ATP serves as a nucleotide switch coupling the genome maturation and packaging motor complexes of a virus assembly machine

The assembly of double-stranded DNA viruses, from phages to herpesviruses, is strongly conserved. Terminase enzymes processively excise and package monomeric genomes from a concatemeric DNA substrate. The enzymes cycle between a stable maturation complex that introduces site-specific nicks into the duplex and a dynamic motor complex that rapidly translocates DNA into a procapsid shell, fueled by ATP hydrolysis. These tightly coupled reactions are catalyzed by terminase assembled into two functionally distinct nucleoprotein complexes; the maturation complex and the packaging motor complex, respectively. We describe the effects of nucleotides on the assembly of a catalytically competent maturation complex on viral DNA, their effect on maturation complex stability and their requirement for the transition to active packaging motor complex. ATP plays a major role in regulating all of these activities and may serve as a ‘nucleotide switch’ that mediates transitions between the two complexes during processive genome packaging. These biological processes are recapitulated in all of the dsDNA viruses that package monomeric genomes from concatemeric DNA substrates and the nucleotide switch mechanism may have broad biological implications with respect to virus assembly mechanisms.

Definition of the Minimal cis-Acting Sequences Necessary for Genome Maturation of the Herpesvirus Murine Cytomegalovirus

ABSTRACT Herpesvirus DNA replication proceeds via concatemeric replicative intermediates that are comprised of head-to-tail-linked genomes. Genome maturation is carried out by the terminase, a protein complex that mediates both insertion of concatemer DNA into capsids and its subsequent cleavage to release genomes within these capsids. This cleavage is sequence specific, but the governing cis-acting DNA sequences are only partially characterized. Two highly conserved motifs called pac1 and pac2 lie near the ends of herpesvirus genomes and are known to be critical for genome maturation. However, the potential importance of other sequences has not been fully investigated. We have undertaken to define all of the sequences necessary for efficient genome maturation for a herpesvirus by inserting ectopic cleavage sites into the murine cytomegalovirus genome and assessing their ability to mediate genome maturation. A combination of deletion and substitution mutations revealed that the minimal cleavage site is large (∼180 bp) and complex. Sequences distal of pac1 (relative to the point of cleavage) were dispensable, suggesting that pac1 may be the sole cis-acting element on this side of the cleavage site. In contrast, a region distal to pac2 up to 150 bp from the point of cleavage was essential. Scanning substitutions revealed that the pac2 side of the cleavage site is complex and may contain multiple cis-acting sequence elements in addition to pac2. These results should facilitate the identification of trans-acting factors that bind to these elements and the elucidation of their functions. Such information will be critical for understanding the molecular basis of this complex process.

Impact of 2-Bromo-5,6-Dichloro-1-β-d-Ribofuranosyl Benzimidazole Riboside and Inhibitors of DNA, RNA, and Protein Synthesis on Human Cytomegalovirus Genome Maturation

ABSTRACT Herpesvirus genome maturation is a complex process in which concatemeric DNA molecules are translocated into capsids and cleaved at specific sequences to produce encapsidated-unit genomes. Bacteriophage studies further suggest that important ancillary processes, such as RNA transcription and DNA synthesis, concerned with repeat duplication, recombination, branch resolution, or damage repair may also be involved with the genome maturation process. To gain insight into the biochemical activities needed for herpesvirus genome maturation, 2-bromo-5,6-dichloro-1-β-d-ribofuranosyl benzimidazole riboside (BDCRB) was used to allow the accumulation of human cytomegalovirus concatemeric DNA while the formation of new genomes was being blocked. Genome formation was restored upon BDCRB removal, and addition of various inhibitors during this time window permitted evaluation of their effects on genome maturation. Inhibitors of protein synthesis, RNA transcription, and the viral DNA polymerase only modestly reduced genome formation, demonstrating that these activities are not required for genome maturation. In contrast, drugs that inhibit both viral and host DNA polymerases potently blocked genome formation. Radioisotope incorporation in the presence of a viral DNA polymerase inhibitor further suggested that significant host-mediated DNA synthesis occurs throughout the viral genome. These results indicate a role for host DNA polymerases in genome maturation and are consistent with a need for terminal repeat duplication, debranching, or damage repair concomitant with DNA packaging or cleavage. Similarities to previously reported effects of BDCRB on guinea pig cytomegalovirus were also noted; however, BDCRB induced low-level formation of a supergenomic species called monomer+ DNA that is unique to human cytomegalovirus. Analysis of monomer+ DNA suggested a model for its formation in which BDCRB permits limited packaging of concatemeric DNA but induces skipping of cleavage sites.