Escherichia coli RuvA and RuvB proteins specifically interact with Holliday junctions and promote branch migration.

The Escherichia coli ruvA and ruvB genes are involved in DNA repair and in the late step of homologous genetic recombination. We have demonstrated previously that the RuvA-RuvB protein complex in the presence of ATP promotes reabsorption of cruciform structures extruded from a supercoiled plasmid with an inverted repeat sequence. Because the cruciform structure is topologically analogous to the Holiday structure, we have proposed that the role of the RuvA and RuvB proteins in recombination is to promote a strand exchange reaction at the Holliday junction. Here, we studied the specific interaction of the RuvA-RuvB complex with the Holliday structure using synthetic analogs prepared by annealing four oligonucleotides. The affinities of the RuvA protein for synthetic Holliday junctions are much higher (> 20-fold) than for duplex DNA, and the affinities of the RuvA protein for the junctions are further enhanced (> 4-fold) by the interaction with the RuvB protein. The RuvA-RuvB protein complex in the presence of ATP promotes dissociation of the synthetic Holliday junction with homology in the central core into two halves by catalyzing branch migration to the DNA ends, but it does not affect the structure of the synthetic Holliday junction without the homology. The separation of the synthetic Holliday junction is a result of the activity of the RuvA-RuvB complex that promotes strand exchange and DNA unwinding. Furthermore, RuvA and RuvB promote the strand exchange reaction at the Holliday junctions made by RecA. These results provide further evidence that the RuvA-RuvB complex recognizes the Holliday junction and promotes branch migration in homologous recombination.     

Analysis of the unoccupied site of an integrated human papillomavirus 16 sequence in a cervical carcinoma

We have previously cloned and analyzed the structure of a type 16 human papillomavirus (HPV16) integration in a primary cervical carcinoma tissue, M50 (Choo et al., J. Virol. 62, 1659-1666, 1988). We found that specific nucleotide sequences within the HPV16 genome influenced the genomic organization of the integrated viral genome. Using the viral-cellular junctions of the M50 DNA as probes, we have now cloned the unoccupied site from a human genomic library. Mapping analysis showed that a deletion of about 1.1 kilobase pairs (kb) had occurred at the integration site of M50. Sequencing of the integration junctions of the unoccupied site and comparison with the viral sequence has revealed short regions of sequence homology between the viral and the cellular genomes at both junctions. Our results are consistent with a mechanism of integration of the HPV16 sequences in the M50 carcinoma involving illegitimate recombination events using short patches of homologous sequences between the two heterologous genomes for anchorage and as guides for crossover. Preferred topoisomerase I cleavage sites and alternating purine and pyrimidine bases, which favor the formation of Z-DNA, could also be identified at the integration regions, supporting a proposed role for the topoisomerase I enzyme in the illegitimate recombination in the viral integration process.     

Analysis of the sequences flanking the translational start sites of Plasmodium falciparum

The 5' and 3' regions adjacent to the initiation codon in 22 Plasmodium falciparum sequences were examined. A 5' consensus sequence (AAAA/ATG) was found. Although P. falciparum non-translated DNA is A-rich, A occurred significantly more frequently in the 4 positions preceding the initiation ATG than in adjacent non-translated DNA, suggesting that this consensus sequence has functional significance in the initiation of translation. This region has similarities with the equivalent sequences in yeast and Drosophila but differs markedly from that in vertebrates. No significant bias in nucleotide frequencies was found 3' to the initiation codon.     

Assembly of the Escherichia coli RuvABC resolvasome directs the orientation of Holliday junction resolution

Genetic recombination can lead to the formation of intermediates in which DNA molecules are linked by Holliday junctions. Movement of a junction along DNA, by a process known as branch migration, leads to heteroduplex formation, whereas resolution of a junction completes the recombination process. Holliday junctions can be resolved in either of two ways, yielding products in which there has, or has not, been an exchange of flanking markers. The ratio of these products is thought to be determined by the frequency with which the two isomeric forms (conformers) of the Holliday junction are cleaved. Recent studies with enzymes that process Holliday junctions in Escherichia coli, the RuvABC proteins, however, indicate that protein binding causes the junction to adopt an open square-planar configuration. Within such a structure, DNA isomerization can have little role in determining the orientation of resolution. To determine the role that junction-specific protein assembly has in determining resolution bias, a defined in vitro system was developed in which we were able to direct the assembly of the RuvABC resolvasome. We found that the bias toward resolution in one orientation or the other was determined simply by the way in which the Ruv proteins were positioned on the junction. Additionally, we provide evidence that supports current models on RuvABC action in which Holliday junction resolution occurs as the resolvasome promotes branch migration.     

An identification of a transforming region of Epstein-Barr viral DNA cannot be confirmed

We have analyzed Epstein-Barr viral DNA sequences in two cell lines HI-26-36 and HI-HFX. Stoerker et al. (J. Stoerker, J.E. Holliday, and R. Glaser (1983), Virology 129, 199-206) concluded that these cells were transformed by virus that arose as the result of marker rescue of a transformation-incompetent deletion mutant of EBV. We compared viral DNA sequences in prototype EBV strains with data presented in the Virology paper. Our findings are not consistent with the data of Stoerker et al. and indicate that the cell lines supplied to us did not arise by "marker rescue" but appear to contain the Jijoye viral genome.     

Shuffling of genes within low-copy repeats on 22q11 (LCR22) by Alu-mediated recombination events during evolution

Low-copy repeats, or segmental duplications, are highly dynamic regions in the genome. The low-copy repeats on chromosome 22q11.2 (LCR22) are a complex mosaic of genes and pseudogenes formed by duplication processes; they mediate chromosome rearrangements associated with velo-cardio-facial syndrome/DiGeorge syndrome, der(22) syndrome, and cat-eye syndrome. The ability to trace the substrates and products of recombination events provides a unique opportunity to identify the mechanisms responsible for shaping LCR22s. We examined the genomic sequence of known LCR22 genes and their duplicated derivatives. We found Alu (SINE) elements at the breakpoints in the substrates and at the junctions in the truncated products of recombination for USP18, GGT, and GGTLA, consistent with Alu-mediated unequal crossing-over events. In addition, we were able to trace a likely interchromosomal Alu-mediated fusion between IGSF3 on 1p13.1 and GGT on 22q11.2. Breakpoints occurred inside Alu elements as well as in the 5' or 3' ends of them. A possible stimulus for the 5' or 3' terminal rearrangements may be the high sequence similarities between different Alu elements, combined with a potential recombinogenic role of retrotransposon target-site duplications flanking the Alu element, containing potentially kinkable DNA sites. Such sites may represent focal points for recombination. Thus, genome shuffling by Alu-mediated rearrangements has contributed to genome architecture during primate evolution.     

Defining the borders of the chicken proto-fps gene, a precursor of Fujinami sarcoma virus

The transforming (onc) genes of retroviruses contain specific sequences, derived from as yet poorly defined, normal cellular genes, termed proto-onc genes. Proto-onc genes must be defined to explain their docility compared to the oncogenicity of the viral derivatives. Here we set out to determine the borders of the chicken proto-fps gene from which the onc genes of avian Fujinami (FSV) and PRC sarcoma viruses (PRCSV) are derived. These onc genes are hybrids of an element from the gag gene of retroviruses (delta gag) linked to a 2.8-kb domain from proto-fps. To identify the 5' border of proto-fps we have sequenced 1.5 kb beyond the 5' border of overlap with viral fps utilizing a proto-fps clone derived previously. A possible promoter was identified that maps 736 nucleotides from this border. The 736 nucleotides contain two possible exons with 121 codons, and short regions of homology with the delta gag termini of FSV and PRCII. A translation stop codon and an adjacent polyadenylation signal were identified just prior to the 3' border of overlap with viral fps within a 1.15-kb sequence of a newly isolated proto-fps clone. Comparing four exons within this 1.15 kb proto-fps sequence with known fps equivalents of FSV and PRCSV, we have detected strain-specific, but no common point mutations in each viral genome. A 3.3-kb polyadenylated proto-fps mRNA was detected in chicken liver RNA by gel electrophoresis and hybridization with proto-fps DNA. We conclude that the coding capacity of proto-fps is just over 3 kb, consistent with the size of the putative proto-fps protein of 98 kDa and hence slightly larger than that of viral fps. Thus proto-fps and the viral delta gag-fps genes each contain distinct 5' regulatory and coding sequences and share the 3' terminal fps domains. It is suggested that this difference, rather than scattered point mutations, is responsible for the oncogenic function of the viral genes and the unknown cellular function of proto-fps.     

Avian Sarcoma and Leukemia Virus (ASLV) integration in vitro: Mutation or deletion of integrase (IN) recognition sequences does not prevent but only reduces the efficiency and accuracy of DNA integration

Integrase (IN) is the enzyme responsible for provirus integration of retroviruses into the host cell genome. We used an Avian Sarcoma and Leukemia Viruses (ASLV) integration assay to investigate the way in which IN integrates substrates mutated or devoid of one or both IN recognition sequences. We found that replacing U5 by non-viral sequences (U5del) or U3 by a mutated sequence (pseudoU3) resulted in two and three fold reduction of two-ended integration (integration of the two ends from a donor DNA) respectively, but had a slight effect on concerted integration (integration of both ends at the same site of target DNA). Further, IN was still able to integrate the viral ends of the double mutant (pseudoU3/U5del) in a two-ended and concerted integration reaction. However, efficiency and accuracy (i.e. fidelity of size duplication and of end cleavage) of integration were reduced.     

Application of bioinformatics in search for cleavable peptides of SARS-CoV M(pro) and chemical modification of octapeptides

According to the "distorted key" theory as elaborated in a review article years ago (Chou, K.C.: Analytical Biochemistry, 1996, 233, 1-14), the knowledge of the cleavable peptides by SARS-CoV M(pro) (severe acute respiratory syndrome coronavirus main proteinase) can provide very useful insights on developing drugs against SARS. In view of this, the softwares, ZCURVE_CoV 1.0 and ZCURVE_CoV 2.0 (http://tubic.tju.edu.cn/sars/), developed recently for SARS-Coronavirus are used to analyze the 36 complete SARS-Coronavirus RNA sequences in the gene bank NCBI (http://www.ncbi.nlm.nih.gov/) from different sources for protein coding genes, and to search for the cleavage sites of SARS-CoV M(pro) in polyproteins pp1a and pp1ab. A total of 396 cleavage points are found in the 36 SARS-Coronavirus and 11 cleavable octapeptides abstracted from the 396 cleavage sites. The statistical distributions of amino acids for the cleavable octapeptides at the subsites R4, R3, R2, R1, R1', R2', R3' and R4' are calculated. The cleavage-specific positions are on R2, R1 and R1', and the positions R3 and R4 are featured by some certain specificity for SARS-CoV M(pro). The structural characters of amino acid residues around the cleavage-specific positions are discussed. Two most promising octapeptides, i.e., NH(2)-ATLQ downward arrowAIAS-COOH and NH(2)-ATLQ downward arrowAENV-COOH, are selected to be the candidates for chemical modification, converting into the inhibitors of SARS-CoV M(pro). A possible strategy to convert a cleavable octapeptide by SARS enzyme into a drug candidate against SARS is elucidated.     

Identification of a 450-bp region of human papillomavirus type 1 that promotes episomal replication in Saccharomyces cerevisiae

Human papillomaviruses (HPVs) replicate as nuclear plasmids in infected cells. Since the DNA replication machinery is generally conserved between humans and Saccharomyces cerevisiae, we studied whether HPV-1 DNA can replicate in yeast. Plasmids containing a selectable marker (with or without a yeast centromere) and either the full-length HPV-1 genome or various regions of the viral long control region (LCR) and the 3' end of the L1 gene were introduced into S. cerevisiae and their ability to replicate episomally was investigated. Our results show that HPV-1 sequences promote episomal replication of plasmids although the yeast centromere is required for plasmid retention. We have mapped the autonomously replicating sequence activity of HPV-1 DNA to a 450 base-pair sequence (HPV-1 nt 6783-7232) that includes 293 nucleotides from the 5' region of the viral LCR and 157 nucleotides from the 3' end of the L1 gene. The HPV-1 ARS does not include the binding sites for the viral E1 and E2 proteins, and these proteins are dispensable for replication in S. cerevisiae.     

Molecular characterization of the genomic breakpoints in a case of t(3;21)(q26;q22).

The t(3;21)(q26;q22) is a recurring chromosomal abnormality in blastic crisis of chronic myelogenous leukemia (CML) and in therapy-related myelodysplastic syndrome and acute leukemia. In order to clarify the genetic recombination mechanism underlying the t(3;21), we molecularly cloned the breakpoints and determined their nucleotide sequence in a case of CML in blastic crisis with t(3;21). Near the breakpoint on chromosome 21, three homopyrimidine (CT)-rich sequences were found. We also identified a sequence homologous to the topoisomerase II binding and cleavage consensus sequence surrounding the breakpoint on chromosome 3, and two topoisomerase II binding and cleavage consensus sequences near the breakpoint on chromosome 21. In addition, around the breakpoint on chromosome 21, four chi-like sequences, potential consensus signals for activating recombination, were found. There were no Alu sequences or antigen receptor gene-like heptamer/nonamer signal sequences within the breakpoints on chromosomes 3 and 21. The breakpoints were found adjacent to the topoisomerase II binding and cleavage consensus sequence or the homopyrimidine-rich sequence. Furthermore, the chi-like sequences and the homopyrimidine-rich sequence were detected on chromosome 21 but not on chromosome 3. Genes Chromosomes Cancer 26:92-96, 1999.