Isolation and molecular characterization of a new Muscovy duck ...

Avian Pathology (December 2006) 35(6), 435 441

Isolation and molecular characterization of a new Muscovy duck parvovirus from Muscovy ducks in the USA Bhawna Poonia1, Patricia A. Dunn2, Huaguang Lu2, Keith W. Jarosinski1 and Karel A. Schat1* 1

Department of Microbiology and Immunology, College of Veterinary Medicine, Cornell University, Ithaca, NY 14853, USA, and 2Animal Diagnostic Laboratory, Department of Veterinary and Biomedical Sciences, Pennsylvania State University, University Park, PA 16802, USA

Between 1997 and 1999 several cases of a new disease in Muscovy ducks were reported in Pennsylvania, USA. The cases were characterized by locomotor dysfunction, weakness, recumbency, 40 to 60% morbidity and 10 to 40% mortality. The most characteristic microscopic lesions were moderate to severe degenerative rhabodomyopathy. In order to characterize the aetiological agent, virus isolation was attempted from the spleen, liver, heart, skeletal muscle and intestine by inoculation of 14-day-old Muscovy duck embryos with tissue homogenates. Deaths occurred on the second egg passage and parvoviruses were isolated by serial passage of allantoic fluid from dead embryos and then in Muscovy duck embryo fibroblast (MDEF) cultures. Parvovirus particles were observed in allantoic fluids and supernatants of MDEF cultures by transmission electron microscopy. Two genomic fragments, comprising 1108 nucleotides of the right open reading frame that codes for the structural viral proteins 1, 2 and 3, were amplified by polymerase chain reaction from one of the isolates, Muscovy duck parvovirus (MDPV)/PSU-31010. Comparison of this fragment with available sequences of other MDPV and related goose parvovirus (GPV) isolates showed that it had only 84.5% sequence identity with other MDPV isolates and 84.6% identity with the GPV isolates. This region shares over 99% identity among previously sequenced MDPV isolates and 95% identity among the related GPV isolates. This suggests that MDPV/PSU-31010 is divergent from all other sequenced MDPV and GPV isolates, and may represent a new group of avian parvoviruses.

Introduction In the mid-1960s, a highly fatal disease, characterized by anorexia, prostration and death within 2 to 5 days, was described in goslings (Derzsy, 1967; Woolcock et al ., 2000). This disease, named Derzsy’s disease, was caused by goose parvovirus (GPV) (Kisary & Derzsy, 1974). During the late 1980s a new disease caused by a related parvovirus appeared in Muscovy ducks (Cairina moschata ) in several parts of the world (Fournier & Gaudry, 1992; Jestin et al ., 1991; Lu et al ., 1993). This disease was characterized by mortalities of between 10 and 80%, nervous, locomotor and enteric signs, abnormal feather development and stunting (Barnes, 1997). Infection in older ducks caused degenerative skeletal muscle myopathy and growth retardation (Glavits et al ., 2005). The virus isolated from Muscovy ducks is closely related to the GPV based on Southern hybridization assays (Zadori et al ., 1994) and shares 81.9% sequence identity with GPV (Zadori et al ., 1995). The genome of Muscovy duck parvovirus (MDPV) consists of singlestranded DNA of 5132 nucleotides, and strands of both polarities are encapsidated (Zadori et al ., 1995). The genome contains two major open reading frames (ORFs). The left ORF (ORF1) encodes the pleiotropic regulatory proteins, and the right ORF (ORF2) encodes

the capsid viral proteins VP1, VP2 and VP3. The latter two proteins are produced by alternate splicing and are completely located within the carboxyl terminus of VP1 (Zadori et al ., 1995). Waterfowl parvoviruses can be categorized into GPV-related or MDPV-related groups based on their nucleotide sequences. Tsai et al . (2004) analysed the sequences of VP1 of five GPV and three MDPV isolates. The two groups of viruses differed by between 20.9 and 24.4% in nucleotide sequence, confirming the results reported by Zadori et al . (1995). The differences in nucleotide sequences within the MDPV group were only between 0.1 and 1.9%. Woolcock et al . (2000) isolated a MDPV from Muscovy ducklings in California and found the sequence of the VP1 gene of this isolate to be identical to the reference MDPV strain 89384, which was isolated in France (Jestin et al ., 1991). The aim of the studies described here were to isolate and characterize the viruses associated with an outbreak of disease in Muscovy ducklings in Pennsylvania, USA.

Material and Methods Case history. The first of a series of submissions of Muscovy ducklings from disease outbreaks with high morbidity and mortality was

*To whom correspondence should be addressed. Tel: /1 607 253 4032. E-mail: [email protected] Received 16 June 2006 ISSN 0307-9457 (print)/ISSN 1465-3338 (online)/06/60435-07 # 2006 Houghton Trust Ltd DOI: 10.1080/03079450601009563

436 B. Poonia et al . presented to the Animal Diagnostic Laboratory at Pennsylvania State University (ADL-PSU) on 30 October 1997. Similar cases were presented at ADL-PSU from additional farms through until early 1999. The sources included semi-integrated poultry companies and small independent farm enterprises in central and southeastern Pennsylvania. Most of the ducks were raised for sale into the northeast live bird marketing system. Flock sizes, housing and management styles were highly variable. Feed sources and formulations differed. The strain of Muscovy duck in the initial cases was a hybrid developed for meat production in Europe. Both males and females were represented among the cases, and some of the farms had multiple ages of ducks. Virus isolation in Muscovy duck embryos. At ADL-PSU, tissues from dead Muscovy ducks were collected. These tissues, including the spleen, liver, heart, skeletal muscle and intestines, were used for virus isolation. Tissue homogenates were prepared as a 1:10 dilution in viral transport medium, consisting of 500 ml minimum essential medium (MEM), 7.5 ml of 1 M Hepes buffer, 10 ml of 10 mg gentamicin/ml, 2.5 ml of 10,000 mg kanamycin/ml, 5 ml antibiotic/antimycotic mixture (10,000 units penicillin-G sodium/ml, 10,000 mg streptomycin sulfate/ml; 25 mg amphotericin B/ml in 0.85% saline) and 5 ml heat-inactivated horse serum, and centrifuged at 250 / g for 10 min at 48C. Supernatants were filtered through 0.45 mm filters and stored at 48C for use within 48 h or stored at 808C for use after 48 h. Fertile Muscovy duck eggs were obtained from breeder flocks in Pennsylvania that were free of MDPV antibodies, did not have a history of parvovirus disease and had not produced progeny suspected of parvovirus disease. The allantoic cavities of three to five 14-day-old embryonated Muscovy duck eggs/specimen were inoculated with 0.2 ml/egg of each of the filtered tissue homogenates. Allantoic fluids were harvested from inoculated eggs 6 to 7 days post inoculation and from embryos that died more than 24 h after inoculation. Serial egg passages were performed in attempts to isolate MDPV. Virus propagation in Muscovy duck embryo fibroblast cultures. Two sources of Muscovy duck embryos were used to prepare Muscovy duck embryo fibroblast (MDEF) cultures from 14-day-old embryos using routine techniques for primary avian embryo fibroblast cultures (Schat & Purchase, 1998) and maintained in MEM supplemented with 10% foetal bovine serum at 378C in 5% CO2. Initially, fertile eggs were used from the same sources that were used for embryo inoculations. For the preparation of viral DNA, specific pathogen free Muscovy duck eggs were imported from France through Grimaud Farms. MDPV/PSU31010 was passaged seven times in Muscovy duck embryos, followed by six passages in MDEF cultures. Virus was harvested between 5 and 4.2175mm7 days post inoculation when 70 to 90% of the cells showed cytopathic effects, characterized by complete destruction of the monolayer of cells. For DNA extraction, MDPV/PSU-31010 was passaged once at Cornell University in tertiary specific pathogen free MDEF

cultures seeded at 1.25 / 105 cells/ml. These cultures were incubated at 368C in MEM supplemented with 0.25% calf serum. When cultures showed cytopathic effects, virus was collected by freeze/thawing three times, followed by centrifugation at 250 / g , and the supernatant fluids were harvested and stored at /808C until use. Transmission electron microscopy. Samples of chorioallantoic fluid and supernatant from the MDEF cultures were centrifuged at 55,000 / g for 1 h. Pellets were resuspended in 200 ml distilled water and then filtered through a 0.2 mm filter. The filtered suspension was mixed with 200 ml of 4% sodium phosphotungstic acid, pH 7.0, and this was sprayed onto 400-mesh carbon-Formvar-coated copper grids. Prepared grids were examined and photographed using a Phillips EM-4000 electron microscope. Viral DNA extraction. Samples were treated with digestion buffer (100 mM NaCl, 10 mM Tris HCl (pH 8.0), 25 mM ethylenediamine tetraacetic acid, 0.5% sodium dodecyl sulphate) containing 100 mg proteinase K/ml (Sigma, St Louis, Missouri, USA) and DNA was extracted with phenol:chloroform:isoamyl alcohol (50:49:1) and precipitated with ethanol (Sambrook et al ., 1989). Polymerase chain reaction assays. Six sets of primers were used. The sequence of primer pairs 1 and 3 to 6, the expected size of the amplicons, the genome location based on the FM strain (GenBank accession number U22967) (Zadori et al ., 1995), and references are presented in Table 1. The sequences for primer pair 1 were provided by Dr J. Pederson (Ames, Iowa, USA) and correspond to nucleotides 2615 to 2634 and 3189 to 3208 of the MDPV FM strain. Primer pair 2 was derived from Chang et al . (2000) and was based on the consensus sequence for VP3 of the FM strain of MDPV and GPV (GenBank accession number U25749) (Zadori et al ., 1995). The forward primer of primer pair 1 and the reverse primer for primer pair 2 span nucleotides 2615 to 3723 of U22967. The forward primer for primer set 2 was located within the 3? end of the amplicon expected using primer set 1. PCR assays were conducted using the touchdown protocol described by Xing & Schat (2000). The touch-down steps consisted of two cycles of 708C for 120 sec, 698C for 115 sec, 688C for 110 sec, 668C for 100 sec, 658C for 95 sec, 638C for 85 sec, 618C for 75 sec and 608C for 70 sec, and these were followed by 30 cycles of 958C for 30 sec, 558C for 30 sec and 728C for 120 sec, with a final incubation at 708C for 7 min. All fragments were cloned and sequenced using the Topo TA cloning kit with the PCR@4-TOPO vector (Invitrogen Corp, Carlsbad, California, USA) according to the manufacturer’s instructions. Four independently selected plasmids were sequenced for amplicons generated with primer sets 1 and 2. Sequencing was performed by the DNA sequencing facility at Cornell University using Big Dye terminators from Applied Biosystems, Inc. (Foster City, California, USA) and primers provided with the Topo TA cloning kit. Sequencing reactions were run on ABI

Table 1. Primer sets used in PCR assays Primer set

1

2 3 4 5 6

a

Genome locationa (nucleotides)

Expected amplicon size (base pairs)

Reference

5?-cctggctataagtatcttgg-3?

2615 to 2634

593

J. Pederson (personal communication)

5?-gtagatgtggttgttgtagc-3? 5?-ccaagctacaacaaccacat-3? 5?-tgagcgaacatgctatggaagg-3? 5?-gatgtgcctggtttgtctct-3? 5?-tcatttttccctcctcccacc-3? 5?-gctctacggacctgcgaccac-3? 5?-ggaaagtacaaagcccctattatt-3? 5?-gatgtgcctggtttgtctct-3? 5?-ccaacatacttatagccagg-3? 5?-atagctatgtctacttttttag-3? 5?-aatttacagattctgagtca-3?

3189 to 3208 3185 to 3204 3702 to 3723 629 to 648 1679 to 1700 1545 to 1566 2594 to 2616 629 to 648 2615 to 2634 2444 to 2465 4632 to 4650

539

Chang et al . (2000)

Sequence

1071

This paper

1071

This paper

2005

This paper

2206

Chu et al . (2001)

Based on the sequence published by Zadori et al . (1995) (GenBank U22967 for pairs 1 to 5 and U25749 for pair 6).

Muscovy duck parvovirus 437 3700 DNA sequencers. The combined sequence was compared with other parvovirus sequences in GenBank using the Clustal V method incorporated in the MegAlignTM program within the Lasergene 6.1 package (DNA Star, Inc., Madison, Wisconsin, USA). Accession number. The sequence was submitted to the GenBank nucleic acid database and has been assigned accession number DQ413026.

Results Clinical signs and lesions. In general, locomotor dysfunction, weakness, recumbency and increased mortality of Muscovy ducklings started at 9 to 10 days of age and peaked at 2 to 2.5 weeks. During the acute phase, morbidity was between 40 and 60%, and mortality was between 10 and 40%. Sequelae in recovered flocks were poor growth, decreased feed conversion efficiency, lingering locomotor deficits and an increased incidence of ascites. Total flock mortality at the end of the growout period typically ranged from 20 to 50%. Gross lesions were subtle, inconsistent or absent. Decreased skeletal muscle mass and pallor of the skeletal muscles of the leg were observed in some birds. Myocardial pallor, hydropericardium, cardiomegaly, splenomegaly, ascites, and fibrin accumulation on the epicardium and capsular surfaces of the spleen and liver were sometimes seen.

Figure 1. Transmission electron micrograph of Muscovy duck parvovirus isolate DPV/PSU-31010 in MDEF cultures, / 24,000. Bar /100 nm.

Microscopically, the most characteristic lesion was moderate to severe degenerative rhabodomyopathy. Mild to moderate myocarditis, fibrinous epicarditis, periportal hepatitis and peripheral neuritis were seen in some sections. Nuclear changes suggestive of intranuclear viral inclusion bodies were seen within occasional myocardial tissues.

DQ413026 U22967 X75093 Z68272 U25749

2615

C CT GG C TAT AA G T AT C T T G G G CC TG GT A A C G G C C T T CA T AA AG G C C CA CC G G T CA A T AA A G C GG AC A G C GT CG CG C TT G A G C A C G AT AA A GC GT A T G AC G ------------------ -- ------- --- -- ----G -- -----G ----- T- --- ----------- -- ------- --- -- --- ----------- -C --- C ------------------ ------- --- ------- -G- ----- -G--- --T-- ----------- -- ---------- -- ----------- --- -- -C- --C -- - - --- - --- -- -- - -- - - - -- -- - -- - - - - - - - - G -- -- -- - G - -- - -T - - - -- - -- - - - -- -- - - - -- - - - - - - -- - - - -- - -- -- - -- -- - C - -- C - - - -- -- -- - - - - -- -- - - - - - - -- -- -- - -- - - - - G -- - - -- -G - -- -- T- - -- -- - - - - - - -- - - - - -- -- -- - -- -- - - - -- - C -- - - - -- -- - -- C

2714

DQ413026 U22967 X75093 Z68272 U25749

2715

A AC A AC TC A AA G C A GG AG A CA A T C C A TA T AT A A A AT T TA A T C AC G C AG A C CA A G A AT TC A T A GA CA GC T T GC A A G G A G AT AC T TC CT TT G GA A GA A A T C T -G - -G -- - -- G- -- - - - - - - - - C- - C -- -- - - - - - - -- -- -- - -- - - - -T -- - -- -- - T - -- - - T- AT C - - -- -- - T- -- - - C - - -- -- - -- G- C- - C- -G - -G -- - -- G -- - -- - - -- - -C -- C -- - - - - - - - - -- - -- -- - - - -- -T -- - - -- - - T - - - -- T- AT C -- -- - -- T- - - - - C - - -- -- - -- G- C - - C- - G- - G- -- - -G -- - -- -- - -- - C - - C - -- -- - - - -- - -- - - -- - - - - -- T -- - - - -- -T - - - -- T- AT C -- - - - - - T - -- -- C -- -- - - - -- G -C - - C - -G--G--T----- -- --- ----C-- A-- ---------- ----- ---------- -- ---T-----T- --C-- ----A C- -CCAG--A--- --- G- T-- ---

281 4

DQ413026 U22967 X75093 Z68272 U2 5749

2815

AGGAA AAGCTGTAT TTCAAGCTAA AAAAAGAA TACTA GCGCC TTT CGGGC TA GTA GAAGAAC CC TCAAACACGGC TCC AA CAA AAAAGGGTAGT GG GAAA C--------C-- --- C-- ------- --- -----T---- A---- --A --C---- -- --------TGT --- -- T---- --TG-T------A --- -- --A --C -- - -- -- - C- -- - -C -- - -- - - - - - - - -- - - -T -- - -A -- -- - - A -- C - -- - - - -- - - - - - -T GT -- - -- - - - - - - -T G -T -- - -- - A - -- -- -- A - -C--------C---- -C-- -- ---- ----C-T- -CT---A --- A--T--C--- ----- ----- -T GT--------- --- TG -T------A- -- -- -- A--T- - -- -G - -- -- - -- -- - G --C - - - - -- C -T -- CT - -- A - - -A -- A -- C - - - - -- -- -- -T - - T GT -- - -- -- - -- A - T G- T - - - -- AA A -- C A - -- -- G

2 91 4

DQ413026 U22967 X75093 Z68272 U25749

2915

CT AA C AG AT C AT TA T CC CG T TG TA A AG A AG CC AA A A C T A A GT G AA G AA A G T G C AG AA CC T G C A G T T AA CG G TG GA G GA GA AT C CA G T T C C A A CA CT G CA G -- - - --- - - --C G - C- - T A - A -- - - - -- - - - - T - -- T -- T C -- - - - -- - AC T - T CC T T- A C - TA G- - - T A- -- -- - -- - - - G - A - -- G- A GC TG C C A -C - -- - -- -- - -- CG - C- - T A - A -- - -- -- - - -- T - - - T- - T C- -- - - - - - A CT -T C C T T- A C- T A G- - - T A - - - -- - -- -- -G - A - - - G- A GC TG C C A - C -- -- - -- -- - -C -- C -- T A - A- -- - -- -- - -- T - - -T -- T C- - - - - - - -A CT - TC CT T - A C - T AG - -- TA - -- -- - -- -- - G - A- -- G- A G CT G C C A -C --T--T--C---- -C--G- -A-- T----- ---T -----T -C C--G- --GTCAG T-CGGG A-GT- G--G- A---CC -T-C--GA-GGA GG -GC --CC- -G-

3 01 4

DQ413026 U22967 X75093 Z68272 U25749

3015

AA GG C AC CG A GC CT G TG G C A G CAT C T AA TA T GG CA G AG G G C GG CG G CG GA AA C A T GG G C G A C T C TA CA G GG GG T G C CG AC GG A GT G G G T A A T TC CT C AG G - -- - -T -- - -A -- - -- - - - -- -- C - - -- C - - - - - - - -- - -A -- A A - -- - - GC T - - -- -- - - - -- -G - - - -- - - -- - - - -T - - - -- -- -- - - - G -- - - -- -----T----A--- --- -- ----C - ---C- -- --- ---- -A- -AA-----GC T-- -- ----- ---G--- ------ ----T --- -- ----- -- G--- ----- -- - T- -- - A- -- - -- - - - -- -C - -- -C - -- -- - - --- - A -- AA - -- -- GC T -- -- - - - - - - - -G -- - -- - - - - - -- -T -- - -- - -- - - - - G- -- - -- - G- - -- -- - -A -- - -- - - - -- -- - -- G- A - - - - - -- -- - - A-- A - - - - - - GC T -- -- -- - - - -- -G - - - -- - - -- - - - -T -- - - - -- -- - -- G -- - - - - -

3114

DQ413026 U22967 X75093 Z68272 U25749

3115

A AAT T G GC AT T GC G A T TC CC A AT G G T TG GG T G A CA C AG T C A TT AC A AA AA C A A C C A GA A C C T GG GT CC T C C C A AG CT A CA AC A AC CA CA T CT A C A AA GC T - - -- -- - -- -- - - --- - - -- - - - -- C- - -- A- - -- -- - -- -- - -- C -- G- -T - -A -- - - - - - - -- - - - - G - -- -- - -- -- - - - -- - - -- - - - -- -- - -- C --------------- --- ------- C- ---A- - ---- ------ --C-- G--T- -A----------- --- G- ---- -------- ------ ----- --- -- C -- - - --- - - -- -- - -- -- - -- -- - - C -- - -A - - - - - -- - -- -- - - C -- G - -T - - A- - - - - - - -- -- -- - G- - - - - - - -- - - - -- - -- -- - -- -- - - - - - C - - - --- - - -- -- - -- -- - -- - - - -- A- - -- AA - -- -- - -- -- C -- - - - G- -C - -- -- - - - - - - -- - - - - G- -- -- - -- -- - - - -- - - -- - - - -- -- - -- A

3214

D Q4 13026 U22967 X75093 Z68272 U25749

3215

A TC A CA AG T GG AA C CA GT C AA GA C A C AA A T AT C C A GT AC G CC GG T T A CA G TA C C C CC TG G G G AT AC TT T G AC T T C A A C CG CT T TC AC T G C CA C TT C T C T C -- C -- -- - C- -- - -- -A - -- - - - -T -- - -- - - - -- -- - T - -T - -A - - - -- C- - - - -- - - - - - G - -- -- - -- T- -- - -- A- A - - C- - - -- - - - T- -- - -- -- C -- -- - C- -- - -- -A - - --- - - T - -- - -- - - - -- -- T -- T- - A - -- - - C- - - -- -- - - - - G- -- -- - -- T - - -- -- A - A - - C - -- -- - -- T- - - - -- - -C - -- -- C -- -- - -- A- - -- -- - T - -- - -- - - - -- -- T -- T- - A - -- - - C- - - - -- -- - - - G- -- -- - -- T - - - - - - A- A- - C- -- - - - -- T -- - - - --- T -- -- - C- -- - -- -C - -- -- - -- -- - -- - - - -- -- - T - -A - - A- - - -- -- - - - - -- - -- - G - -- -- - -- T- -- - -- C- C - - C- - - -- - - - C- -- - -- C

331 4

DQ413026 U22967 X75093 Z68272 U25749

3315

C AA G A GAC T G GCA G A GA C T C AT CA A TA A T C AT TG G GG GA T CA GA C C G AA A GC G CT CA AG T T C AA A A TT T T C AA T G T CC AG GT C AA AG A A G TC A C AA C G C A -- - -- -- - -- -- - -- -- - -- -- - -- C- - C- -- - - --- - - -T -- - - - -- - - -- A - -- - - A - - -- - G- -A - - - - - - -- G- -A - - T - - - - -- - -- -- G- - A- -- - - -- -- - -- - - - -- -- - -- -- - - C -- C -- - - - -- -- - -T -- - - - -- - - -- A - -- - - A - - -- - G - -A - - -- - - - - G - -A -- T- - - - - - - -- -- G- - A -- -- - -- -- - -- - - - -- -- - - --- - - C-- C - -- -- - -- -- - T- -- - - - -- - -- A - - -- -A - - - -- G - -A - - -- - - - - G - -A -- T -- -- - - - -- - - G- - - - -- T -- -- - -- -- - -- -- - -T -- - - - C- - C -- - - - -- -A - -C -- - - - -- - CT - T - -T - -A - - -- - G- - - - -- -- -- - -- - A - - - - - -- -- - -- -- - - - -- -

3 414

DQ413026 U22967 X75093 Z68272 U25749

3415

GG AT C AG AC G AA AA C AA T T G CA AA C AA TC T CA C A T C TAC T A TC CA G GT AT T C A CG G AT G A T G A GC A TC AG C TC CC G TA TG TT C TT G G C T C C G CG AC A GA A -- - C -- -- - A- -G - -T - - - -T -- - - - -C - -T - - C - - -- - A- -- - - - A- - -- - - - -- - -A - - -- A - -- - - - -- G -- C - -- - -- - - G -- -- - G- -C - - G -- G - -- C -- -- - A- -G - -T - - - -T -- - - --C - - T- -C - -- -- A -- -- - - A- - - -- - - - -- -A - - - -A - -- - - - -- G -- C - -- - -- - - G -- - - - G - - C -- G -- G --- C - -- -- A -- G- - T- - - - T- -- - -- C- - T- -C - -- -- A -- - - - - A - -- - - -- - - -- A - - - - A -- -- -- - -G -- C -- -- -- - -G - - - - - G - -C -- G -- G -- - - --- - - A- -G - -C -- - -- -- - - - -- - -- - - C - - -- - A- -- - - A -- C - -T - - - -- -- - - - -- - -- - - A -- - -- - - -- - -- -- G -- -- - G- -T - - G - --

3514

DQ413026

3415

G GTA C G ATG C CG CC G T TC C C G TC T G A TG TC T A T GC C CT G C C AC AG T AC GG G T A CT G TA C C A TG C AC AC CA A CC AG A A CGG GG C T AG A TT C A T GA CA G AA G

3614

-- G - -- - - - - - A - - - - - - - -C -- - - - -- - G - - - - - - T -- - - C - - -- - - - - C - - - - - C - - A - - - - -- - - - - - - -- - - G T - - A - - G -- - -- - - A T G A C A G - A -- G--------A----- ---C- -------G------T--- -C- -- -----C -----C--A--- ---- ------ ---GT--A --G-- -- --- ATGAC AG-A -- G -- -- - -- - A - -- - - - -- C - - -- - - - - G - - - - - - T- - - - C- -- - -- - - C -- - - - C- - A - - - -- - - -- -- - - - -- G T - - A - - G - - - - - - -A TG A C A G - A - -C- -C -- - -- -- ----- --- ----- ----- ----------G -- ----- -- -----C--A-- ----- -- --- -- ---T- -A--AC-G-- --A TGA CCGTA

U22967 X75093 Z68272 U25749 DQ413026 U22967 X7509 3 Z68272 U25749

3615

C G C C T T C T A C T G T C T T A G A A T A C T T C C C C A G C C A A A T G C T G A G A A C A G G G A A T A A C T T C G A G T T C T C T T T T G A G T T T G A G A G T G T T C C CT T C C A T A G C A T G TG - C- T C T A- TG - -- - - G -- - - - - - - - - -- T - - G - -- - -- - - - - - - -- - - - - - - T - -T - - A -- - A G -- - -- - - - - - - - A G A A -- -- - - - - - - -- - - - - GT G -C -T C TA -T G - - - - - G - - - - -- - - - -- - T - -G - - - - - - - - - -- - - - - - -- - - T - - T - - A - - - A G- - - - -- -- - - - - A G A A - - - - -- - - - -- - - - - - GTG -C-TC TA-TG ----- G-- -- ----- ---T- -G--------- -- --- -- ----T --T-- A---A G-- ---- ------ AGAA---- ----- --- -- --GTG-A-TCTACTG- ----G -- --- -- --T--T-- G------- ----- -- C-- C- --- -T --- ---A-A---- -C- -- --AGA A-----T---- -- --- --

D Q413026 U22967 X75093 Z682 72 U 25 7 4 9

3715

GTTCGCTCA --- ------------ ----------------- -

3714

3723

Figure 2. Sequence comparison for the 1109 nucleotide fragment of MDPV/PSU-31010 (GenBank accession number DQ413026) with three MDPV isolates (GenBank accession numbers U22967, X75093, and Z68272) and one goose parvovirus (Genbank accession number U25749).

438 B. Poonia et al .

AY382883 (GPV 82-0308) AY382887 (GPV 86-1015) AY382884 (GPV 82-0321) AY382889 (GPV 01-1001) AY382885 (GPV 82-0321v) AY382886 (GPV 82-0408) AY382888 (GPV 99-0808) U25749 (GPV B) U34761 (GPV SHM319) AF416726 (GPV YG) AY506547 (GPV HG5-82) AY512830 (GPV GD) AY382891 (DPV 90-0215) AY382893 (DPV 97-0104) AY382890 (DPV 90-0219v) AY382892 (DPV 90-0219) AY510603 (MDPV GD) U22967 (MDPV FM) X75093 (MDPV FM) Z68272 (MDPV 89394FRANCE) PSU-31010

10.8 10

8 6 4 Nucleotide Substitutions (x100)

2

0

Figure 3. Phylogenetic tree based on the sequence of the 1109 nucleotide of MDPV isolate MDPV/PSU-31010 and available sequences in GenBank for MDPV and GPV. The GenBank accession numbers are shown with the parvovirus type and strain/isolate name in parentheses.

Epidemiology. By mid-1999, approximately 20 premises in Pennsylvania were affected with MDPV disease. Epidemiological evidence strongly suggested that the virus was introduced into Pennsylvania via hatching eggs and 1-day-old ducklings from the same breeder company. In some instances, there was potential for subsequent spread between farms by visitors. The disease was seen in successive flocks on some of the farms despite cleaning and disinfection. Initial laboratory tests. Initial assays for ionophores, vitamin E and selenium failed to identify an aetiology. Routine bacteriology, mycology, serology and conventional virus isolation did not yield significant or consistent findings. As additional case histories revealed a common breeder source for all cases, suspicion shifted to vertically transmitted diseases and parvovirus was first considered as a possible aetiology (Dunn et al ., 1999). Convalescent blood samples obtained from diseased flocks were submitted to the National Veterinary Services Laboratory (Ames, Iowa, USA) and were found to contain antibodies against GPV by indirect immunofluorescence assays. Virus isolation and propagation. Embryo deaths occurred on the second egg passage and parvovirus particles were detected in the allantoic fluids by transmission electron microscopy (Figure 1). Five additional passages were performed in Muscovy duck embryos and consistently induced embryo mortality. MDEF cultures were inoculated with preparations prepared from embryos to propagate virus isolates. Cytopathic effects were not observed until passages 4 to 5, and major destruction of monolayers occurred after passage 6. MDPV required

initial isolation in Muscovy duck embryos before it could be adapted to MDEF cultures. DNA sequence. Primer sets 1 and 2 produced the expected amplicons of 593 and 539 base pairs, respectively, while all other primer sets failed to amplify the expected fragments. Sequencing of four independently selected plasmids confirmed that these amplicons were derived from MDPV sequences, and the combined sequence of 1109 bases spanned nucleotides 2615 to 3723 of ORF2, including parts of all capsid proteins (Figure 2). The putative unusual start codon ACG for VP2 is located at nucleotides 2885 to 2887 and the start codon for VP3 is found at nucleotides 3044 to 3046. Comparison with one GPV and three MDPV sequences detected many differences between MDPV/PSU-30010 and both the MDPV and the GPV sequences (Figure 2). Similar sequences in the GenBank database that had greater than 80% identity with MDPV/PSU-30010 were used to generate a phylogenic tree using MegAlignTM 6.1 (DNASTAR Inc.). The sequence of MDPV/PSU-31010 differed considerably from those of characterized isolates (Figure 3). The differences in the nucleotide sequence (Figure 2) also resulted in differences in the predicted amino acid sequences for VP1 and VP3 (Figure 4). The predicted amino acid sequence for VP2 was not examined because of the unusual start codon.

Discussion Prior to the outbreak described here, MDPV disease had not been recognized in the Americas, although around the same time MDPV was isolated in California (Dunn et al ., 1999; Woolcock et al ., 2000). The clinical signs, gross and microscopic lesions, and clinical course of the

Muscovy duck parvovirus 439

A. VP1 1 1

- - - - - - - - - - - - - - - - - - - - - - - - - - - - - M S T F L E K F E D W Y E T A A A S W R H L K A G A P K P K

PSU-31010 U22967

1 31

- - - - - - - - - - - - - - - - - - - - - - - - - P G Y K Y S N Q Q S Q S V S T D R K P Q R K D N N R G F V L P G Y K Y

PSU-31010 U22967

6 61

L G P G N G L H K G P P V N K A D S V A L E H D K A Y D E Q V G P G N G L D K G P P V N K A D S V A L E H D K A Y D Q Q

PSU-31010 U22967

36 91

L K A G D N P Y I K F N H A D Q E F I D S L Q G D T S F G R L K A G D N P Y I K F K H A D Q E F I D N L Q G D T S F G G

PSU-31010 U22967

66 121

N L G K A V F Q A K K R I L A P F G L V E E P S N T A P T K N L G K A V F Q A K K R I L E P L G L V E E P V N M A P A K

PSU-31010 U22967

96 151

K G S G K L T D H Y P V V K K P K L S E E S A E P A V N G G K S S G K L T D H D P I V K K P K L S E E N S P S P S N S G

PSU-31010 U22967

126 181

G E S S S N T A E G T E P V A A S N M A E G G G G N M G D S G E A S A A A T E G S E P V A A P N M A E G G S G A M G D S

PSU-31010 U22967

156 211

T G G A D G V G N S S G N W H C D S Q W L G D T V I T K T T A G G A D G V G N A S G N W H C D S Q W L G D T V I T K T T

PSU-31010 U22967

186 241

R T W V L P S Y N N H I Y K A I T S G T S Q D T N I Q Y A G R T W V L P S Y N N H M Y Q A I T S G T N P D S N T Q Y A G

PSU-31010 U22967

216 271

Y S T P W G Y F D F N R F H C H F S P R D W Q R L I N N H W Y S T P W G Y F D F N R F H C H F S P R D W Q R L I N N H W

PSU-31010 U22967

246 301

G I R P K A L K F K I F N V Q V K E V T T Q D Q T K T I A N G I R P K A L K F K I F N V Q V K E V T T Q D Q T K T I A N

PSU-31010 U22967

276 331

N L T S T I Q V F T D D E H Q L P Y V L G S A T E G T M P P N L T S T I Q I F T D N E H Q L P Y V L G S A T E G T M P P

PSU-31010 U22967

306 361

F P S D V Y A L P Q Y G Y C T M H T N Q N G A R F - - - - F P S D V Y A L P Q Y G Y C T M H T N Q S G A R F N D R S A

PSU-31010 U22967

Figure 4. Predicted amino acid sequence for VP1 (4a) and VP3 (4b) of Muscovy duck parvovirus isolates PSU-31010 and U22967. Amino acids that differ between the two isolates are denoted in bold.

440 B. Poonia et al .

B. VP3 1 1

M A E G G G G N M G D S T G G A D G V G N S S G N W H C D S M A E G G S G A M G D S A G G A D G V G N A S G N W H C D S

PSU-31010 U22967

31 31

Q W L G D T V I T K T T R T W V L P S Y N N H I Y K A I T S Q W L G D T V I T K T T R T W V L P S Y N N H M Y Q A I T S

PSU-31010 U22967

61 61

G T S Q D T N I Q Y A G Y S T P W G Y F D F N R F H C H F S G T N P D S N T Q Y A G Y S T P W G Y F D F N R F H C H F S

PSU-31010 U22967

91 91

P R D W Q R L I N N H W G I R P K A L K F K I F N V Q V K E P R D W Q R L I N N H W G I R P K A L K F K I F N V Q V K E

PSU-31010 U22967

121 121

V T T Q D Q T K T I A N N L T S T I Q V F T D D E H Q L P Y V T T Q D Q T K T I A N N L T S T I Q I F T D N E H Q L P Y

PSU-31010 U22967

151 151

V L G S A T E G T M P P F P S D V Y A L P Q Y G Y C T M H T V L G S A T E G T M P P F P S D V Y A L P Q Y G Y C T M H T

PSU-31010 U22967

181 181

N Q N G A R F - - - - - - - - - - - - - - - - - - - - - - N Q S G A R F N D R S A F Y C L E Y F P S Q M L R T G N N F

PSU-31010 U22967

Figure 4 (Continued)

cases in Pennsylvania were comparable with those previously described (Dalibard et al ., 1993). The MDPV/PSU-31010 isolate is of interest because the nucleotide sequence, and the predicted amino acid sequences for VP1 and VP3 are clearly different from other MDPV and GPV sequences. The approximately 1.1 kb region within ORF2 shares over 99% sequence similarity among MDPV isolates, and the GPV isolates share more than 95% similarity. However, the available sequence of the MDPV/PSU-31010 isolate has an average sequence identity with other MDPV and GPV isolates of 85%. Most of these isolates are from Europe or Asia. Another US isolate, the MDPV isolate from California (Woolcock et al ., 2000), had 100% sequence identity with the reference strain 89384 (Z68272) (Jestin et al ., 1991), whereas the MDPV/PSU-31010 isolate shared only about 85% identity with Z68272. These results clearly show that the MDPV/PSU-31010 isolate is markedly different from any of the MDPV or GPV isolates described in the literature. The differences are most probably also present in other parts of the genome because the other primer combinations failed to amplify the expected fragments. The differences are of considerable interest because these are located in the coding region of the structural viral proteins. The start codons for VP1, VP2 and VP3 are located at nucleotides 2450 to 2452, 2885 to 2887, and 3044 to 3046, respectively, in the MDPV FM genome. The VP2 and VP3 start codons for MDPV are located at the same locations as for the FM isolate. The predicted MDPV/PSU-31010 VP2 start codon has the same unusual sequence, ACG, as that reported for the reference strain 89394 from France (Zadori et al ., 1995).

The reasons for this divergence are not clear. The number of passages (seven in Muscovy duck embryos and seven in MDEF cultures) is unlikely to account for such variation. An MDPV vaccine strain (90-0219V), which had undergone more than 100 passages in embryonated eggs or embryo fibroblast cultures, exhibited only a 0.1% nucleotide difference from its parental field strain, whereas a GPV vaccine strain (82-0321V), which had undergone a total of 70 passages in embryonated eggs or embryo fibroblast cultures, exhibited only a 3.3% nucleotide difference from its parental field strain (Tsai et al ., 2004). It is possible that MDPV/PSU-31010 actually represents a new parvovirus and additional studies will be needed to completely resolve this question, including the cloning and sequencing of the complete MDPV/PSU-31010 genome. Acknowledgements The authors thank Dr A. Castro and Dr D. Gaudry for their contributions to this study, and Kathy Hillard (ADL-PSU), Tom Doman (ADL-PSU) and Priscilla O’Connell (Cornell University) for excellent technical assistance. The studies at Cornell University were supported in part by a grant from Grimaud Farms, Stockton, California, USA. References Barnes, H.J. (1997). Muscovy duck parvovirus. In B.W. Calnek, H.J. Barnes, C.W. Beard, L.R. McDougald, & Y.M. Saif (Eds) Diseases of Poultry 10th edn (pp. 1032 1033). Ames, IA: Iowa State University Press.

Muscovy duck parvovirus 441 Chang, P.-C., Shien, J.-H., Wang, M.-S. & Shieh, H.K. (2001). Phylogenetic analysis of parvoviruses isolated in Taiwan from ducks and geese. Avian Pathology, 29 , 45 49. Chu, C.Y., Pan, M.J. & Cheng, J.T. (2001). Genetic variation of the nucleocapsid genes of waterfowl parvovirus. Journal of Veterinary Medical Science, 63 , 1165 1170. Dalibard, V., Plassiart, G., Cherel, Y., Hurtrel, M. & Wyers, M. (1993). Characterization of histological lesions of spontaneous parvovirus of the Muscovy duck (Carina moschata). Differential histopathological diagnosis with reovirus. Recueil de Me´decine Ve´te´rinaire, 169 , 763 772. Derzsy, D. (1967). A viral disease of goslings. I. Epidemiological, clinical, pathological and aethiological studies. Acta Veterinaria Academiae Scientiarum Hungaricae, 17 , 443 448. Dunn, P.A., Nesselrodt, A.J., Miller, W.L., Castro, A.E. & Ziegler, A.F. (1999). Case report: Muscovy duck parvoviral disease in Pennsylvania ducklings. In Proceedings of the 71st Northeastern Conference on Avian Diseases (p. 34), Blacksburg, VA, USA. Fournier, D. & Gaudry, D. (1992). Recent discoveries on waterfowl pathology: a new parvovirus of Muscovy ducks in France *Field vaccination trials. In M.S. McNulty & J.B. McFerran (Eds), Proceedings of the Commission of the European Communities Meeting on Virus Diseases of Poultry *New and Evolving Pathogens (pp. 183 194). Brussels: European Commission. Glavits, R., Zolnai, A., Szabo, E., Ivanics, E., Zarka, P., Mato, T. & Palya, V. (2005). Comparative pathological studies on domestic geese (Anser anser domestica) and Muscovy ducks (Cairina moschata) experimentally infected with parvovirus strains of goose and Muscovy duck origin. Acta Veterinaria Hungarica , 53 , 73 89. Jestin, V., le Bras, M.-O., Cherbonnel, M., le Gall, G. & Bennejean, G. (1991). Mise en evidence de parvovirus (virus de la maladie de Derzsy) tres pathogenes dans les elevages de canards de Barbarie. Recueil de Me´decine Ve´te´rinaire, 167 , 849 857.

Kisary, J. & Derzsy, D. (1974). Viral disease of goslings. IV. Characterization of the causal agent in tissue culture system. Acta Veterinaria Academiae Scientiarum Hungaricae, 24 , 287 292. Lu, Y.S., Lin, D.F., Lee, Y.L, Liao, Y.K. & Tsai, H.J. (1993). Infectious bill atrophy syndrome caused by parvovirus in a co-outbreak with duck viral hepatitis in ducklings in Taiwan. Avian Diseases, 37 , 591 596. Sambrook, J., Fritsch, E.F. & Maniatis, T. (1989). In Molecular Cloning. A Laboratory Manual , 2nd edn. Cold Spring Harbor, NY: Cold Spring Harbor Laboratory Press. Schat, K.A. & Purchase, H.G. (1998). Cell-culture methods. In D.E. Swayne, J.R. Glisson, M.W. Jackwood, J.E. Pearson, & W.M. Reed (Eds.), A Laboratory Manual for the Isolation and Identification of Avian Pathogens 4th edn (pp. 223 234). Kennett Square, PA: American Association of Avian Pathologists. Tsai, H.J., Tseng, C.H., Chang, P.C., Mei, K. & Wang, S.C. (2004). Genetic variation of viral protein 1 genes of field strains of waterfowl parvoviruses and their attenuated derivatives. Avian Diseases, 48 , 512 521. Woolcock, P.R., Jestin, V., Shivaprasad, H.L., Zwingelstein, F., Arnauld, C., McFarland, M.D., Pedersen, J.C. & Senne, D.A. (2000). Evidence of Muscovy duck parvovirus in Muscovy ducklings in California. Veterinary Record , 146 , 68 72. Xing, Z. & Schat, K.A. (2000). Expression of cytokine genes in Marek’s disease virus-infected chickens and chicken embryo fibroblasts. Immunology, 100 , 70 76. Zadori, Z., Erdei, J., Nagy, J. & Kisary, J. (1994). Characteristics of the genome of goose parvovirus. Avian Pathology, 23 , 359 364. Zadori, Z., Stefancsik, R., Rauch, T. & Kisary, J. (1995). Analysis of the complete nucleotide sequences of goose and muscovy duck parvoviruses indicates common ancestral origin with adeno-associated virus 2. Virology, 212 , 562 573.

Avian Pathology (December 2006) 35(6), 1 2

Non-English Abstracts

Isolation and molecular characterization of a new Muscovy duck parvovirus from Muscovy ducks in the USA Bhawna Poonia1, Patricia Dunn2, Huaguang Lu2, Keith Jarosinski1 and Karel Schat1* 1

Department of Microbiology and Immunology, College of Veterinary Medicine, Cornell University, Ithaca, NY 14853, USA, and 2Animal Diagnostic Laboratory, Department of Veterinary and Biomedical Sciences, Pennsylvania State University, University Park, PA 16802, USA

Entre 1997 et 1999 plusieurs cas d’une nouvelle maladie observeé chez les canards de Barbarie ont e´te´ rapporte´s en Pennsylvanie, USA. Les cas e´taient caracte´rise´s par un disfonctionnement locomoteur, de la faiblesse, des sujets couche´s, 4060% de morbidite´ et 1040% de mortalite´. Les le´sions microscopiques les plus caracte´ristiques ont e´te´ une rhabodomyopathie mode´reé a` aigue¨. Dans le but de caracte´riser l’agent e´tiologique, des essais d’isolement de virus ont e´te´ reálise´s a` partir de la rate, du foie, du cœur, des muscles du squelette et de l’intestin par inoculation a` des embryons de canard de Barbarie aˆge´s de 14 jours avec des broyats de tissu. Les mortalite´s sont apparues au 2e`me passage sur œufs et des parvovirus on e´te´ isole´s par passages en se´rie du liquide allantoı¨dien d’embryons morts et puis sur des cultures de fibroblastes d’embryon de canard de Barbarie (MDEF). En microscopie e´lectronique, des particules de parvovirus ont e´te´ observeés a` partir des liquides allantoı¨diens et des surnageants des cultures de MDEF. Deux fragments geńomiques, comprenant 1108 nucleótides au niveau du cadre ouvert de lecture droit qui code les proteínes virales de structure (VP)1, 2 et 3, ont e´te´ amplifie´s par PCR a` partir d’une des souches isoleés, de parvovirus du canard Barbarie (MDPV)/PSU-31010. La comparaison de ce fragment aux se´quences disponibles d’autres MDPV et des souches), virus apparente´, de parvovirus de l’oie (GPV) a montre´ qu’il y avait seulement 84,5% d’identite´ avec les autres souches de MDPV et 84,6% d’identite´ avec les souches de GPV. Cette re´gion pre´sente plus de 99% d’identite´ avec celle des MDVP se´quence´s ante´rieurement et 95% d’identite´ avec celle des GPV), virus apparente´. Ceci sugge`re que la souche MDPV/PSU-31010 est diffe´rente des autres souches de MDPV ET GPV se´quenceés et qu’elle peut repre´senter un nouveau groupe de parvovirus aviaires. Zwischen 1997 und 1999 wurde aus Pennsylvania von mehreren Fa¨llen einer neuen Erkrankung bei Moschusenten berichtet. Das Krankheitsbild war durch Bewegungssto¨rungen, Schwa¨che und Festliegen bei einer Morbidita¨t von 40-60 % und einer Mo¨rtalita¨t von 10-40 % gekennzeichnet. Histopathologisch war eine gering- bis hochgradige degenerative Rhabdomyopathie die charakteristische Vera¨nderung. Zur Ermittlung des a¨tiologischen Agens wurde mittels Inokulation von Gewebehomogenaten in 14-ta¨gige embryonierte Moschusenteneier eine Virusisolierung aus Milz, Leber, Herz, Skelettmuskel und Darm versucht. Nach zwei Eipassagen begannen die Embryonen zu sterben und Parvoviren wurden durch weitere Passagierung der Allantoisflu¨ssigkeit von toten Embryonen im Ei und dann in Moschusentenembryofibroblasten (MEEF)-Kulturen isoliert. Elektronenmikrokopisch konnten in den Allantoisflu¨ssigkeiten und den MEEF-Kulturu¨bersta¨nden Parvoviruspartikel nachgewiesen werden. Aus einem der Isolate, dem Flugentenparvovirus (MEPV)/PSU-31010 wurden mittels Polymerasekettenreaktion zwei Genomfragmente bestehend aus 1108 Nukleotiden des rechten offenen Leserahmens, der fu¨r die Virusstrukturproteine (VP) 1, 2 und 3 kodiert, amplifiziert. Der Vergleich dieses Fragments mit verfu¨gbaren Sequenzen anderer MEPV und verwandten Ga¨nseparvovirus (GPV)-Isolaten ließ erkennen, dass es eine nur 84,5%-ige Sequenzu¨ber¨ bereinstimmung mit den GPV-Isolaten hatte. einstimmung mit anderen MEPV-Isolaten und eine 84,6%-ige U Bei den bislang sequenzierten MEPV-Isolaten weist diese Region eine 99%-ige Identita¨t und unter den verwandten GPV-Isolaten eine 95%-ige Identita¨t auf. Dies legt nahe, dass MEPV/PSU-31010 sich von allen anderen sequenzierten MEPV- und GPV-Isolaten unterscheidet und wahrscheinlich eine neue Gruppe avia¨rer Parvoviren repra¨sentiert. Entre 1997 y 1999 se describieron varios casos de una nueva enfermedad en patos Criollos en Pennsylvania, USA. Los casos se caracterizaron por la presencia de disfuncioń locomotora, debilidad, letargo, morbilidad

*To whom correspondence should be addressed. Tel: /1 607 253 4032. E-mail: [email protected] Received 16 June 2006 ISSN 0307-9457 (print)/ISSN 1465-3338 (online)//60001-02 # 2006 Houghton Trust Ltd DOI: 10.1080/03079450601009563

2 B. Poonia et al .

del 40-60% y mortalidad del 10-40%. Las lesiones microsco´picas ma´s caracterı´sticas fueron rabdomiopatıá degenerativa moderada a grave. Con el objetivo de caracterizar el agente causal se realizo´ aislamiento vı´rico mediante inoculacioń de embriones de pato Criollo de 14 dıás de vida con homogeneizados de bazo, hı´gado, corazoń, mu´sculo esquele´tico e intestino. Se produjeron mortalidades en el segundo pase en huevo y se aislaron parvovirus mediante pase seriado del lı´quido alantoideo de los embriones muertos en cultivos de fibroblastos de embriones de pato Criollo (MDEF). Las partıćulas de parvovirus se observaron mediante microscopıá electrońica en los lı´quidos alantoideos y en los sobrenadantes de los cultivos de MDEF. Se amplificaron mediante reaccioń en cadena de la polimerasa dos fragmentos del genoma, que comprendıán 1108 nucleo´tidos del fragmento de lectura abierta derecho que codifica para las proteıńas estructurales (VP) 1, 2 y 3, de uno de los aislamientos, parvovirus de pato Criollo MDPV9/PSU-31010. La comparacioń de este fragmento con las secuencias disponibles de otros MDPV y aislamientos relacionados de parvovirus de gansos (GPV) mostro´ que so´lo tenıá una identidad de la secuencia del 84.5% con otros aislamientos de MDPV y del 84.6% con aislamientos de GPV. Esta regioń comparte aproximadamente un 99% de identidad entre aislamientos de MDPV secuenciados previamente y un 95% de identidad entre aislamientos de GPV relacionados. Esto sugiere que MDPV/PSU-31010 diverge del resto de aislamientos de MDPV y GPV secuenciados y podrıá representar un nuevo grupo de parvovirus aviares.