Abstract
The first step in influenza viral mRNA synthesis is the endonucleolytic cleavage of heterologous RNAs containing cap 1 (m(7)GpppNm) structures to generate capped primers that are 10 to 13 nucleotides long, which are then elongated to form the viral mRNA chains. We examined the temperature sensitivity of these steps in vitro by using two WSN virus temperature-sensitive mutants, ts1 and ts6, which have a defect in the genome RNA segment coding for the viral PB2 protein. For these experiments, it was necessary to employ purified viral cores rather than detergent-treated virions to catalyze transcription, as preparations of detergent-treated virions contain destabilizing or inhibitory activities which render even the transcription catalyzed by wild-type virus temperature sensitive. Using purified wild-type viral cores, we found that the rates of endonucleolytic cleavage of capped primers and of overall transcription were similar at 39.5 and 33 degrees C, the in vivo nonpermissive and permissive temperatures, respectively. In contrast, the activities of the cap-dependent endonucleases of ts1 and ts6 viral cores at 39.5 degrees C were only about 15% of those at 33 degrees C. The steps in transcription after endonucleolytic cleavage of the capped RNA primer were largely, if not totally, temperature insensitive, indicating that the mutations in the PB2 protein found in ts1 and ts6 virions affect only the endonuclease step. The temperature-sensitive defect is most likely in the recognition of the 5'-terminal cap 1 structure that occurs as a required first step in the endonuclease reaction: the cap-dependent binding of a specific capped primer fragment to ts1 viral cores was temperature sensitive under conditions in which binding to wild-type viral cores was not affected by increasing the temperature from 33 to 39.5 degrees C. Thus, our results establish that the viral PB2 protein functions in cap recognition during the endonuclease reaction.