Comparison of DNA binding and integration half-site selection by avian myeloblastosis virus integrase.

Insertion of the linear retrovirus DNA genome into the host DNA by the virus-encoded integrase (IN) is essential for efficient replication. We devised an efficient virus-like DNA plasmid integration assay which mimics the standard oligonucleotide assay for integration. It permitted us to study, by electron microscopy and sequence analysis, insertion of a single long terminal repeat terminus (LTR half-site) of one plasmid into another linearized plasmid. The reaction was catalyzed by purified avian myeloblastosis virus IN in the presence of Mg2+. The recombinant molecules were easily visualized and quantitated by agarose gel electrophoresis. Agarose gel-purified recombinants could be genetically selected by transformation of ligated recombinants into Escherichia coli HB101 cells. Electron microscopy also permitted the identification and localization of IN-DNA complexes on the virus-like substrate in the absence of the joining reaction. Intramolecular and intermolecular DNA looping by IN was visualized. Although IN preferentially bound to AT-rich regions in the absence of the joining reaction, there was a bias towards GC-rich regions for the joining reaction. Alignment of 70 target site sequences 5' of the LTR half-site insertions with 68 target sites previously identified for the concerted insertion of both LTR termini (LTR full-site reaction) indicated similar GC inflection patterns with both insertional events. Comparison of the data suggested that IN recognized only half of the target sequences necessary for integration with the LTR half-site reaction.     

Avian Retrovirus pp32 DNA-Binding Protein I. Recognition of Specific Sequences on Retrovirus DNA Terminal Repeats

The avian retrovirus pp32 protein possesses a DNA-nicking activity which prefers supercoiled DNA as substrate. We have investigated the binding of pp32 to avian retrovirus long terminal repeat (LTR) DNA present in both supercoiled and linear forms. The cloned viral DNA was derived from unintegrated Schmidt-Ruppin A (SRA) DNA. A subclone of the viral DNA in pBR322 (termed pPvuII-DG) contains some src sequences, tandem copies of LTR sequences, and partial gag sequences in the order src-U(3) U(5):U(3) U(5)-gag. Binding of pp32 to supercoiled pPvuII-DG DNA followed by digestion of this complex with a multicut restriction enzyme (28 fragments total) permitted pp32 to preferentially retain on nitrocellulose filters two viral DNA fragments containing only LTR DNA sequences. In addition, pp32 also preferentially retained four plasmid DNA fragments containing either potential promoters or Tn3 "left-end" inverted repeat sequences. Mapping of the pp32 binding sites on viral LTR DNA was accomplished by using the DNase I footprinting technique. The pp32 protein, but not the avian retrovirus alphabeta DNA polymerase, is able to form a unique protein-DNA complex with selected regions of either SRA or Prague A LTR DNAs. Partial DNase I digestion of a 275-base pair SRA DNA fragment complexed with pp32 gives upon electrophoresis in denaturing gels a unique ladder pattern, with regions of diminished DNase I susceptibility from 6 to 10 nucleotides in length, in comparison with control digests in the absence of protein. The binding of pp32 to this fragment also yields enhanced DNase I-susceptible sites that are spaced between the areas protected from DNase I digestion. The protected region of this unique complex was a stretch of 170 +/- 10 nucleotides that encompasses the presumed viral promoter site in U(3), which is adjacent to the src region, extends through U(5), and proceeds past the joint into U(3) for about 34 base pairs. No specific protection or DNase I enhancement by pp32 was observed in experiments with a 435-base pair SRA DNA fragment derived from a part of U(3) and the adjacent src region or a 55-base pair DNA fragment derived from another part of U(3). The DNA sequence of Prague A DNA at the fused LTRs differs from that of SRA DNA. The alteration in the sequence at the juncture of the LTRs prevented pp32 from forming a stable complex in this region of the LTR. Our results are relevant to two aspects of the interaction between pp32 and LTR DNA. First, the pp32 protein in the presence of selected viral DNA restriction fragments possibly forms a higher order oligomer analogous to Escherichia coli DNA gyrase-DNA complexes or eucaryotic nucleosome structures. Second, the specificity of the binding suggests a role for pp32 and the protected DNA sequences in the retrovirus life cycle. The preferred sequences to which pp32 binds include two adjacent 15-base pair inverted terminal repeats at the joint between U(5) and U(3) in SRA DNA. This region is involved in circularization of linear DNA and is perhaps the site that directs integration into cellular DNA.     

DNase protection analysis of retrovirus integrase at the viral DNA ends for full-site integration in vitro

Retrovirus intasomes purified from virus-infected cells contain the linear viral DNA genome and integrase (IN). Intasomes are capable of integrating the DNA termini in a concerted fashion into exogenous target DNA (full site), mimicking integration in vivo. Molecular insights into the organization of avian myeloblastosis virus IN at the viral DNA ends were gained by reconstituting nucleoprotein complexes possessing intasome characteristics. Assembly of IN-4.5-kbp donor complexes capable of efficient full-site integration appears cooperative and is dependent on time, temperature, and protein concentration. DNase I footprint analysis of assembled IN-donor complexes capable of full-site integration shows that wild-type U3 and other donors containing gain-of-function attachment site sequences are specifically protected by IN at low concentrations (<20 nM) with a defined outer boundary mapping ~20 nucleotides from the ends. A donor containing mutations in the attachment site simultaneously eliminated full-site integration and DNase I protection by IN. Coupling of wild-type U5 ends with wild-type U3 ends for full-site integration shows binding by IN at low concentrations probably occurs only at the very terminal nucleotides (<10 bp) on U5. The results suggest that assembly requires a defined number of avian IN subunits at each viral DNA end. Among several possibilities, IN may bind asymmetrically to the U3 and U5 ends for full-site integration in vitro.     

An essential saccharide binding domain for the mAb 2C7 established for Neisseria gonorrhoeae LOS by ES-MS and MSn

A study of bacterial surface oligosaccharides were investigated among different strains of Neisseria gonorrhoeae to correlate structural features essential for binding to the MAb 2C7. This epitope is widely expressed and conserved in gonococcal isolates, characteristics essential to an effective candidate vaccine antigen. Sample lipooligosaccharides (LOS), was prepared by a modification of the hot phenol-water method from which de-O-acetylated LOS and oligosaccharide (OS) components were analyzed by ES-MS-CID-MS and ES-MSnin a triple quadrupole and an ion trap mass spectrometer, respectively. Previously documented natural heterogeneity was apparent from both LOS and OS preparations which was admixed with fragments induced by hydrazine and mild acid treatment. Natural heterogeneity was limited to phosphorylation and antenni extensions to the alpha-chain. Mild acid hydrolysis to release OS also hydrolyzed the beta(1-->6) glycosidic linkage of lipid A. OS structures were determined by collisional and resonance excitation combined with MS and multistep MSn which provided sequence information from both neutral loss, and nonreducing terminal fragments. A comparison of OS structures, with earlier knowledge of MAb binding, enzyme treatment, and partial acid hydrolysis indicates a generic overlapping domain for 2C7 binding. Reoccurring structural features include a Hepalpha(1-->3)Hepbeta(1-->5)KDO trisaccharide core branched on the nonreducing terminus (Hep-2) with an alpha(1-->2) linked GlcNAc (gamma-chain), and an alpha-linked lactose (beta-chain) residue. From the central heptose (Hep-1), a beta(1-->4) linked lactose (alpha-chain), moiety is required although extensions to this residue appear unnecessary.      

Amino Acid Sequence Analysis of Reverse Transcriptase Subunits from Avian Myeloblastosis Virus

The NH₂-terminal amino acid sequences of the α and β chains of avian myeloblastosis αβ DNA polymerase were determined by using microsequence analysis in the subnanomole range and were found to be identical up to 17 residues. The common sequence was as follows: Thr-Val-Ala-Leu-His-Leu-Ala-Ile-Pro-Leu-Lys-Trp-Lys-Pro-Asn-His-Thr-. This result provides convincing chemical evidence that the α chain is derived from the NH₂-terminal region of the β chain by proteolytic cleavage, whereas the amino acid composition for these α and β subunits and p32 DNA endonuclease suggests that the latter is derived from the carboxyl-terminal region of the β chain.     

Molecular and genetic determinants of rous sarcoma virus integrase for concerted DNA integration

Site-directed mutagenesis of recombinant Rous sarcoma virus (RSV) integrase (IN) allowed us to gain insights into the protein-protein and protein-DNA interactions involved in reconstituted IN-viral DNA complexes capable of efficient concerted DNA integration (termed full-site). At 4 nM IN, wild-type (wt) RSV IN incorporates approximately 30% of the input donor into full-site integration products after 10 min of incubation at 37 degrees C, which is equivalent to isolated retrovirus preintegration complexes for full-site integration activity. DNase I protection analysis demonstrated that wt IN was able to protect the viral DNA ends, mapping approximately 20 bp from the end. We had previously mapped the replication capabilities of several RSV IN mutants (A48P and P115S) which appeared to affect viral DNA integration in vivo. Surprisingly, recombinant RSV A48P IN retained wt IN properties even though the virus carrying this mutation had significantly reduced integrated viral DNA in comparison to wt viral DNA in virus-infected cells. Recombinant RSV P115S IN also displayed all of the properties of wt RSV IN. Upon heating of dimeric P115S IN in solution at 57 degrees C, it became apparent that the mutation in the catalytic core of RSV IN exhibited the same thermolabile properties for 3' OH processing and strand transfer (half-site and full-site integration) activities consistent with the observed temperature-sensitive defect for integration in vivo. The average half-life for inactivation of the three activities were similar, ranging from 1.6 to 1.9 min independent of the IN concentrations in the assay mixtures. Wt IN was stable under the same heat treatment. DNase I protection analysis of several conservative and nonconservative substitutions at W233 (a highly conserved residue of the retrovirus C-terminal domain) suggests that this region is involved in protein-DNA interactions at the viral DNA attachment site. Our data suggest that the use of recombinant RSV IN to investigate efficient full-site integration in vitro with reference to integration in vivo is promising.     

A novel structure of DNA repair protein RecO from Deinococcus radiodurans

Recovery of arrested replication requires coordinated action of DNA repair, replication, and recombination machineries. Bacterial RecO protein is a member of RecF recombination repair pathway important for replication recovery. RecO possesses two distinct activities in vitro, closely resembling those of eukaryotic protein Rad52: DNA annealing and RecA-mediated DNA recombination. Here we present the crystal structure of the RecO protein from the extremely radiation resistant bacteria Deinococcus radiodurans (DrRecO) and characterize its DNA binding and strand annealing properties. The RecO structure is totally different from the Rad52 structure. DrRecO is comprised of three structural domains: an N-terminal domain which adopts an OB-fold, a novel alpha-helical domain, and an unusual zinc-binding domain. Sequence alignments suggest that the multidomain architecture is conserved between RecO proteins from other bacterial species and is suitable to elucidate sites of protein-protein and DNA-protein interactions necessary for RecO functions during the replication recovery and DNA repair.     

Efficient concerted integration by recombinant human immunodeficiency virus type 1 integrase without cellular or viral cofactors

Replication of retroviruses requires integration of the linear viral DNA genome into the host chromosomes. Integration requires the viral integrase (IN), located in high-molecular-weight nucleoprotein complexes termed preintegration complexes (PIC). The PIC inserts the two viral DNA termini in a concerted manner into chromosomes in vivo as well as exogenous target DNA in vitro. We reconstituted nucleoprotein complexes capable of efficient concerted (full-site) integration using recombinant wild-type human immunodeficiency virus type I (HIV-1) IN with linear retrovirus-like donor DNA (480 bp). In addition, no cellular or viral protein cofactors are necessary for purified bacterial recombinant HIV-1 IN to mediate efficient full-site integration of two donor termini into supercoiled target DNA. At about 30 nM IN (20 min at 37 degrees C), approximately 15 and 8% of the input donor is incorporated into target DNA, producing half-site (insertion of one viral DNA end per target) and full-site integration products, respectively. Sequencing the donor-target junctions of full-site recombinants confirms that 5-bp host site duplications have occurred with a fidelity of about 70%, similar to the fidelity when using IN derived from nonionic detergent lysates of HIV-1 virions. A key factor allowing recombinant wild-type HIV-1 IN to mediate full-site integration appears to be the avoidance of high IN concentrations in its purification (about 125 microg/ml) and in the integration assay (<50 nM). The results show that recombinant HIV-1 IN may not be significantly defective for full-site integration. The findings further suggest that a high concentration or possibly aggregation of IN is detrimental to the assembly of correct nucleoprotein complexes for full-site integration.