Sequence requirements for RNA strand transfer during nidovirus discontinuous subgenomic RNA synthesis.

Nidovirus subgenomic mRNAs contain a leader sequence derived from the 5' end of the genome fused to different sequences ('bodies') derived from the 3' end. Their generation involves a unique mechanism of discontinuous subgenomic RNA synthesis that resembles copy-choice RNA recombination. During this process, the nascent RNA strand is transferred from one site in the template to another, during either plus or minus strand synthesis, to yield subgenomic RNA molecules. Central to this process are transcription-regulating sequences (TRSs), which are present at both template sites and ensure the fidelity of strand transfer. Here we present results of a comprehensive co-variation mutagenesis study of equine arteritis virus TRSs, demonstrating that discontinuous RNA synthesis depends not only on base pairing between sense leader TRS and antisense body TRS, but also on the primary sequence of the body TRS. While the leader TRS merely plays a targeting role for strand transfer, the body TRS fulfils multiple functions. The sequences of mRNA leader-body junctions of TRS mutants strongly suggested that the discontinuous step occurs during minus strand synthesis.

Autographa californica baculoviruses with large genomic deletions are rapidly generated in infected insect cells.

Defective interfering baculoviruses (DIs) lack considerable portions of the genome, interfere with the replication of helper virus, and cause the so-called "passage-effect" during serial passaging in insect cells and in bioreactor configurations. We investigated their origin by (nested) PCR and demonstrated that DIs lacking approximately 43% (d43) of their DNA are present in low-passage Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV)-E2 virus stocks and in polyhedra, but not in the authentic AcMNPV isolate obtained prior to passage in cell culture. To investigate whether DIs are rapidly generated de novo in Sf21 insect cells, a genetically homogeneous AcMNPV bacmid was serially passaged, resulting in the generation of d43 DIs within two passages. AT-rich sequences of up to 66 nucleotides of partly unknown origin were found at the deletion junctions in the d43 DI genomes. These data suggest that the rapid generation of DIs is an intrinsic property of baculovirus infection in insect cell culture and involves several recombination steps.