Martha Abin

Phylogenetic analysis of Newcastle disease viruses isolated from waterfowl in the Upper Midwest Region of the United States

BackgroundThis study was conducted to characterize Newcastle disease virus (NDV) isolates obtained from waterfowl from the Upper Midwest region of the United States. A total of 43 NDVs were isolated by inoculation of cloacal samples in embryonated chicken eggs. These isolates were obtained from 24 mallards, seven American green-winged teals, six northern pintails, four blue-winged teals, and two wood ducks. Partial sequences of fusion gene were analyzed to determine the pathotypes and genotypes involved.ResultsDeduced amino acid sequence of the cleavage site of fusion (F) protein revealed that all isolates had avirulent motifs. Of the 43 isolates, 23 exhibited sequence motif of 111GGKQGRL117 at the cleavage site, 19 exhibited 111GEKQGRL117 while one isolate showed 111GERQGRL117. Phylogenetic analysis based on comparison with different classes of NDVs revealed that all 43 isolates clustered with class II NDVs and none with class I NDVs. Within class II, five isolates were phylogenetically close to genotype I NDVs while the remaining 38 were close to genotype II.ConclusionWe conclude that more than one genotype of NDV circulates in waterfowl in the Upper Midwest region of the US. Continuous surveillance may help better understand the epidemiology of NDVs maintained in wild bird populations and their relationship to NDVs in domestic poultry, if any.

The occurrence of enteric viruses in Light Turkey Syndrome

Two studies were conducted to determine the role of enteric viruses in Light Turkey Syndrome (LTS), which is characterized by lower weight in market age turkeys than their standard breed character. In the surveillance study, we selected four LTS and two non-LTS turkey flocks in Minnesota and collected faecal samples at 2, 3, 5 and 8-weeks of age. Astrovirus, rotavirus, and reovirus were detected alone or in various combinations in both LTS and non-LTS flocks. No coronavirus was detected in LTS flocks and no corona- or reovirus was detected in non-LTS flocks. In the second study, 2-week-old turkey poults were divided into two groups; Group A (challenged) was inoculated orally with 10% pooled faecal suspension from LTS flocks and group B (control) was inoculated with phosphate buffered saline (PBS). Clinical signs of depression, huddling, and lack of uniform size were observed in the challenged group but not in the control group. diarrhoea was observed in both groups but was more severe in the challenged group than in the control group. Birds in the challenged group shed astrovirus, rotavirus and reovirus, while the control group shed only astrovirus. Virus shedding in both groups was observed for up to nine weeks of age. Significantly lower body weights were seen in the challenged group starting at seven weeks of age and lasting until 20 weeks of age. These findings suggest that viral enteritis at an early age may set up conditions for the development of LTS in adult turkeys.

Influence of Suspending Liquid, Impactor Type, and Substrate on Size-Selective Sampling of MS2 and Adenovirus Aerosols

Size-selective sampling methods for detecting viral aerosols are needed to assess the risk of airborne transmission of disease. Andersen and MOUDI nonviable cascade impactors were used to separate test aerosols containing MS2 bacteriophage or adenovirus into size fractions spanning much of the human respirable range. Culture-based methods and a fluorescent tracer dye allowed quantification of the viral particles that remained infective after being aerosolized into a test apparatus and collected by the impactors. In addition, various suspension fluids and impaction surfaces were evaluated for their effect on virus viability. Both the Andersen and MOUDI impactors were able to sample live viruses from test aerosols, although the relative recovery rate of MS2 was higher than adenovirus (P < 0.001). The MS2 and adenovirus aerosols were sensitive to different test factors. MS2 recovery was dependent on the suspension fluid (P < 0.0001) and RH (P = 0.001), whereas adenovirus recovery was dependent on aerodynamic particle size (P < 0.001). Relative recovery of adenovirus was highest in the 0.56–1.9 μm diameter range. The results confirm that nonviable cascade impactors are capable of size-separating and detecting aerosolized viruses in the human respirable range, and that MS2 and adenovirus can retain viability after nebulization under experimental conditions. The findings cast doubt, however, on the suitability of MS2 as a general surrogate for human and animal viruses. Copyright 2012 American Association for Aerosol Research

Comparison of Cloacal and Oropharyngeal Samples for the Detection of Avian Influenza Virus in Wild Birds

Abstract This study was conducted to compare oropharyngeal (OP) and cloacal samples of wild birds (n  =  137) for the detection and isolation of avian influenza virus (AIV). A total of 39 (28.5%) cloacal and 85 (62.0%) OP samples were positive for AIV by real-time reverse transcription–PCR (RRT-PCR). The AIV nucleic acid was detected in both cloacal and OP samples from 27 (19.7%) birds, in cloacal samples only from 12 (8.8%) birds, and in OP samples only from 58 (42.3%) birds. Thus, a total of 97 (70.8%) birds were AIV positive by RRT-PCR. The cycle threshold values for the cloacal samples ranged from 16.6 to 36.9 (mean 31.5), and those for OP samples ranged from 18 to 38.9 (mean 34.9). Of the cloacal samples, 12 were positive for H5 subtype influenza virus by RRT-PCR, with one being low pathogenic H5N1. In contrast, five of the OP samples were H5 positive, but none was H5N1. None of the cloacal or OP samples was H7 positive. Eight cloacal samples yielded AIV on inoculation in embryonated chicken eggs, while only one isolate was obtained from OP samples. Thus, from testing of 137 birds, only nine (6.6%) AIV isolates were obtained. The isolates from cloacal samples were subtyped as H6N1 (n  =  5), H3N8 (n  =  2), and H4N8 (n  =  1), and the isolate from OP sample was subtyped as H6N1. No virus was isolated from the corresponding cloacal sample of the bird whose OP sample yielded AIV on virus isolation. These results suggest that surveillance programs for detection of AIV by RRT-PCR may include both sample types (cloacal and OP) to obtain a better picture of AIV prevalence, and OP samples may yield additional isolates of AIV when tested in conjunction with cloacal samples.

Triple reassortant swine influenza A (H3N2) virus in waterfowl.

To the Editor: In 1998, a new lineage of triple reassortant influenza A (H3N2) virus (TR-H3N2) with genes from humans (hemmaglutinin [HA], neuraminidase [NA], and polymerase basic 1 [PB1]), swine (matrix [M], nonstructural [NS], and nucleoprotein [NP]), and birds (polymerase acidic [PA] and PB2) emerged in the U.S. swine population. Subsequently, similar viruses were isolated from turkeys (1,2), minks, and humans in the United States and Canada (3,4). In 2007, our national influenza surveillance resulted in isolation of 4 swine-like TR-H3N2 viruses from migratory waterfowl (3 from mallards [Anas platyrrhynchos] and 1 from a northern pintail [Anas acuta] of 266 birds sampled) in north-central South Dakota. We report on the characterization of these TR-H3N2 viruses and hypothesize about their potential for interspecies transmission.

Amplification of four genes of influenza A viruses using a degenerate primer set in a one step RT-PCR method

We designed a degenerate primer set that yielded full-length amplification of hemagglutinin (HA), neuraminidase (NA), matrix (M), and non-structural protein (NSP) genes of influenza A viruses in a single reaction mixture. These four genes were amplified from 15 HA (1-15) and 9 NA (1-9) subtypes of influenza A viruses of avian (n=16) origin. In addition, 272 field isolates of avian origin were tested by this method. Full-length amplification of HA, NA, M, and NSP genes was obtained in 242 (88.9%), 254 (93.4%), 268 (98.5%), and 268 (98.5%) isolates, respectively. No gene was amplified in four isolates. Of these four isolates, two were subtyped as H4N6, one as H7N7, and one as H10N7. Amplification was successful for all 4 genes of H1N1, H2N3, and H3N2 isolates of swine influenza. Also, all four genes were amplified in one equine influenza (H3N8) isolate and seven isolates of human origin (H1N1 and H3N2). This appears to be the first study using degenerate primer set for full-length amplification of four genes of influenza A viruses in a single reaction. Further studies are needed to determine if this primer set can be used for subtyping of influenza virus isolates.

The role of type-2 turkey astrovirus in poult enteritis syndrome

ABSTRACT An experimental study was conducted to determine the comparative pathogenicity of type-2 turkey astrovirus (TAstV-2) obtained from turkey flocks afflicted with poult enteritis syndrome (PES) and from turkey flocks displaying no apparent signs of infection. In total, ninety 7-d-old poults, which tested negative for the presence of astrovirus, rotavirus, coronavirus, and reovirus by reverse transcriptase (RT) PCR, were divided evenly into 3 groups: A, B, and C. Birds in group A were inoculated orally with turkey astrovirus-positive intestinal contents from birds affected with PES. Group B received turkey astrovirus-containing intestinal contents from apparently healthy flocks. Group C served as a negative control and was given PBS. Clinical signs of diarrhea, depression, and dullness were observed in group A. Birds in group B also showed clinical signs similar to those in group A, although the signs were milder in nature. Birds in group C did not show any clinical signs. At 16 d postinoculation, the BW of birds in group A was significantly lower than that of birds in groups B or C. In addition, the bursa size was reduced in group A, but not in groups B or C. Birds in groups A and B, but not in group C, were found to shed turkey astrovirus in their feces, as detected by RT-PCR. These results provide a preliminary indication that TAstV-2 from PES birds may be more pathogenic than TAstV-2 from apparently healthy poults. Further studies are needed to determine if pathogenic and nonpathogenic strains of TAstV-2 exist in the environment. These results also reinforce our previous observations that astrovirus is involved in PES, causing significant retardation in growth and weight gain.

Comparison of spike and aerosol challenge tests for the recovery of viable influenza virus from non-woven fabrics

To experimentally determine the survival kinetics of influenza virus on personal protective equipment (PPE) and to evaluate the risk of virus transfer from PPE, it is important to compare the effects on virus recovery of the method used to contaminate the PPE with virus and the type of eluent used to recover it.

Isolation of Avian Influenza virus from Polymerase Chain Reaction–Negative Cloacal Samples of Waterfowl:

Avian influenza virus (AIV) is one of the most important zoonotic pathogens because of its potential to cause severe disease outbreaks in avian and human hosts. Virus isolation in embryonated chicken eggs (ECEs) remains a gold standard technique for AIV detection. However, some laboratories prefer molecular methods, such as real-time quantitative reverse transcription polymerase chain reaction (qRT-PCR), for initial sample screening because of their high throughput sample processing and rapid results. Samples found positive on real-time qRT-PCR are then inoculated in ECEs for virus isolation and characterization. This approach is based on the premise that real-time qRT-PCR will detect all AIV-positive samples. The current study aimed to determine if AIV can be isolated from cloacal samples of waterfowl that were initially found to be negative by real-time qRT-PCR screening. Quantitative RT-PCR–negative cloacal samples (1,369) were inoculated for virus isolation in commercial nonspecific pathogen–free ECEs. After 4 days of incubation, the allantoic fluids were harvested and inoculated in fresh ECEs for a second passage. Allantoic fluids from 147 samples were positive for hemagglutination with chicken erythrocytes. Of the 147 hemagglutination-positive allantoic fluids, 82 were AIV positive when confirmed with real-time qRT-PCR. Ten isolates were subtyped as H7N2 (n = 7), H7N1, H1N2, and H2N2. In addition, N subtype could be determined for isolates from an additional 25 samples. These results highlight the fact that screening by realtime qRT-PCR may result in some false-negative cloacal samples for AIV.

Improved Method for the Isolation and Sub-Typing of Avian Influenza Viruses from Oropharyngeal Samples of Ducks

SUMMARY. Waterfowl are the natural reservoirs of avian influenza viruses (AIVs), from which the virus can spread to other species including humans, poultry, and swine. For the surveillance of AIV in their natural reservoir, most laboratories initially screen the samples using real-time reverse-transcriptase–polymerase chain reaction because of its high speed and sensitivity. Thereafter, virus isolation is used to isolate viruses from positive samples. Although many studies point to the need of testing both cloacal and oropharyngeal (OP) samples in AIV surveillance programs, most laboratories focus only on cloacal samples. This study was undertaken to determine the utility of OP samples as target samples in AIV surveillance programs under a strict cold chain of samples from the field to the laboratory. A total of 16 AIV (15.1%) were isolated from the 106 OP samples examined. Upon subtyping, four hemagglutinin subtypes (H1, H3, H4, and H6) and three neuraminidase subtypes (N1, N2, and N8) were detected in nine different combinations. Mixed infection with two different subtypes was found in four samples. No AIVs were isolated from the corresponding cloacal samples. These results highlight the fact that testing of properly frozen OP samples could add value to the understanding of the epidemiology and ecology of AIV in waterfowl populations.