It is important to rapidly differentiate infectious bronchitis virus (IBV) from disease agents like highly pathogenic avian influenza virus and exotic Newcastle disease virus, which can be extremely similar in the early stages of their pathogenesis. In this study, we report the development and testing of a real-time RT-PCR assay using a Taqman-labeled probe for early and rapid detection of IBV. The assay amplifies a 143-bp product in the 5'-UTR of the IBV genome and has a limit of detection and quantification of 100 template copies per reaction. All 15 strains of IBV tested as well as two Turkey coronavirus strains were amplified, whereas none of the other pathogens examined, tested positive. Evaluation of the assay was completed with 1329 tracheal swab samples. A total of 680 samples collected from IBV antibody negative birds were negative for IBV by the real-time RT-PCR assay. We tested 229 tracheal swabs submitted to two different diagnostic laboratories and found 79.04% of the tracheal swabs positive for IBV by real-time RT-PCR, whereas only 27.51% of the samples were positive by virus isolation, which is the reference standard test. We also collected a total of 120 tracheal swabs at six different time points from birds experimentally infected with different dosages of IBV and found that, independent of the dose given, the viral load in the trachea plateau at 5 days post-inoculation. In addition, an inverse relationship between the dose of virus given and the viral load at 14 days post-inoculation was observed. Finally, we tested 300 total tracheal swab samples, from a flock of commercial broilers spray vaccinated for IBV in the field. The percentage of birds infected with the IBV vaccine at 3, 7, and 14 days post-vaccination was 58%, 65%, and 83%, respectively, indicating that only slightly more than half the birds were initially infected then the vaccine was subsequently transmitted to other birds in the flock. This observation is significant because coronaviruses, which have a high mutation rate, can revert to pathogenicity when bird-to-bird transmission occurs. The real-time RT-PCR test described herein can be used to rapidly distinguish IBV from other respiratory pathogens, which is important for control of this highly infectious virus. The test was extremely sensitive and specific, and can be used to quantitate viral genomic RNA in clinical samples.
The spike glycoprotein of infectious bronchitis virus (IBV), a coronavirus, is translated as a precursor protein (So), then cleaved into two subunits (S1 and S2) by host cell serine proteases. In this study, we compared the cleavage recognition site of 55 IBV isolates to determine if the cleavage recognition site sequence, which consists of five basic amino acid residues, correlates with host cell range, serotype, geographic origin, and pathogenicity as it does in orthomyxoviruses and paramyxoviruses. The most common cleavage recognition site observed (33 of 55 viruses) was Arg-Arg-Ser-Arg-Arg, representing at least 11 different serotypes. Thus, cleavage recognition site does not appear to correlate with serotype. We also determined that cleavage recognition site sequence does not correlate with pathogenicity because attenuated and pathogenic isolates (different passages of the same virus) contain identical cleavage recognition site sequences. In addition, nephropathogenic strains had the same cleavage recognition site sequence as many nonnephropathogenic isolates. Cleavage recognition site sequence does correlate with viruses in different geographic regions, which may be an important characteristic to examine in epidemiologic studies. An IBV monoclonal antibody neutralization-resistant mutant (NR 18) had an unusual substitution of Ile for Arg at the fourth position, giving the sequence Arg-Arg-Ser-Ile-Arg, which likely prevents cleavage and, thus, destroys the conformationally dependent monoclonal antibody binding epitope. Six residues on the amino-terminal side of the cleavage recognition site are conserved in 31% of the isolates and consist of only one or two basic amino acids. Thus, the number of basic residues around the cleavage recognition site does not appear to correlate with increased cleavability, host cell range, and increased virulence as it does with envelope glycoproteins in orthomyxoviruses and paramyxoviruses.
In 2007, a novel coronavirus associated with an acute respiratory disease in alpacas (Alpaca Coronavirus, ACoV) was isolated. Full-length genomic sequencing of the ACoV demonstrated the genome to be consistent with other Alphacoronaviruses. A putative additional open-reading frame was identified between the nucleocapsid gene and 3'UTR. The ACoV was genetically most similar to the common human coronavirus (HCoV) 229E with 92.2% nucleotide identity over the entire genome. A comparison of spike gene sequences from ACoV and from HCoV-229E isolates recovered over a span of five decades showed the ACoV to be most similar to viruses isolated in the 1960’s to early 1980’s. The true origin of the ACoV is unknown, however a common ancestor between the ACoV and HCoV-229E appears to have existed prior to the 1960’s, suggesting virus transmission, either as a zoonosis or anthroponosis, has occurred between alpacas and humans.
In 1993, a new molecular typing method for infectious bronchitis virus (IBV) was introduced. This method uses reverse transcriptase-polymerase chain reaction (RT-PCR) and restriction fragment length polymorphism (RFLP) analysis of the spike gene to obtain RFLP patterns that correlate with serotype. Using that test at the Poultry Diagnostic and Research Center (PDRC, University of Georgia, Athens, GA), we have identified a total of 1523 IBV isolates in the past 11 yr. The data were obtained from clinical samples submitted to our laboratory from birds with clinical signs characteristic of IBV infection. The samples are primarily from the southeastern United States but are also from many other states as well as from outside the United States. Most of the isolations occurred during July, followed by May, April, November, October, and January. The fewest number of isolates identified on an annual basis was 20 in 2003. An unusually high number of isolations occurred in 1997 (318 isolations) and 1999 (246 isolations), which coincided with the GAV variant virus and GA98 variant virus outbreaks respectively. By far, the Ark-DPI strain was the most frequently identified type of IBV and ranged from 23% to 65% of total isolations per year. Ark-like isolates, defined as having a similar but unique RFLP pattern from the Ark-DPI vaccine strain were identified every year of the study except in 1996. In addition, new Ark-like isolates continued to emerge each year (except in the year 2000) beginning in 1997, reflecting the ability of that IBV type to undergo genetic drift. Eighty-two different variant viruses were identified although only two (GAV and GA98) became persistent and caused widespread disease. Some viruses tended to be geographically restricted to a given area (CAV in California and MX97-8147 in Mexico), whereas others were widespread (Ark-DPI, Conn, DE072, and Mass). The Florida, Gray, Holte, Iowa, and JMK types were not detected during the 11-yr period, and no foreign virus types were detected in the United States. These data show that IBV variant viruses are consistently circulating in commercial poultry and are capable of causing disease outbreaks. Our observations highlight the importance of constantly monitoring IBV as well as other coronaviruses like severe acute respiratory syndrome-coronavirus that have the ability to change and emerge to cause disease in a susceptible host.
Molecular Characterization of Infectious Bronchitis Virus Isolates Foreign to the United States and Comparison with United States Isolates
Eleven infectious bronchitis virus (IBV) isolates foreign to the United States were analyzed by using reverse transcriptase (RT)-polymerase chain reaction (PCR)/restriction fragment length polymorphism (RFLP) and S1 glycoprotein gene sequencing. Two of the isolates generated RFLP patterns that resembled the Mass 41 strain. Seven novel RFLP patterns were detected among the other nine foreign IBV isolates. Five of the foreign isolates were further analyzed by S1 glycoprotein gene sequencing in our laboratory. Phylogenetic analysis of S1 glycoprotein-deduced amino acid sequences for 4/91 pathogenic, 4/91 attenuated, and Variant 1 were greater than 90% similar to viruses belonging to the 793/B serogroup and, therefore, are possibly serologically related. Variant 2 was only 81.0% similar to viruses belonging to the European serogroup B, and, therefore, predicting its serotype is difficult. Isolates 98-07484 and 97-8123 were genotypically unique and therefore might be serologically unique. With the RFLP patterns and the deduced S1 amino acid sequence data as a reference, none of the IBV isolates foreign to the United States have been detected in the United States.
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