibodies could be detected again in the serum of these hatchlings at 9 wk of age, before the age that bornaviral RNA could again be detected in feathers and blood. At 16 wk, these antibodies became abundant. The finding that late-stage embryos, presumably free of ABV RNA, can be obtained from eggs from infected parents suggests that hand- or foster-raising of such birds may be a method to obtain birnavirus-free offspring from some infected birds.

Diagnosis of Avian bornavirus infection in psittaciformes by serum antibody detection and reverse transcription polymerase chain reaction assay using feather calami.

Avian bornavirus (ABV) is the causative agent of proventricular dilatation disease (PDD), a highly devastating and contagious disease of psittacines (parrots and parakeets), which has resulted in the death of many captive birds. Accurate diagnosis of bornavirus infection is therefore important for the identification and isolation of infected birds. The current study showed that nonvascular contour (chest) feather calami provide a ready and minimally invasive source of RNA for the detection of ABV by reverse transcription polymerase chain reaction (RT-PCR). Storage of the feathers at room temperature for at least a month did not affect the results. Serological analysis by enzyme-linked immunosorbent assay (ELISA) showed that identification of anti-bornaviral nucleoprotein P40 antibodies can identify many birds with a past or present infection. The presence of anti-avian bornaviral P24 phosphoprotein and P16 matrix protein antibodies was quite variable, rendering these antibodies less useful for diagnosis of ABV infection. The significance of the present findings is that the use of nonvascular feathers as a source of RNA allows sample collection under conditions where storage of other samples would be difficult. Serum detection by ELISA of anti-P40 antibodies allows the identification of infected birds when RT-PCR fails.

Presence of avian bornavirus RNA and anti-avian bornavirus antibodies in apparently healthy macaws.

Recently a novel avian bornavirus has been described that has been suggested to be the possible etiological agent for proventricular dilatation disease or macaw wasting disease. This article describes two macaws that shed avian bornaviral RNA sequences and demonstrated anti-avian bornavirus antibodies as revealed by reverse transcriptase polymerase chain reaction (RT-PCR), enzyme-linked immunosorbent assay (ELISA), and Western blot, yet are free of outward clinical signs of the disease.

Sequence analysis of four double-stranded RNA genomic segments reveals an orthoreovirus with a unique genotype infecting psittaciformes.

This paper describes the characterization of four double-stranded ribonucleic acid segments, S1, S2, S3, and S4, of a newly identified pathogenic reovirus from parrots. The four segments share a unique 5' terminus GCUUUUC. The amino-acid sequences of the conserved sigma A and sigma NS proteins show less than 60% sequence similarity, whereas those of the outer capsid proteins sigma B and sigma C have at most 47% sequence similarity to their counterparts in other bird or bat reoviruses. In a phylogenetic analysis of the amino-acid sequences, the proteins coded for by the S1 segment, P10, P17, and sigma C, group with their homologous proteins in other avian reoviruses, whereas the major capsid protein, sigma B, and the nonstructural protein, sigma NS, show more sequence similarity to their bat reoviral counterparts. The phylogenetic relationship of sigma A with the homologous avian and bat sequences is unresolved. The possibility that the parrot reovirus has evolved from an ancestral, more batlike reovirus is discussed. It is proposed to designate this unique virus as PsRV.

The evolution of the spindlin gene in birds: sequence analysis of an intron of the spindlin W and Z gene reveals four major divisions of the Psittaciformes.

The Psittaciformes (parrots, parakeets) are among the most widely held captive birds. Yet, their evolution and their phylogenetic relationships have been relatively little studied. This paper describes the phylogenetic relationships between a number of Psittaciformes as derived from the sequences of the third intron of the Z-chromosomal and W-chromosomal spindlin genes. The Z-chromosomal sequences of the kakapo (Strigops habroptilus), the kea (Nestor notabilis), and the kaka (Nestor meridionalis) from New Zealand form a cluster which is the sister group to all other Psittaciformes. The results show further that the Z-chromosomal sequences of the other species can be divided into two groups based on the occurrence of a sequence element ACCCT. The group with the insert (A) is mainly from species with an Australasian geographical distribution and includes such species as the Lories (Lorius, etc.), the budgerigar (Melospittacus undulatus), and the rosellas (Platycercus). It also includes the African lovebirds (Agapornidae), which are the only representative of group A outside Australasia. Group B, without the insert, includes the neotropical parrots and parakeets such as the amazons (Amazona, etc.), the macaws (Ara, etc.), and the conures (Aratinga, etc.), the Australian Cacatuini and the African species such as the African grey parrot (Psittacus erithacus) as well as Coracopsis vasa from Madagascar and Psittrichas fulgidus from New Guinea. The W-chromosomal sequence data show that another division of the Psittacidae is found in the replacement of a pyrimidine-rich segment occurring in many non-psittacines as well as the kakapo (S. habroptilus), the kea (N. notabilis), the kaka (N. meridionalis), and the Cacatuini by a microsatellite consisting of a variable number of TATTA monomers in the other Psittaciformes. The results support a Gondwanan origin of the Psittaciformes and the suggestion that paleogeographic events were a major force in psittacine divergence.