Experimental induction of mucosal disease: consequences of superinfection of persistently infected cattle with different strains of cytopathogenic bovine viral diarrhea virus

Bovine viral diarrhea virus genomic variation within persistently infected cattle

Bovine viral diarrhea virus (BVDV) is a single stranded RNA virus in the family Flaviviridae that causes a form of persistent infection. If a fetus is infected in utero during the first 120days of gestation the resulting calf will be immunotolerant to the infecting strain and maintain the virus for life. These animals are epidemiologically important in maintaining BVDV on farms, but also present a unique opportunity to study quasispecies in vivo in the absence of significant selection by the host adaptive immune response. We used deep sequencing and novel analytical methods to characterize the viral populations within the mesenteric lymph nodes of 10 persistently infected animals. Our results indicate that the pattern of variability across the viral genome from animal to animal is very consistent within BVDV subgenotypes. However, the individual mutations that constitute this variation are not necessarily the same in each animal. Even in the absence of significant immune selection the structural genes of BVDV vary more extensively than the non-structural genes. These findings could be useful for future vaccine design against BVDV as well as for measuring and understanding patterns of variation in other ssRNA viruses, especially those that belong to the family Flaviviridae.

Cytopathic bovine viral diarrhea viruses (BVDV): emerging pestiviruses doomed to extinction

Bovine viral diarrhea virus (BVDV), a Flaviviridae pestivirus, is arguably one of the most widespread cattle pathogens worldwide. Each of its two genotypes has two biotypes, non-cytopathic (ncp) and cytopathic (cp). Only the ncp biotype of BVDV may establish persistent infection in the fetus when infecting a dam early in gestation, a time point which predates maturity of the adaptive immune system. Such fetuses may develop and be born healthy but remain infected for life. Due to this early initiation of fetal infection and to the expression of interferon antagonistic proteins, persistently infected (PI) animals remain immunotolerant to the infecting viral strain. Although only accounting for some 1% of all animals in regions where BVDV is endemic, PI animals ensure the viral persistence in the host population. These animals may, however, develop the fatal mucosal disease, which is characterized by widespread lesions in the gastrointestinal tract. Cp BVD virus, in addition to the persisting ncp biotype, can be isolated from such animals. The cp viruses are characterized by unrestrained genome replication, and their emergence from the persisting ncp ones is due to mutations that are unique in each virus analyzed. They include recombinations with host cell mRNA, gene translocations and duplications, and point mutations. Cytopathic BVD viruses fail to establish chains of infection and are unable to cause persistent infection. Hence, these viruses illustrate a case of "viral emergence to extinction" - irrelevant for BVDV evolution, but fatal for the PI host.

Long-distance airborne transport of infectious PRRSV and Mycoplasma hyopneumoniae from a swine population infected with multiple viral variants

Airborne transport of porcine reproductive and respiratory syndrome virus (PRRSV) and Mycoplasma hyopneumoniae (M hyo) has been reported out to 4.7 km. This study attempted to determine whether this event could occur over longer distances and across multiple viral variants. To accomplish this goal, a mixed infection of 3 PRRSV variants (1-8-4, 1-18-2 and 1-26-2) and M hyo 232 was established in a source population of growing pigs. Over 21-day period, air samples were collected from the source population and at designated distances from the herd. Samples were tested for PRRSV RNA and M hyo DNA by PCR and if positive, further characterized. In exhaust air from the source population, PRRSV and M hyo were detected in 21 of 21 and 8 of 21 air samples, respectively. Five of 114 (4.4%) long-distance air samples were positive for PRRSV and 6 of 114 (5.2%) were positive for M hyo. The 5 PRRSV-positive samples were collected at 2.3, 4.6, 6.6 and 9.1 km from the herd. All contained infectious virus and were >99.2% homologous to PRRSV 1-8-4. No evidence of PRRSV 1-18-2 or 1-26-2 was detected in long-distance samples. All 6 M hyo-positive samples were 99.9% homologous to M hyo 232 and 3 samples (collected at 3.5, 6.8 and 9.2km from the herd) were infectious. These results indicate that airborne transport of PRRSV 1-8-4 and M hyo 232 occurs over longer distances than previously reported and that both pathogens remained infectious.

BVD control in Europe: current status and perspectives

For several decades after the first description of bovine viral diarrhea and its causative agent (BVDV) the economic impact of the infection was underestimated and in addition there were no suitable diagnostics and procedures for a systematic control at hand. Today, there are several estimates on the real economic impact of the infection and during the last 15 years the serological and virological laboratory diagnosis of BVDV infections has improved. Also, successful procedures aimed at eradicating BVDV infections by using a strict test and removal policy for animals persistently infected (PI) with BVDV accompanied by movement restrictions for infected herds have been implemented in the Scandinavian countries. The success of these efforts has encouraged other European countries to follow the same procedures. However, the Scandinavian control strategy might—for a number of reasons—not be acceptable for all European countries. In such cases, the test and removal strategy, with its fundamental elements of biosecurity, removal of PI animals and monitoring of herd status, in combination with systematic vaccination, might be an acceptable compromise. The impact of the BVDV-free status of regions and nations on international trade is not yet clear. In any case, biosecurity measures will be of utmost importance for individual control programs as well as multiple control programs to co-exist in Europe.

Homologous recombination in bovine pestiviruses. Phylogenetic and statistic evidence

Bovine pestiviruses (Bovine Viral Diarrea Virus 1 (BVDV 1) and Bovine Viral Diarrea Virus 2 (BVDV 2)) belong to the genus Pestivirus (Flaviviridae), which is composed of positive stranded RNA viruses causing significant economic losses world-wide. We used phylogenetic and bootstrap analyses to systematically scan alignments of previously sequenced genomes in order to explore further the evolutionary mechanisms responsible for variation in the virus. Previously published data suggested that homologous crossover might be one of the mechanisms responsible for the genomic rearrangements observed in cytopathic (cp) strains of bovine pestiviruses. Nevertheless, homologous recombination involves not just homologous crossovers, but also replacement of a homologous region of the acceptor RNA. Furthermore, cytopathic strains represent dead paths in evolution, since they are isolated exclusively from the fatal cases of mucosal disease. Herein, we report evidence of homologous inter-genotype recombination in the genome of a non-cytopathic (ncp) strain of Bovine Viral Diarrea Virus 1, the type species of the genus Pestivirus. We also show that intra-genotype homologous recombination might be a common phenomenon in both species of Pestivirus. This evidence demonstrates that homologous recombination contribute to the diversification of bovine pestiviruses in nature. Implications for virus evolution, taxonomy and phylogenetics are discussed.

Bovine viral diarrhoea virus infections and its control. A review

Infections with bovine viral diarrhoea virus continue to plague the cattle industry worldwide. The wish to control the negative effects of the virus has lead to the development of numerous vaccines, but also of eradication schemes. In this paper, a comprehensive overview on BVDV is given: the virus and its clinical manifestations, its occurrence and economic impact, the different routes of transmission, as well as diagnostic methods and objectives. Furthermore, the two major options for BVDV control--eradication and vaccination--are discussed as well as the risk for reintroduction of BVDV after eradication.

A family of closely related bovine viral diarrhea virus recombinants identified in an animal suffering from mucosal disease: new insights into the development of a lethal disease in cattle

Induction of lethal mucosal disease (MD) in cattle is linked to the generation of cytopathogenic (cp) bovine viral diarrhea virus (BVDV) in animals persistently infected with a noncytopathogenic BVDV. In most cases the cp variants are generated by recombination with cellular or viral sequences. BVDV was obtained from the serum of an MD animal and propagated in tissue culture without plaque purification. Analysis of cDNA clones established from RNA of these cells showed that apparently a variety of different viral RNAs were present. Seven of the cDNA clones contained a cellular sequence coding for light chain 3 (LC3) of microtubule-associated proteins 1A and 1B. This insertion had already been found in the cp virus JaCP obtained from the same animal and isolated by plaque purification. Analysis of further plaque-purified cp viruses showed that the diseased animal contained a family of closely related cp BVDV recombinants. A set of viruses with different duplications of viral sequences in their genomes and a variety of defective viral RNAs with deletions were found that all contained the LC3* insertion. For all the recombinants the 3' recombination sites and, in all but one case, also the 5' recombination sites between cellular and viral sequence were identical. Variation between the individual deduced genome structures resulted from different duplications or deletions of viral sequences located upstream of the cellular insertion. These results suggest that within the animal a primary recombinant with a genome containing the LC3* insertion was generated. In a trimming process a set of secondary virus recombinants was generated from this hypothetical primary recombined RNA. These secondary recombinants display genome structures that represent variations of the basic scheme already present in the primary recombinant. Apparently this trimming process that finally led to an outbreak of MD lasted a long time since recombined RNA with the basic genome structure of the cp viruses could be demonstrated in samples already taken a long time before outbreak of the disease.