Vaccinia virus DNA ligase recruits cellular topoisomerase II to sites of viral replication and assembly

Vaccinia virus replication is inhibited by etoposide and mitoxantrone even though poxviruses do not encode the type II topoisomerases that are the specific targets of these drugs. Furthermore, one can isolate drug-resistant virus carrying mutations in the viral DNA ligase and yet the ligase is not known to exhibit sensitivity to these drugs. A yeast two-hybrid screen was used to search for proteins binding to vaccinia ligase, and one of the nine proteins identified comprised a portion (residue 901 to end) of human topoisomerase IIbeta. One can prevent the interaction by introducing a C(11)-to-Y substitution mutation into the N terminus of the ligase bait protein, which is one of the mutations conferring etoposide and mitoxantrone resistance. Coimmunoprecipitation methods showed that the native ligase and a Flag-tagged recombinant protein form complexes with human topoisomerase IIalpha/beta in infected cells and that this interaction can also be disrupted by mutations in the A50R (ligase) gene. Immunofluorescence microscopy showed that both topoisomerase IIalpha and IIbeta antigens are recruited to cytoplasmic sites of virus replication and that less topoisomerase was recruited to these sites in cells infected with mutant virus than in cells infected with wild-type virus. Immunoelectron microscopy confirmed the presence of topoisomerases IIalpha/beta in virosomes, but the enzyme could not be detected in mature virus particles. We propose that the genetics of etoposide and mitoxantrone resistance can be explained by vaccinia ligase binding to cellular topoisomerase II and recruiting this nuclear enzyme to sites of virus biogenesis. Although other nuclear DNA binding proteins have been detected in virosomes, this appears to be the first demonstration of an enzyme being selectively recruited to sites of poxvirus DNA synthesis and assembly.     

Vaccinia virus encodes a thymidylate kinase gene: sequence and transcriptional mapping

The nucleotide sequence and deduced amino acid sequence of a vaccinia virus gene from the SalI F fragment are shown. The predicted polypeptide shares 42% amino acid identity over a 200 amino acid region with Saccharomyces cerevisiae thymidylate kinase (TmpK) and has low homology with herpes simplex virus deoxypyrimidine kinase. Northern blotting and S1 nuclease protection showed that the TmpK gene is transcribed early during infection and mapped the mRNA 5' end to immediately upstream of the second inframe ATG codon of the open reading frame (ORF). The encoded polypeptide is predicted to be 204 amino acids long (23.2 kD) and is almost colinear with yeast TmpK. Vaccinia virus possesses genes for TK and TmpK, separated by 57 kilobases of DNA, which are co-ordinately expressed and the encoded enzymes perform sequential steps in the same biochemical pathway.     

A cold-regulated Arabidopsis gene encodes a polypeptide having potent cryoprotective activity.

We previously showed that cor15, a cold-regulated gene from Arabidopsis thaliana, encodes a 15 kDa polypeptide designated COR15. Here we report that COR15 has potent cryoprotective activity in an in vitro cryoprotection assay. Specifically, COR15 was very effective in protecting the cold-labile enzyme lactate dehydrogenase against freeze-inactivation; on a concentration basis, it was about 10(6) times more effective than sucrose and 10(2)-10(3) times more effective than other proteins including bovine serum albumin. The possible role of cor15 in cold acclimation is discussed.     

Vaccinia virus encodes an essential gene with strong homology to protein kinases

The B1 gene of vaccinia virus encodes a 34-kDa protein which is essential for viral replication. Temperature-sensitive mutants bearing lesions in this gene arrest at the stage of DNA replication during nonpermissive infections. In this report, the sequence of the 34-kDa open reading frame is presented, and the mutations in two ts alleles are identified. Analysis of the deduced protein sequence reveals strong homology with catalytic domains of numerous protein kinases. The lesion in one of the mutants alters an invariant glycine residue within one such domain.     

NAD+-dependent DNA ligase encoded by a eukaryotic virus.

We report the production, purification, and characterization of an NAD(+)-dependent DNA ligase encoded by the Amsacta moorei entomopoxvirus (AmEPV), the first example of an NAD(+) ligase from a source other than eubacteria. AmEPV ligase lacks the zinc-binding tetracysteine domain and the BRCT domain that are present in all eubacterial NAD(+) ligases. Nonetheless, the monomeric 532-amino acid AmEPV ligase catalyzed strand joining on a singly nicked DNA in the presence of a divalent cation and NAD(+). Neither ATP, dATP, nor any other nucleoside triphosphate could substitute for NAD(+). Structure probing by limited proteolysis showed that AmEPV ligase is punctuated by a surface-accessible loop between the nucleotidyltransferase domain, which is common to all ligases, and the N-terminal domain Ia, which is unique to the NAD(+) ligases. Deletion of domain Ia of AmEPV ligase abolished the sealing of 3'-OH/5'-PO(4) nicks and the reaction with NAD(+) to form ligase-adenylate, but had no effect on phosphodiester formation at a pre-adenylated nick. Alanine substitutions at residues within domain Ia either reduced (Tyr(39), Tyr(40), Asp(48), and Asp(52)) or abolished (Tyr(51)) sealing of a 5'-PO(4) nick and adenylyl transfer from NAD(+) without affecting ligation of DNA-adenylate. We conclude that: (i) NAD(+)-dependent ligases exist in the eukaryotic domain of the phylogenetic tree; and (ii) ligase structural domain Ia is a determinant of cofactor specificity and is likely to interact directly with the nicotinamide mononucleotide moiety of NAD(+).     

Vaccinia virus encodes an active thymidylate kinase that complements a cdc8 mutant of Saccharomyces cerevisiae.

A vaccinia virus open reading frame (ORF) previously predicted to encode thymidylate kinase (TmpK) is shown to encode an active enzyme. A copy of the ORF, generated by polymerase chain reaction, was cloned into an Escherichia coli inducible expression vector. Cell extracts of E. coli expressing the vaccinia gene contained high levels of TmpK activity, whereas extracts of cells without the TmpK gene did not. The vaccinia ORF expressed from a yeast vector complemented a Saccharomyces cerevisiae cdc8 mutant, demonstrating functional compatibility of the vaccinia virus and yeast TmpK enzymes. The gene is shown to be nonessential for the replication of vaccinia virus in cultured cells by the construction of a viable virus mutant that has the coding region of the TmpK gene interrupted by the Ecogpt gene. Synthesis of the vaccinia TmpK protein in infected cells was demonstrated by the use of a polyvalent rabbit antiserum raised against the purified TmpK enzyme expressed in E. coli to immunoprecipitate a 23-kDa early polypeptide from cells infected with wild type vaccinia but not from cells infected with the TmpK mutant. Plasmid vectors that allow the construction of recombinant viruses expressing foreign gene(s) from the nonessential TmpK locus are described.     

Vaccinia DNA ligase complements Saccharomyces cerevisiae cdc9, localizes in cytoplasmic factories and affects virulence and virus sensitivity to DNA damaging agents.

The functional compatibility of vaccinia virus DNA ligase with eukaryotic counterparts was demonstrated by its ability to complement Saccharomyces cerevisiae cdc9. The vaccinia DNA ligase is a 63 kDa protein expressed early during infection that is non-essential for virus DNA replication and recombination in cultured cells. This implies complementation by a mammalian DNA ligase, yet no obvious recruitment of host DNA ligase I from the nucleus to the cytoplasm was observed during infection. An antiserum raised against a peptide conserved in eukaryotic DNA ligases identified the virus enzyme in discrete cytoplasmic 'factories', the sites of virus DNA synthesis, demonstrating immunological cross-reactivity between host DNA ligase I and the vaccinia enzyme. DNA ligase was not detected in the factories of a mutant virus lacking the ligase gene. Despite this, no difference in growth between wild-type (WT) and mutant virus was detectable even in Bloom's syndrome cells which have reduced DNA ligase I activity. However, DNA ligase negative virus showed an increased sensitivity to UV or bleomycin in cultured cells, and the importance of DNA ligase for virus virulence in vivo was demonstrated by the attenuated phenotype of the deletion mutant in intranasally infected mice.     

Footprinting of Chlorella virus DNA ligase bound at a nick in duplex DNA.

The 298-amino acid ATP-dependent DNA ligase of Chlorella virus PBCV-1 is the smallest eukaryotic DNA ligase known. The enzyme has intrinsic specificity for binding to nicked duplex DNA. To delineate the ligase-DNA interface, we have footprinted the enzyme binding site on DNA and the DNA binding site on ligase. The size of the exonuclease III footprint of ligase bound a single nick in duplex DNA is 19-21 nucleotides. The footprint is asymmetric, extending 8-9 nucleotides on the 3'-OH side of the nick and 11-12 nucleotides on the 5'-phosphate side. The 5'-phosphate moiety is essential for the binding of Chlorella virus ligase to nicked DNA. Here we show that the 3'-OH moiety is not required for nick recognition. The Chlorella virus ligase binds to a nicked ligand containing 2',3'-dideoxy and 5'-phosphate termini, but cannot catalyze adenylation of the 5'-end. Hence, the 3'-OH is important for step 2 chemistry even though it is not itself chemically transformed during DNA-adenylate formation. A 2'-OH cannot substitute for the essential 3'-OH in adenylation at a nick or even in strand closure at a preadenylated nick. The protein side of the ligase-DNA interface was probed by limited proteolysis of ligase with trypsin and chymotrypsin in the presence and absence of nicked DNA. Protease accessible sites are clustered within a short segment from amino acids 210-225 located distal to conserved motif V. The ligase is protected from proteolysis by nicked DNA. Protease cleavage of the native enzyme prior to DNA addition results in loss of DNA binding. These results suggest a bipartite domain structure in which the interdomain segment either comprises part of the DNA binding site or undergoes a conformational change upon DNA binding. The domain structure of Chlorella virus ligase inferred from the solution experiments is consistent with the structure of T7 DNA ligase determined by x-ray crystallography.     

The yeast CDC9 gene encodes both a nuclear and a mitochondrial form of DNA ligase I.

BACKGROUND: The yeast CDC9 gene encodes a DNA ligase I activity required during nuclear DNA replication to ligate the Okazaki fragments formed when the lagging DNA strand is synthesised. The only other DNA ligase predicted from the yeast genome sequence, DNL4/LIG4, is specifically involved in a non-homologous DNA end-joining reaction. What then is the source of the DNA ligase activity required for replication of the yeast mitochondrial genome? RESULTS: We report that CDC9 encodes two distinct polypeptides expressed from consecutive in-frame AUG codons. Translational initiation at these two sites gives rise to polypeptides differing by a 23 residue amino-terminal extension, which corresponds to a functional mitochondrial pre-sequence sufficient to direct import into yeast mitochondria. Initiation at the first AUG codon results in a 755 amino-acid polypeptide that is imported into mitochondria, whereupon the pre-sequence is proteolytically removed to yield the mature mitochondrial form of Cdc9p. Initiation at the second AUG codon produces a 732 amino-acid polypeptide, which is localised to the nucleus. Cells expressing only the nuclear isoform were found to be specifically defective in the maintenance of the mitochondrial genome. CONCLUSIONS: CDC9 encodes two distinct forms of DNA ligase I. The first is targeted to the mitochondrion and is required for propagation and maintenance of mitochondrial DNA, the second localises to the nucleus and is sufficient for the essential cell-division function associated with this gene.     

Experimental genomic evolution: extensive compensation for loss of DNA ligase activity in a virus

Deletion of the viral ligase gene drastically reduced the fitness of bacteriophage T7 on a ligase-deficient host. Viral evolution recovered much of this fitness during long-term passage, but the final fitness remained below that of the intact virus. Compensatory changes occurred chiefly in genes involved in DNA metabolism: the viral endonuclease, helicase, and DNA polymerase. Two other compensatory changes of unknown function also occurred. Using a method to distinguish compensatory mutations from other beneficial mutations, five additional substitutions from the recovery were shown to enhance adaptation to culture conditions and were not compensatory for the deletion. In contrast to the few previous studies of viral recovery from deletions, the compensatory changes in T7 did not restore the deletion or duplicate major regions of the genome. The ability of this deleted genome to recover much of the lost fitness via mutations in its remaining genes reveals a considerable evolutionary potential to modify the interactions of its elements in maintaining an essential set of functions.     

Vaccinia virus morphogenesis is blocked by a temperature-sensitive mutation in the I7 gene that encodes a virion component.

The ts16 mutation of vaccinia virus WR (R. C. Condit, A. Motyczka, and G. Spizz, Virology 128:429-443, 1983) has been mapped by marker rescue to the I7L open reading frame located within the genomic HindIII I DNA fragment. The I7 gene encodes a 423-amino-acid polypeptide. Thermolabile growth was attributed to an amino acid substitution, Pro-344-->Leu, in the predicted I7 protein. A normal temporal pattern of viral protein synthesis was elicited in cells infected with ts16 at the nonpermissive temperature (40 degrees C). Electron microscopy revealed a defect in virion assembly at 40 degrees C. Morphogenesis was arrested at a stage subsequent to formation of spherical immature particles. Western immunoblot analysis with antiserum directed against the I7 polypeptide demonstrated an immunoreactive 47-kDa polypeptide accumulating during the late phase of synchronous vaccinia virus infection. Immunoblotting of extracts of wild-type virions showed that the I7 protein is encapsidated within the virus core. The I7 polypeptide displays amino acid sequence similarity to the type II DNA topoisomerase of Saccharomyces cerevisiae.     

The human DNA ligase III gene encodes nuclear and mitochondrial proteins

We provide evidence that the human DNA ligase III gene encodes a mitochondrial form of this enzyme. First, the DNA ligase III cDNA contains an in-frame ATG located upstream from the putative translation initiation start site. The DNA sequence between these two ATG sites encodes an amphipathic helix similar to previously identified mitochondrial targeting peptides. Second, recombinant green fluorescent protein harboring this sequence at its amino terminus was efficiently targeted to the mitochondria of Cos-1 monkey kidney cells. In contrast, native green fluorescent protein distributed to the cytosol. Third, a series of hemagglutinin-DNA ligase III minigene constructs were introduced into Cos-1 cells, and immunocytochemistry was used to determine subcellular localization of the epitope-tagged DNA ligase III protein. These experiments revealed that inactivation of the upstream ATG resulted in nuclear accumulation of the DNA ligase III protein, whereas inactivation of the downstream ATG abolished nuclear localization and led to accumulation within the mitochondrial compartment. Fourth, mitochondrial protein extracts prepared from human cells overexpressing antisense DNA ligase III mRNA possessed substantially less DNA ligase activity than did mitochondrial extracts prepared from control cells. DNA end-joining activity was also substantially reduced in extracts prepared from antisense mRNA-expressing cells. From these results, we conclude that the human DNA ligase III gene encodes both nuclear and mitochondrial enzymes. DNA ligase plays a central role in DNA replication, recombination, and DNA repair. Thus, identification of a mitochondrial form of this enzyme provides a tool with which to dissect mammalian mitochondrial genome dynamics.     

DNA ligase activity in UV-irradiated monkey kidney cells.

The DNA ligase activity of monkey kidney CV-1 cells has been measured at different stages of culture growth and after different time intervals following ultraviolet irradiation. Results indicate that: - The level of enzyme activity is about twice higher in non synchronous, rapidly dividing cells than in confluent cultures. - UV-irradiation of cells induces a "de novo" synthesis of DNA ligase. - This induction is dose dependent in its extent and kinetics, and may lead to a DNA ligase level in UV-irradiated stationary cultures of the same order as observed in unirradiated exponentially growing cells. - This induction seems to be independent of semiconservative DNA synthesis since it is not affected by fluorodeoxyuridine.     

Vaccinia virus A6L encodes a virion core protein required for formation of mature virion

Vaccinia virus A6L is a previously uncharacterized gene that is conserved in all sequenced vertebrate poxviruses. Here, we constructed a recombinant vaccinia virus encoding A6 with an epitope tag and showed that A6 was expressed in infected cells after viral DNA replication and packaged in the core of the mature virion. Furthermore, we showed that A6 was essential for vaccinia virus replication by performing clustered charge-to-alanine mutagenesis on A6, which resulted in two vaccinia virus mutants (vA6L-mut1 and vA6L-mut2) that displayed a temperature-sensitive phenotype. At 31 degrees C, both mutants replicated efficiently; however, at 40 degrees C, vA6L-mut1 grew to a low titer, while vA6L-mut2 failed to replicate. The A6 protein expressed by vA6L-mut2 exhibited temperature-dependent instability. At the nonpermissive temperature, vA6L-mut2 was normal at viral gene expression and viral factory formation, but it was defective for proteolytic processing of the precursors of several major virion proteins, a defect that is characteristic of a block in virion morphogenesis. Electron microscopy further showed that the morphogenesis of vA6L-mut2 was arrested before the formation of immature virion with nucleoid and mature virion. Taken together, our data show that A6 is a virion core protein that plays an essential role in virion morphogenesis.