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Korean J. Vet. Serv. 2024; 47(4): 201-209
Published online December 30, 2024
https://doi.org/10.7853/kjvs.2024.47.4.201
© The Korean Socitety of Veterinary Service
Correspondence to : Choi-Kyu Park
E-mail: parkck@knu.ac.kr
https://orcid.org/0000-0002-0784-9061
†These first two authors contributed equally to this work.
This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0). which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
To identify the causes of sudden death in pet parrots in this study, molecular screening was carried out to detect major psittacine viral pathogens including Psittacine beak and feather disease virus (PBFDV), Avian bornavirus (ABV), Psittacid herpesvirus 1 (PsHV-1), Avian polyomavirus, and Avian paramyxovirus serotype 1. The results showed that all six parrots were infected with PBFDV, indicating that PBFDV was likely the main cause of their deaths. Among these PBFDV-positive parrots, three were dually coinfected with PBFDV and ABV and one was triply coinfected with PBFDV, ABV and PsHV-1, indicating two viruses (ABV and PsHV-1) may also contribute to fatal outcomes of parrots. In Korea, there have been reports on the genetic characterization of PBFDV and APyV, but no reports on PsHV-1. Therefore, to further characterize PsHV-1 detected from a rosella parakeet, the partial UL16 gene was sequenced and compared with those of the reference PsHV-1 strains retrieved from the GenBank database. The Korean PsHV-1 (KPsHV-1 strain) was closely related to the genotype 1 PsHV-1 strain reported in the USA showing 100% nucleotide identity. Phylogenetic analysis based on the partial UL16 gene indicated that the KPsHV-1 strain was clustered into the genotype 1 group, which supported that genotype 1 PsHV-1 was introduced in Korea. To the best of our knowledge, this is the first report identifying the genotype of the PsHV-1 strain in Korean parrots. These findings contribute to our understanding of the epidemiology of psittacine viruses and the genetic characteristics of PsHV-1 among pet parrots in Korea. Further studies are needed to understand the epidemiology and genetic characteristics of psittacine viruses and to develop effective control measures for these viral infections in pet parrots.
Keywords Pet parrot, Molecular detection, Psittacid herpesvirus 1, Genotyping
Pacheco’s disease (PD) is an acute, highly contagious disease that is often fatal to psittacine birds. This disease was first identified from psittacine birds (parrots) in 1929 in Brazil (Pacheco and Bier, 1930). Since then, the disease has been reported in various countries and continents, including the USA, Europe, South America, South Africa, and Japan (Gough and Alexander, 1993; Katoh et al., 2010). Such a global transmission of the disease is believed to be due to the international trade of pet parrots, as like in other parrot diseases (Tomaszewski et al., 2003; Franzo et al., 2022). PD is caused by psittacid herpesvirus-1 (PsHV-1), also known as psittacid alphaherpesvirus-1 and now renamed
Clinical signs are rarely observed in PD-affected birds, as they typically suffer sudden deaths. Therefore, PD should be suspected in any psittacine birds that die suddenly without showing clinical signs (Katoh et al., 2010). However, sudden deaths of psittacine birds can also be caused by psittacine beak and feather disease virus (PBFDV), avian polyomavirus (APV), avian bornavirus (ABV), or avian paramyxovirus serotype 1 (APMV-1). Therefore, the etiological diagnosis of the causal virus is essential to determine whether psittacine birds died due to PD (Katoh et al., 2010). Currently, molecular diagnostic methods such as polymerase chain reaction (PCR) and real-time PCR are widely used for the routine diagnosis of psittacine viral pathogens due to their rapid speed and high specificity and sensitivity (Tomaszewski et al., 2003; Styles et al., 2005).
In Korea, the first case of PD was reported in 2003 from dead Bourke’s parakeets (
In this study, we identified PsHV-1 from a deceased rosella parakeet (
Among the 55 parrots under six months of age raised in an aviary in Gyeongsangbuk-do province, Korea, 12 suffered acute deaths with few or no premonitory signs over two weeks. The observed clinical signs included profuse, watery diarrhea and depression, leading to death within 24 hours. No treatment was conducted for the affected birds due to their sudden deaths. Six of the affected birds – one golden conure (
For etiological diagnosis, five major viral pathogens were tested by previously described assays: PCR for PBFDV, APV, and PsHV-1; reverse transcription PCR (RT-PCR) for ABV and APMV-1. For these assays, pathogen-specific primer sets were used (Table 1). PCR was performed with a commercial PCR kit (Excel TB 2X Taq premix; Inclone, South Korea) according to previously described PCR protocols for PBFDV (Ypelaar et al., 1999; Kim et al., 2014b), APV (Johne and Müller, 1998; Kim et al., 2014c), and PsHV-1 (Tomaszewski et al., 2003; Styles et al., 2005), and the manufacturer’s protocol, respectively. RT-PCR was performed with a commercial one-step RT-PCR kit (PrimeScriptTM One-Step RT-PCR Kit Ver. 2, Takara Bio, Kusatsu, Shiga, Japan) according to previously described RT-PCR protocols for ABV (Guo et al., 2012; Kim et al., 2014a) and APMV-1 (Creelan et al., 2002) and the manufacturer’s protocol, respectively. After subjecting the amplified DNA to 1.5% agarose gel electrophoresis and staining with NEO green dye (Neoscience, Suwon, South Korea) (Table 1), the virus-specific DNA bands were observed using an ultraviolet light transilluminator (Neoscience).
Table 1 . Primers and probes used for the detection of psittacine viral pathogens
Pathogen | Method | Target gene (amplicon size) | Primer and probe (5’-3’) | Reference |
---|---|---|---|---|
ABV | RT-PCR | M gene (351-bp) | F: GGTAATTGTTCCTGGATGGC R: ACACCAATGTTCCGAAGACG | Guo et al. (2012) |
PBFDV | PCR | ORF1 gene (717-bp) | F: AACCCTACAGACGGCGAG R: GTCACAGTCCTCCTTGTACC | Ypelaar et al. (1999) |
APV | PCR | T gene (310-bp) | F: CAAGCATATGTCCCTTTATCCC R: CTGTTTAAGGCCTTCCAAGATG | Johne and Müller (1998) |
PsHV-1 | PCR | UL17-UL16 gene (667-bp) | F: TGCGTGGGGTTAAACTCGGAAC R: GATGTTAGGCTCGTGTAGTCG | Tomaszewski et al. (2003) |
APMV-1 | RT-PCR | F gene (202-bp) | F: GGTGAGTCTATCCGGARGATACAAG R: TCATTGGTTGCRGCAATGCTCT | Creelan et al. (2002) |
ABV, avian bornavirus; PBFDV, psittacine beak and feather disease virus; APV, avian polyomavirus; PsHV-1, psittacid herpesvirus 1; APMV-1, avian paramyxovirus serotype 1.
The nucleic acids of PsHV-1-positive sample (sample no. 2) were subjected to genetic characterization and genotyping through PCR amplification. The partial UL16 gene sequence (nucleotides/nt 1-419) was amplified using the PCR primer set for PsHV-1 detection previously described by Tomaszewski et al. (2003) (Table 1). The PCR amplification for sequencing was performed with a commercial PCR kit (Excel TB 2X Taq premix) according to manufacturer’s protocol and Tomaszewski et al. (2003) protocol. The PCR product was purified using a commercial kit (GeneAll ExpinTM Combo GP 200 miniprep kit, GeneAll, Seoul, the South Korea) and sequenced using the Sanger’s method by a commercial company (BIONICS, Daejeon, South Korea). Both forward and reverse strands were sequenced to ensure accuracy. The resulting sequences were analyzed and assembled using Geneious Prime (https://www.geneious.com, accessed on 5 November 2024). The partial UL16 gene sequence of KPsHV-1 was successfully obtained in this study and it was deposited in the National Center for Biotechnology Information GenBank database (GenBank accession number PQ645140).
To further characterize the KPsHV-1, the UL16 gene sequence of global PsHV-1 strains with different genotypes were retrieved from the GenBank database (www.ncbi.nlm.nih.gov/genebank, accessed on 5 November 2024). The partial UL16 gene sequence of the KPsHV-1 strain was aligned with the corresponding sequences of the reference PsHV-1 strains using the MAFFT multiple sequence alignment software (v7.490) (Katoh and Standley, 2013). For phylogenetic analysis, the Geneious tree builder (RAxML 8.2.11 plugin) was used to construct a maximum likely hood phylogenetic tree using the GTR GAMMA tree model. The tree was generated through rapid bootstrapping and a search for the best-scoring analysis with 1,000 bootstrap replicates (Stamatakis, 2014). The phylogenetic tree was visualized using the iTOL phylogenetic tree viewer (Letunic and Bork, 2021).
All six parrots tested positive for PBFDV, with three (one golden conure and two rosella parakeets) positive for ABV and one (rosella parakeet) positive for PsHV-1 by PCR and RT-PCR assays for the detection of five psittacine viral pathogens. None of all six parrots were positive for APV and APMV-1 (Table 2, Fig. 1). Three parrots (three green-cheeked parakeets) were solely infected with PBFDV, while two parrots (one golden conure and one rosella parakeet) were coinfected with ABV and PBFDV. Surprisingly, one parrot (rosella parakeet; sample no. 2) was confirmed to be coinfected with three viruses: ABV, PBFDV, and PsHV-1. These results indicated that PBFDV is widely spread, and its coinfection with other viral pathogens, such as ABV and PsHV-1, is common among psittacine birds in Korea.
Table 2 . Molecular detection of major psittacine viral pathogens in the analyzed samples
No. | Common name (species) | Detection of psittacine viral pathogens (+/−) | ||||
---|---|---|---|---|---|---|
ABV | PBFDV | APV | PsHV-1 | APMV-1 | ||
1 | Golden conure ( | Pos | Pos | Neg | Neg | Neg |
2 | Rosella parakeet ( | Pos | Pos | Neg | Pos | Neg |
3 | Rosella parakeet ( | Pos | Pos | Neg | Neg | Neg |
4 | Green-cheeked parakeet ( | Neg | Pos | Neg | Neg | Neg |
5 | Green-cheeked parakeet ( | Neg | Pos | Neg | Neg | Neg |
6 | Green-cheeked parakeet ( | Neg | Pos | Neg | Neg | Neg |
ABV, avian bornavirus; PBFDV, psittacine beak and feather disease virus; APV, avian polyomavirus; PsHV-1, psittacid herpesvirus 1; APMV-1, avian paramyxovirus serotype 1; Pos, positive; Neg, negative.
To genetically characterize Korean PSHV-1 (KPsHV-1), the partial UL 16 gene nucleotide (nt) sequence was obtained. Alignment of this sequence with those of the reference PsHV-1 strains revealed that KPsHV-1 belongs to genotype 1, showing 100% nt identity with the genotype 1 PsHV-1 strain previously reported in the USA (Strain 97-0001; GenBank accession number AY372243). In contrast, the UL16 gene sequence of KPsHV-1 strain was different from the sequences of genotype 2, 3, and 4 PsHV-1 strains, showing multiple nt variations (Fig. 2). For further characterization, a phylogenetic tree was constructed with four different genotypes of PsHV-1 strains. The results showed that KPsHV-1 is clustered with other genotype 1 strains reported from the USA and Brazil while being distinct from genotype 2, 3, and 4 PsHV-1 strains (Fig. 3). These findings support that the genotype 1 PsHV-1 strain was introduced and circulated in Korean psittacine bird population.
With the increasing import of pet parrots, the introduction of various related diseases became inevitable in South Korea (Kim et al., 2022a). To date, several viral pathogens have been identified in Korean pet parrots, including ABV (Kim et al., 2014a), PBFDV (Kim et al., 2014b), and APV (Kim et al., 2014c; Kim et al., 2022b; Yun et al., 2023). In addition, herpesvirus infection in parrots was reported in 2003, but the exact etiological diagnosis was not made (Kwon et al., 2003). Therefore, genetic information about the herpesvirus that infected Korean parrots has not yet been revealed. In this study, six parrots that suffered acute deaths were subjected to etiological analysis using PCR and RT-PCR assays for specific detection of major viral pathogens. As a result, PBFDV, ABV, and PsHV-1 were detected in tested samples, but APV and APMV-1 were not detected (Table 2). All six parrots tested positive for PBFDV, with three parrots positive for ABV and one parrot positive for PsHV-1. Surprisingly, two parrots were coinfected with PBFDV and ABV, and while one parrot was coinfected with PBFDV, ABV, and PsHV-1. These results suggested that although PBFDV was the main cause of the clinical outcomes in these parrots, ABV and PsHV-1 may have also contributed to some extent. This hypothesis is supported by a previous report describing the sudden deaths of parrots due to coinfection with these three viruses (PBFDV, ABV, and PsHV-1) in their acute infection forms (Simpson et al., 1975; Katoh et al., 2010; Ma et al., 2020; Ko et al., 2024). However, further studies are required to elucidate their pathological roles and interactions of the viruses resulting in the sudden death of the parrots observed in this study.
As PBFDV, APV1, ABV, PsHV-1, and APMV-1 are considered the most prevalent viruses in psittacine birds, many studies have investigated the effects of individual infections. However, only a few studies have explored the impact of coinfections with these viruses (Antonio et al., 2024). A recent study reported that dual or triple coinfections with PBFDV, APV1 and/or PsHV-1 are common across various species of psittacine birds (Gibson et al., 2019). In this study, coinfections with PBFDV, ABV, and/or PsHV-1 were first identified in psittacine birds in Korea parrots, suggesting that coinfections with different viral pathogens may be common in Korean psittacine bird populations. Therefore, further extensive studies are needed to determine the prevalence and coinfection status of the psittacine viral pathogens in Korea. Moreover, advanced molecular diagnostic methods are needed for the differential and simultaneous detection of these viral infections in Korean psittacine birds.
Genetic analysis of the partial UL16 gene revealed that KPsHV-1 identified in this study belongs to genotype 1, showing 100% homology with the reference genotype 1 PsHV-1 strain (Strain 97-0001; GenBank number AY372243) (Fig. 2). Furthermore, KPsHV-1 was clustered together with other previously reported genotype 1 PsHV-1 strains and was distinctly clustered from other genotypes of PsHV-1 strains (Fig. 3). This is the first report for genotype identification of PsHV-1 circulating in Korean psittacine birds. However, considering the global distribution of various genotypes of PsHV-1 and their carriers, it is predicted that all known genotypes of PsHV-1 are already introduced in Korea. Nevertheless, there have been no reports on prevalence and genotype distribution of the virus in the Korean pet parrot population. Therefore, further studies are required to determine the prevalence and genotype distribution of the virus to mitigate the infection risks of the viral infection and to prevent the outbreaks of the disease in pet parrots in Korea.
In conclusion, PsHV-1 infection was confirmed in a Rosella parakeet (
This research was supported by Commercialization of strategic technology research results Program through INNOPOLIS Foundation funded by the Ministry of Science and ICT (grant number, 2024-GJ-RD-0033/project title, Commercialization and industrialization of multi-diagnostic kits for rapid diagnosis of infectious diseases in pet and industrial animals in the Honam region).
The authors confirm that the ethical policies of the journal, as noted on the journal’s author guidelines page, have been adhered to. This study was conducted in 2024 and was beyond the purview of the Institutional Animal Care and Use Committee (IACUC) at Kyungpook National University (KNU), as the KNU IACUC only evaluates proposals using laboratory animals maintained in indoor facilities and not research involving outdoor animals. Carcasses of dead parrots were directly submitted from the owner of the affected aviary to the Veterinary Diagnostic Laboratory in the College of Veterinary Medicine of Kyungpook National University for etiological diagnosis.
No potential conflict of interest relevant to this article was reported.
Korean J. Vet. Serv. 2024; 47(4): 201-209
Published online December 30, 2024 https://doi.org/10.7853/kjvs.2024.47.4.201
Copyright © The Korean Socitety of Veterinary Service.
Ji-Hyeon Baek 1†, Hye-Ryung Kim 1,2†, Jonghyun Park 1,2, Yong-Gu Yeo 1,3, Oh-Deog Kwon 1, Seung-Chun Park 1,4, Choi-Kyu Park 1*
1College of Veterinary Medicine & Institute for Veterinary Biomedical Science, Kyungpook National University, Daegu 41566, Korea
2DIVA Bio Incorporation, Daegu 41519, Korea,
3Seoul Zoo, Gwacheon 13829, Korea,
4Laboratory of Veterinary Pharmacokinetics and Pharmacodynamics, College of Veterinary Medicine and Cardiovascular Research Institute, Kyungpook National University, Daegu 41566, Korea
Correspondence to:Choi-Kyu Park
E-mail: parkck@knu.ac.kr
https://orcid.org/0000-0002-0784-9061
†These first two authors contributed equally to this work.
This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0). which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
To identify the causes of sudden death in pet parrots in this study, molecular screening was carried out to detect major psittacine viral pathogens including Psittacine beak and feather disease virus (PBFDV), Avian bornavirus (ABV), Psittacid herpesvirus 1 (PsHV-1), Avian polyomavirus, and Avian paramyxovirus serotype 1. The results showed that all six parrots were infected with PBFDV, indicating that PBFDV was likely the main cause of their deaths. Among these PBFDV-positive parrots, three were dually coinfected with PBFDV and ABV and one was triply coinfected with PBFDV, ABV and PsHV-1, indicating two viruses (ABV and PsHV-1) may also contribute to fatal outcomes of parrots. In Korea, there have been reports on the genetic characterization of PBFDV and APyV, but no reports on PsHV-1. Therefore, to further characterize PsHV-1 detected from a rosella parakeet, the partial UL16 gene was sequenced and compared with those of the reference PsHV-1 strains retrieved from the GenBank database. The Korean PsHV-1 (KPsHV-1 strain) was closely related to the genotype 1 PsHV-1 strain reported in the USA showing 100% nucleotide identity. Phylogenetic analysis based on the partial UL16 gene indicated that the KPsHV-1 strain was clustered into the genotype 1 group, which supported that genotype 1 PsHV-1 was introduced in Korea. To the best of our knowledge, this is the first report identifying the genotype of the PsHV-1 strain in Korean parrots. These findings contribute to our understanding of the epidemiology of psittacine viruses and the genetic characteristics of PsHV-1 among pet parrots in Korea. Further studies are needed to understand the epidemiology and genetic characteristics of psittacine viruses and to develop effective control measures for these viral infections in pet parrots.
Keywords: Pet parrot, Molecular detection, Psittacid herpesvirus 1, Genotyping
Pacheco’s disease (PD) is an acute, highly contagious disease that is often fatal to psittacine birds. This disease was first identified from psittacine birds (parrots) in 1929 in Brazil (Pacheco and Bier, 1930). Since then, the disease has been reported in various countries and continents, including the USA, Europe, South America, South Africa, and Japan (Gough and Alexander, 1993; Katoh et al., 2010). Such a global transmission of the disease is believed to be due to the international trade of pet parrots, as like in other parrot diseases (Tomaszewski et al., 2003; Franzo et al., 2022). PD is caused by psittacid herpesvirus-1 (PsHV-1), also known as psittacid alphaherpesvirus-1 and now renamed
Clinical signs are rarely observed in PD-affected birds, as they typically suffer sudden deaths. Therefore, PD should be suspected in any psittacine birds that die suddenly without showing clinical signs (Katoh et al., 2010). However, sudden deaths of psittacine birds can also be caused by psittacine beak and feather disease virus (PBFDV), avian polyomavirus (APV), avian bornavirus (ABV), or avian paramyxovirus serotype 1 (APMV-1). Therefore, the etiological diagnosis of the causal virus is essential to determine whether psittacine birds died due to PD (Katoh et al., 2010). Currently, molecular diagnostic methods such as polymerase chain reaction (PCR) and real-time PCR are widely used for the routine diagnosis of psittacine viral pathogens due to their rapid speed and high specificity and sensitivity (Tomaszewski et al., 2003; Styles et al., 2005).
In Korea, the first case of PD was reported in 2003 from dead Bourke’s parakeets (
In this study, we identified PsHV-1 from a deceased rosella parakeet (
Among the 55 parrots under six months of age raised in an aviary in Gyeongsangbuk-do province, Korea, 12 suffered acute deaths with few or no premonitory signs over two weeks. The observed clinical signs included profuse, watery diarrhea and depression, leading to death within 24 hours. No treatment was conducted for the affected birds due to their sudden deaths. Six of the affected birds – one golden conure (
For etiological diagnosis, five major viral pathogens were tested by previously described assays: PCR for PBFDV, APV, and PsHV-1; reverse transcription PCR (RT-PCR) for ABV and APMV-1. For these assays, pathogen-specific primer sets were used (Table 1). PCR was performed with a commercial PCR kit (Excel TB 2X Taq premix; Inclone, South Korea) according to previously described PCR protocols for PBFDV (Ypelaar et al., 1999; Kim et al., 2014b), APV (Johne and Müller, 1998; Kim et al., 2014c), and PsHV-1 (Tomaszewski et al., 2003; Styles et al., 2005), and the manufacturer’s protocol, respectively. RT-PCR was performed with a commercial one-step RT-PCR kit (PrimeScriptTM One-Step RT-PCR Kit Ver. 2, Takara Bio, Kusatsu, Shiga, Japan) according to previously described RT-PCR protocols for ABV (Guo et al., 2012; Kim et al., 2014a) and APMV-1 (Creelan et al., 2002) and the manufacturer’s protocol, respectively. After subjecting the amplified DNA to 1.5% agarose gel electrophoresis and staining with NEO green dye (Neoscience, Suwon, South Korea) (Table 1), the virus-specific DNA bands were observed using an ultraviolet light transilluminator (Neoscience).
Table 1 . Primers and probes used for the detection of psittacine viral pathogens.
Pathogen | Method | Target gene (amplicon size) | Primer and probe (5’-3’) | Reference |
---|---|---|---|---|
ABV | RT-PCR | M gene (351-bp) | F: GGTAATTGTTCCTGGATGGC R: ACACCAATGTTCCGAAGACG | Guo et al. (2012) |
PBFDV | PCR | ORF1 gene (717-bp) | F: AACCCTACAGACGGCGAG R: GTCACAGTCCTCCTTGTACC | Ypelaar et al. (1999) |
APV | PCR | T gene (310-bp) | F: CAAGCATATGTCCCTTTATCCC R: CTGTTTAAGGCCTTCCAAGATG | Johne and Müller (1998) |
PsHV-1 | PCR | UL17-UL16 gene (667-bp) | F: TGCGTGGGGTTAAACTCGGAAC R: GATGTTAGGCTCGTGTAGTCG | Tomaszewski et al. (2003) |
APMV-1 | RT-PCR | F gene (202-bp) | F: GGTGAGTCTATCCGGARGATACAAG R: TCATTGGTTGCRGCAATGCTCT | Creelan et al. (2002) |
ABV, avian bornavirus; PBFDV, psittacine beak and feather disease virus; APV, avian polyomavirus; PsHV-1, psittacid herpesvirus 1; APMV-1, avian paramyxovirus serotype 1..
The nucleic acids of PsHV-1-positive sample (sample no. 2) were subjected to genetic characterization and genotyping through PCR amplification. The partial UL16 gene sequence (nucleotides/nt 1-419) was amplified using the PCR primer set for PsHV-1 detection previously described by Tomaszewski et al. (2003) (Table 1). The PCR amplification for sequencing was performed with a commercial PCR kit (Excel TB 2X Taq premix) according to manufacturer’s protocol and Tomaszewski et al. (2003) protocol. The PCR product was purified using a commercial kit (GeneAll ExpinTM Combo GP 200 miniprep kit, GeneAll, Seoul, the South Korea) and sequenced using the Sanger’s method by a commercial company (BIONICS, Daejeon, South Korea). Both forward and reverse strands were sequenced to ensure accuracy. The resulting sequences were analyzed and assembled using Geneious Prime (https://www.geneious.com, accessed on 5 November 2024). The partial UL16 gene sequence of KPsHV-1 was successfully obtained in this study and it was deposited in the National Center for Biotechnology Information GenBank database (GenBank accession number PQ645140).
To further characterize the KPsHV-1, the UL16 gene sequence of global PsHV-1 strains with different genotypes were retrieved from the GenBank database (www.ncbi.nlm.nih.gov/genebank, accessed on 5 November 2024). The partial UL16 gene sequence of the KPsHV-1 strain was aligned with the corresponding sequences of the reference PsHV-1 strains using the MAFFT multiple sequence alignment software (v7.490) (Katoh and Standley, 2013). For phylogenetic analysis, the Geneious tree builder (RAxML 8.2.11 plugin) was used to construct a maximum likely hood phylogenetic tree using the GTR GAMMA tree model. The tree was generated through rapid bootstrapping and a search for the best-scoring analysis with 1,000 bootstrap replicates (Stamatakis, 2014). The phylogenetic tree was visualized using the iTOL phylogenetic tree viewer (Letunic and Bork, 2021).
All six parrots tested positive for PBFDV, with three (one golden conure and two rosella parakeets) positive for ABV and one (rosella parakeet) positive for PsHV-1 by PCR and RT-PCR assays for the detection of five psittacine viral pathogens. None of all six parrots were positive for APV and APMV-1 (Table 2, Fig. 1). Three parrots (three green-cheeked parakeets) were solely infected with PBFDV, while two parrots (one golden conure and one rosella parakeet) were coinfected with ABV and PBFDV. Surprisingly, one parrot (rosella parakeet; sample no. 2) was confirmed to be coinfected with three viruses: ABV, PBFDV, and PsHV-1. These results indicated that PBFDV is widely spread, and its coinfection with other viral pathogens, such as ABV and PsHV-1, is common among psittacine birds in Korea.
Table 2 . Molecular detection of major psittacine viral pathogens in the analyzed samples.
No. | Common name (species) | Detection of psittacine viral pathogens (+/−) | ||||
---|---|---|---|---|---|---|
ABV | PBFDV | APV | PsHV-1 | APMV-1 | ||
1 | Golden conure ( | Pos | Pos | Neg | Neg | Neg |
2 | Rosella parakeet ( | Pos | Pos | Neg | Pos | Neg |
3 | Rosella parakeet ( | Pos | Pos | Neg | Neg | Neg |
4 | Green-cheeked parakeet ( | Neg | Pos | Neg | Neg | Neg |
5 | Green-cheeked parakeet ( | Neg | Pos | Neg | Neg | Neg |
6 | Green-cheeked parakeet ( | Neg | Pos | Neg | Neg | Neg |
ABV, avian bornavirus; PBFDV, psittacine beak and feather disease virus; APV, avian polyomavirus; PsHV-1, psittacid herpesvirus 1; APMV-1, avian paramyxovirus serotype 1; Pos, positive; Neg, negative..
To genetically characterize Korean PSHV-1 (KPsHV-1), the partial UL 16 gene nucleotide (nt) sequence was obtained. Alignment of this sequence with those of the reference PsHV-1 strains revealed that KPsHV-1 belongs to genotype 1, showing 100% nt identity with the genotype 1 PsHV-1 strain previously reported in the USA (Strain 97-0001; GenBank accession number AY372243). In contrast, the UL16 gene sequence of KPsHV-1 strain was different from the sequences of genotype 2, 3, and 4 PsHV-1 strains, showing multiple nt variations (Fig. 2). For further characterization, a phylogenetic tree was constructed with four different genotypes of PsHV-1 strains. The results showed that KPsHV-1 is clustered with other genotype 1 strains reported from the USA and Brazil while being distinct from genotype 2, 3, and 4 PsHV-1 strains (Fig. 3). These findings support that the genotype 1 PsHV-1 strain was introduced and circulated in Korean psittacine bird population.
With the increasing import of pet parrots, the introduction of various related diseases became inevitable in South Korea (Kim et al., 2022a). To date, several viral pathogens have been identified in Korean pet parrots, including ABV (Kim et al., 2014a), PBFDV (Kim et al., 2014b), and APV (Kim et al., 2014c; Kim et al., 2022b; Yun et al., 2023). In addition, herpesvirus infection in parrots was reported in 2003, but the exact etiological diagnosis was not made (Kwon et al., 2003). Therefore, genetic information about the herpesvirus that infected Korean parrots has not yet been revealed. In this study, six parrots that suffered acute deaths were subjected to etiological analysis using PCR and RT-PCR assays for specific detection of major viral pathogens. As a result, PBFDV, ABV, and PsHV-1 were detected in tested samples, but APV and APMV-1 were not detected (Table 2). All six parrots tested positive for PBFDV, with three parrots positive for ABV and one parrot positive for PsHV-1. Surprisingly, two parrots were coinfected with PBFDV and ABV, and while one parrot was coinfected with PBFDV, ABV, and PsHV-1. These results suggested that although PBFDV was the main cause of the clinical outcomes in these parrots, ABV and PsHV-1 may have also contributed to some extent. This hypothesis is supported by a previous report describing the sudden deaths of parrots due to coinfection with these three viruses (PBFDV, ABV, and PsHV-1) in their acute infection forms (Simpson et al., 1975; Katoh et al., 2010; Ma et al., 2020; Ko et al., 2024). However, further studies are required to elucidate their pathological roles and interactions of the viruses resulting in the sudden death of the parrots observed in this study.
As PBFDV, APV1, ABV, PsHV-1, and APMV-1 are considered the most prevalent viruses in psittacine birds, many studies have investigated the effects of individual infections. However, only a few studies have explored the impact of coinfections with these viruses (Antonio et al., 2024). A recent study reported that dual or triple coinfections with PBFDV, APV1 and/or PsHV-1 are common across various species of psittacine birds (Gibson et al., 2019). In this study, coinfections with PBFDV, ABV, and/or PsHV-1 were first identified in psittacine birds in Korea parrots, suggesting that coinfections with different viral pathogens may be common in Korean psittacine bird populations. Therefore, further extensive studies are needed to determine the prevalence and coinfection status of the psittacine viral pathogens in Korea. Moreover, advanced molecular diagnostic methods are needed for the differential and simultaneous detection of these viral infections in Korean psittacine birds.
Genetic analysis of the partial UL16 gene revealed that KPsHV-1 identified in this study belongs to genotype 1, showing 100% homology with the reference genotype 1 PsHV-1 strain (Strain 97-0001; GenBank number AY372243) (Fig. 2). Furthermore, KPsHV-1 was clustered together with other previously reported genotype 1 PsHV-1 strains and was distinctly clustered from other genotypes of PsHV-1 strains (Fig. 3). This is the first report for genotype identification of PsHV-1 circulating in Korean psittacine birds. However, considering the global distribution of various genotypes of PsHV-1 and their carriers, it is predicted that all known genotypes of PsHV-1 are already introduced in Korea. Nevertheless, there have been no reports on prevalence and genotype distribution of the virus in the Korean pet parrot population. Therefore, further studies are required to determine the prevalence and genotype distribution of the virus to mitigate the infection risks of the viral infection and to prevent the outbreaks of the disease in pet parrots in Korea.
In conclusion, PsHV-1 infection was confirmed in a Rosella parakeet (
This research was supported by Commercialization of strategic technology research results Program through INNOPOLIS Foundation funded by the Ministry of Science and ICT (grant number, 2024-GJ-RD-0033/project title, Commercialization and industrialization of multi-diagnostic kits for rapid diagnosis of infectious diseases in pet and industrial animals in the Honam region).
The authors confirm that the ethical policies of the journal, as noted on the journal’s author guidelines page, have been adhered to. This study was conducted in 2024 and was beyond the purview of the Institutional Animal Care and Use Committee (IACUC) at Kyungpook National University (KNU), as the KNU IACUC only evaluates proposals using laboratory animals maintained in indoor facilities and not research involving outdoor animals. Carcasses of dead parrots were directly submitted from the owner of the affected aviary to the Veterinary Diagnostic Laboratory in the College of Veterinary Medicine of Kyungpook National University for etiological diagnosis.
No potential conflict of interest relevant to this article was reported.
Table 1 . Primers and probes used for the detection of psittacine viral pathogens.
Pathogen | Method | Target gene (amplicon size) | Primer and probe (5’-3’) | Reference |
---|---|---|---|---|
ABV | RT-PCR | M gene (351-bp) | F: GGTAATTGTTCCTGGATGGC R: ACACCAATGTTCCGAAGACG | Guo et al. (2012) |
PBFDV | PCR | ORF1 gene (717-bp) | F: AACCCTACAGACGGCGAG R: GTCACAGTCCTCCTTGTACC | Ypelaar et al. (1999) |
APV | PCR | T gene (310-bp) | F: CAAGCATATGTCCCTTTATCCC R: CTGTTTAAGGCCTTCCAAGATG | Johne and Müller (1998) |
PsHV-1 | PCR | UL17-UL16 gene (667-bp) | F: TGCGTGGGGTTAAACTCGGAAC R: GATGTTAGGCTCGTGTAGTCG | Tomaszewski et al. (2003) |
APMV-1 | RT-PCR | F gene (202-bp) | F: GGTGAGTCTATCCGGARGATACAAG R: TCATTGGTTGCRGCAATGCTCT | Creelan et al. (2002) |
ABV, avian bornavirus; PBFDV, psittacine beak and feather disease virus; APV, avian polyomavirus; PsHV-1, psittacid herpesvirus 1; APMV-1, avian paramyxovirus serotype 1..
Table 2 . Molecular detection of major psittacine viral pathogens in the analyzed samples.
No. | Common name (species) | Detection of psittacine viral pathogens (+/−) | ||||
---|---|---|---|---|---|---|
ABV | PBFDV | APV | PsHV-1 | APMV-1 | ||
1 | Golden conure ( | Pos | Pos | Neg | Neg | Neg |
2 | Rosella parakeet ( | Pos | Pos | Neg | Pos | Neg |
3 | Rosella parakeet ( | Pos | Pos | Neg | Neg | Neg |
4 | Green-cheeked parakeet ( | Neg | Pos | Neg | Neg | Neg |
5 | Green-cheeked parakeet ( | Neg | Pos | Neg | Neg | Neg |
6 | Green-cheeked parakeet ( | Neg | Pos | Neg | Neg | Neg |
ABV, avian bornavirus; PBFDV, psittacine beak and feather disease virus; APV, avian polyomavirus; PsHV-1, psittacid herpesvirus 1; APMV-1, avian paramyxovirus serotype 1; Pos, positive; Neg, negative..
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