In vitro translation of influenza virus messenger RNAs

Molecular studies of the differential replication at pyrexial temperatures of two influenza viruses differing in virulence for ferrets

Replication of a virulent clone (7a) of the reassortant influenza virus A/Puerto Rico/8/34-A/England/939/69 (H3N2) in ferret nasal turbinate tissue is less affected than that of an attenuated clone (64d) by temperatures which occur during pyrexia in ferrets. This is a factor which contributes to the difference in virulence of the two clones. The differential replication of the two clones at pyrexial temperatures has been reproduced in allantois-on-shell (egg-bit) cultures, and the synthesis of viral polypeptides and RNA species examined. This virus-host system was chosen because it was more convenient to use than organ cultures but, like the latter, might provide information relevant to the in vivo situation. With this system it was not possible to achieve single cycle replication: the observed effects are cumulative over several (2 to 3) cycles of replication (24 h) and therefore conclusions from them may not be as definitive as those from single cycle conditions. However, in cells infected with clone 64d both A(+) cRNA and polypeptide synthesis were little affected at 40 degrees C but levels were decreased by about 70-80% at 41 degrees C; A(+) cRNA and polypeptide levels were unaffected even at 41 degrees C with clone 7a. These reductions seem insufficient to account for the 10-fold reduction in infectious yields of clone 64d at 40 degrees C or the 100-fold and 10-fold reductions in yields of clones 64d and 7a respectively at 41 degrees C. There was no evidence of increased production of non-infectious virus at elevated temperatures by either clone. Levels of vRNA were considerably reduced at 40 and 41 degrees C for both clones, but the levels were considerably greater at all temperatures in clone 7a-infected cells than in those infected with clone 64d; vRNA levels were higher for clone 7a at 41 degrees C than for clone 64d at 37 degrees C. The different levels of vRNA do not reflect differences in the availability of template A(-) cRNAs since levels of these were similar for both clones at 37 and 40 degrees C and only reduced for clone 64d at 41 degrees C. Although the interpretation of these data is complicated by multiple cycles of replication it appears that limited availability of vRNA could be an important constraint on the ability of clone 64d to replicate at pyrexial temperatures.

Preparation of projection-less particles from influenza virus and their messenger activities in prokaryotic and eukaryotic systems

A fraction of projection-less particles was prepared from influenza A/Dunedin/4/73 and A/Victoria/3/75 (X-47) (H3N2) by detergent treatment and extraction into ether at 0 degrees C. The activity of this material in stimulating protein synthesis in vitro was studied and compared with that of isolated virion RNA using a) an RNA-dependent E. coli system, and b) a wheat germ system. In the bacterial system the purified RNA had the highest template activity, while in the eukaryotic system the disrupted particle preparation was by far the most active. Translation products were formed with immunological and electrophoretic properties similar to those of several influenza virion proteins. The experiments indicate that, when added in the form of disrupted projection-less particles, RNA from influenza A2 virus is utilized as a template by eukaryotic ribosomes.

Cell-free coupling of influenza virus RNA transcription and translation

A cell-free coupled system for the transcription and translation of fowl plague virus RNA is described. The system utilizes a new nuclease-preincubated rabbit reticulocyte lysate that has a high sensitivity to exogenous mRNA and a very low level of nuclease activity. Translation of the viral proteins in the coupled system is strictly dependent upon the viral transcriptase activity. In the coupled system the optimal concentration of magnesium is intermediate between the optimum for transcription and that for translation. Translation of the viral proteins seems faithful. The products represent the major viral peptides M and NP and two peptides with the same electrophoretic mobility as HA and P2. Viron NA is not resolved in the kind of polyacrylamide gels described. Proteins M and NP were immunoprecipitable with monospecific antisera. It is concluded that the virion-associated RNA polymerase transcribes the negative-stranded segments of the viral genome coding for these major structural proteins into fully functional mRNA's.

The segments of influenza viral mRNA

Influenza viral mRNA, i.e., complementary RNA (cRNA), isolated from infected cells , was resolved into six different species by electrophoresis in 2.1% acrylamide gels containing 6 M urea. The cRNA's were grouped into three size classes: L (large), M (medium-size), and S (small). Similarly, when gels were sliced for analysis, the virion RNA (vRNA) also distributed into six peaks because the three largest vRNA segments were closely spaced and were resolved only when the gels were autoradiographed or stained. Because of their attached polyadenylic acid [poly(A)]sequences, the cRNA segments migrated more slowly than did the corresponding vRNA segments during gel electrophoresis. After removal of the poly(A) by RNase H, the cRNA and vRNA segments comigrated, indicating that they were approximately the same size. One of the cRNA segments, S2, was shown by annealing to contain the genetic information in the vRNA segment with which it comigrated, strongly suggesting that each cRNA segment was transcribed from the vRNA segment of the same size. In contrast to the vRNA segments, which when isolated from virions were present in approximately 1:1 molar ratios, the segments of the isolated cRNA were present in unequal amounts, with the segments M2 and S2 predominating, suggesting that different amounts of the cRNA segments were synthesized in the infected cell. The predominant cRNA segments, M2 and S2, and also the S1 segment, were active as mRNA's in wheat germ extracts. The M2 cRNA was the mRNA for the nucleocapsid protein; S1 for the membrane protein; and S2 for the nonstructural protein NS1.

Identification of the defective genes in three mutant groups of influenza virus

Seven complementation-recombination groups of temperature-sensitive (ts) influenza WSN virus mutants have been previously isolated. Recently two of these groups (IV and VI) were shown to possess defects in the neuraminidase and the hemagglutinin gene, respectively, and two groups (I and III) were reported to have defects in the P3 and P1 proteins which are required for complementary RNA synthesis. In this communication we report on the defects in the remaining three mutant groups. Wild-type (ts+) recombinants derived from ts mutants and different non-ts influenza viruses were analyzed on RNA polyacrylamide gels. This technique permitted the identification of the P2 protein, the nucleoprotein, and the M protein as the defective gene products in mutant groups II, V, and VII, respectively. Based on the physiological behavior of mutants in groups II and V, it appears that P2 protein and nucleoprotein are required for virion RNA synthesis during influenza virus replication.

P1 and P3 proteins of influenza virus are required for complementary RNA synthesis

Members of two temperature-sensitive (ts) mutant groups of influenza A/WSN virus defective in complementary RNA synthesis were analyzed with respect to the identity of their defective genes. RNA analysis of recombinants having a ts+ phenotype derived from the mutants and HK virus permitted the identification of RNA 1 and RNA 2 as the single defective gene in mutant groups I and III, respectively. Based on knowledge obtained by mapping the WSN virus genome, it then was possible to determine that biologically functional P3 protein (coded for by RNA 1) and P1 protein (RNA 2) are required for complementary RNA synthesis of influenza virus.