Three-dimensional interaction of Phi29 pRNA dimer probed by chemical modification interference, cryo-AFM, and cross-linking.

Six pRNAs (p for packaging) of bacterial virus phi29 form a hexamer complex that is an essential component of the viral DNA translocating motor. Dimers, the building block of pRNA hexamer, assemble in the order of dimer --> tetramer --> hexamer. The two-dimensional structure of the pRNA monomer has been investigated extensively; however, the three-dimensional structure concerning the distance constraints of the three stems and loops are unknown. In this report, we probed the three-dimensional structure of pRNA monomer and dimer by photo affinity cross-linking with azidophenacyl. Bases 75-81 of the left stem were found to be oriented toward the head loop and proximate to bases 26-31 in a parallel orientation. Chemical modification interference indicates the involvement of bases 45-71 and 82-91 in dimer formation. Dimer was formed via hand-in-hand contact, a novel RNA dimerization that in some aspects is similar to the kissing loops of the human immunodeficiency virus. The covalently linked dimers were found to be biologically active. Both the native dimer and the covalently linked dimer were found by cryo-atomic force microscopy to be similar in global conformation and size.

Probing the structure of monomers and dimers of the bacterial virus phi29 hexamer RNA complex by chemical modification.

All dsDNA viruses multiply their genome and assemble a procapsid, a protein shell devoid of DNA. The genome is subsequently inserted into the procapsid. The bacterial virus phi29 DNA translocating motor contains a hexameric RNA complex composed of six pRNAs. Recently, we found that pRNA dimers are building blocks of pRNA hexamers. Here, we report the structural probing of pRNA monomers and dimers by chemical modification under native conditions and in the presence or absence of Mg2+. The chemical-modification pattern of the monomer is compared to that of the dimer. The data strongly support the previous secondary-structure prediction of the pRNA concerning the single-stranded areas, including three loops and seven bulges. However, discrepancies between the modification patterns of two predicted helical regions suggest the presence of more complicated, higher-order structure in these areas. It was found that dimers were formed via hand-in-hand and head-to-head contact, as the interacting sequence of the right and left loops and all bases in the head loop were protected from chemical modification. Cryoatomic force microscopy revealed that the monomer displayed a check-mark shape and the dimer exhibited an elongated shape. The dimer was twice as long as the monomer. Direct observation of the shape and measurement of size and thickness of the images strongly support the conclusion from chemical modification concerning the head-to-head contact in dimer formation. Our results also suggest that the role for Mg2+ in pRNA folding is to generate a proper configuration for the right and head loops, which play key roles in this symmetrical head-to-head organization. This explains why Mg2+ plays a critical role in pRNA dimer formation, procapsid binding, and phi29 DNA packaging.

Sequencing of a 5.5-kb DNA fragment and identification of a gene coding for a subunit of the helicase/primase complex of avian laryngotracheitis virus (ILTV).

The nucleotide sequence of a 5,520-bp EcoRI restriction fragment of avian infectious laryngotracheitis (ILTV) DNA was reported and submitted to GeneBank with an accession number of AF001078. Computer prediction revealed one large potential open reading frame (ORF) with sequence similar to one subunit of the DNA helicase-primase complex of alpha-herpesviruses. The DNA helicase/primase complex of HSV-1 consists of three sub-units with molecular weights of 12,000, 97,000 and 70,000, encoded by genes UL52, UL5 and UL8, respectively. This enzyme complex is essential for herpesvirus DNA replication. The UL52 and UL5-equivalent genes of ILTV have been reported previously (Fuchs, W. and Mettenleiter, T.C.; J Gen Virol, 1996, 77: 2221-2229; Johnson, M.A. et. al., Arch Virol, 1995, 14: 623-634). Amino acid sequence comparison and homology search revealed that this ORF shares sequence similarity of the UL8-equivalent gene of alpha-herpesviruses, that is, the ORF 52 of vericura-zoster virus (VZV), the ORF 54 of equine herpesvirus type-1 (EHV-1), as well as the equivalent gene of bovine herpesvirus type 1 (BHV-1) and canine herpesvirus (Vlcek, C. et al., Virology, 1995, 210: 100-108; Remond, M. et al., J Gen Virol, 1996, 77: 37-48).