Different genetically engineered mutants of bovine viral diarrhea virus (BVDV) were analyzed for the ability to establish infection in the fetuses of pregnant heifers. The virus mutants exhibited either a deletion of the overwhelming part of the genomic region coding for the N-terminal protease N pro , a deletion of codon 349, which abrogates the RNase activity of the structural glycoprotein E rns , or a combination of both mutations. Two months after infection of pregnant cattle with wild-type virus or either of the single mutants, the majority of the fetuses contained virus or were aborted or found dead in the uterus. In contrast, the double mutant was not recovered from fetal tissues after a similar challenge, and no dead fetuses were found. This result was verified with a nonrelated BVDV containing similar mutations. After intrauterine challenge with wild-type virus, mutated viruses, and cytopathogenic BVDV, all viruses could be detected in fetal tissue after 5, 7, and 14 days. Type 1 interferon (IFN) could be detected in fetal serum after challenge, except with wild-type noncytopathogenic BVDV. On days 7 and 14 after challenge, the largest quantities of IFN in fetal serum were induced by the N pro and RNase-negative double mutant virus. The longer duration of fetal infection with the double mutant resulted in abortion. Therefore, for the first time, we have demonstrated the essential role of both N pro and E rns RNase in blocking interferon induction and establishing persistent infection by a pestivirus in the natural host.
Elimination of the RNase activity of classical swine fever virus (CSFV) glycoprotein E rns was previously shown to result in virus attenuation. Specific reduction of B cell numbers in the peripheral blood, a typical symptom of CSFV infection in pigs, was not detected on infection with the RNase-negative mutant C-H346D [Meyers et al. (1999). J Virol 73, 10224-10235]. The present report shows that this feature is restricted to this specific virus mutant, and does not represent a general property of RNase-negative CSFV. The effects induced by infection with two other RNase-negative and wild-type (wt) CSFV strains on the composition of peripheral blood cells have been further analysed. For all viruses, not only general leukopenia but also a reduction of different subsets of leukocytes (T-lymphocytes, monocytes and granulocytes) was detected. Similar to the results with B-cells, no significant differences with regard to changes in cell number were determined for RNase-negative mutants and wt virus during the initial phase of infection. Later, the values returned to pre-infection levels for the mutants, but stayed at low levels in the wt virus-infected animals. A major difference was reflected in the virus load of the infected animals, which was dramatically higher for pigs infected with wt CSFV, so that reduction of the virus load represents a further marker for attenuation resulting from RNase destruction. Attenuation was also detectable for the RNase-negative mutant C-W300G, which showed rapid reversion to the wt sequence within the infected pig. The prevention of fatal disease after infection with C-W300G is apparently determined during the short time between infection and reversion, as the virus revertant reisolated from infected pigs was shown to be virulent when used for infection in a follow-up study. Reversion of C-W300G was also detected in tissue culture during passage on swine testis epithelioid cells and porcine transformed kidney (MAX) cells, whereas the mutation was stable when SK6 or 38A1D cells were tested.
The porcine hormone-sensitive lipase gene and its cDNA have been isolated and sequenced. Several putative regulatory sequences have been detected in the promotor region. The deduced amino acid sequence is 85% identical to the corresponding human, mouse and rat sequence. A search for polymorphisms revealed one intronic and one exonic polymorphism, the latter resulting in a conservative amino acid substitution. Linkage mapping located the LIPE gene close to the calcium release channel (CRC) locus on chromosome 6.
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