Evolution of DNA ligases of nucleo-cytoplasmic large DNA viruses of eukaryotes: a case of hidden complexity.

BACKGROUND: Eukaryotic Nucleo-Cytoplasmic Large DNA Viruses (NCLDV) encode most if not all of the enzymes involved in their DNA replication. It has been inferred that genes for these enzymes were already present in the last common ancestor of the NCLDV. However, the details of the evolution of these genes that bear on the complexity of the putative ancestral NCLDV and on the evolutionary relationships between viruses and their hosts are not well understood. RESULTS: Phylogenetic analysis of the ATP-dependent and NAD-dependent DNA ligases encoded by the NCLDV reveals an unexpectedly complex evolutionary history. The NAD-dependent ligases are encoded only by a minority of NCLDV (including mimiviruses, some iridoviruses and entomopoxviruses) but phylogenetic analysis clearly indicated that all viral NAD-dependent ligases are monophyletic. Combined with the topology of the NCLDV tree derived by consensus of trees for universally conserved genes suggests that this enzyme was represented in the ancestral NCLDV. Phylogenetic analysis of ATP-dependent ligases that are encoded by chordopoxviruses, most of the phycodnaviruses and Marseillevirus failed to demonstrate monophyly and instead revealed an unexpectedly complex evolutionary trajectory. The ligases of the majority of phycodnaviruses and Marseillevirus seem to have evolved from bacteriophage or bacterial homologs; the ligase of one phycodnavirus, Emiliana huxlei virus, belongs to the eukaryotic DNA ligase I branch; and ligases of chordopoxviruses unequivocally cluster with eukaryotic DNA ligase III. CONCLUSIONS: Examination of phyletic patterns and phylogenetic analysis of DNA ligases of the NCLDV suggest that the common ancestor of the extant NCLDV encoded an NAD-dependent ligase that most likely was acquired from a bacteriophage at the early stages of evolution of eukaryotes. By contrast, ATP-dependent ligases from different prokaryotic and eukaryotic sources displaced the ancestral NAD-dependent ligase at different stages of subsequent evolution. These findings emphasize complex routes of viral evolution that become apparent through detailed phylogenomic analysis but not necessarily in reconstructions based on phyletic patterns of genes. REVIEWERS: This article was reviewed by: Patrick Forterre, George V. Shpakovski, and Igor B. Zhulin.

Caspase-dependent induction of apoptosis in barramundi, Lates calcarifer (Bloch), muscle cells by grouper iridovirus.

We recently reported that grouper iridovirus (GIV) can induce apoptosis in barramundi, Lates calcarifer, muscle (BM) and swim bladder (BSB) cell lines. In this paper, we further characterize the molecular mechanism underlying apoptotic death in BM cells triggered by GIV. DNA-laddering and apoptotic cells were observed in BM cells infected with UV-irradiated or untreated GIV but was absent in cells infected with heat-inactivated GIV, indicating the involvement of viral protein in the apoptosis event. In GIV-infected BM cells, the conversion of procaspase-3 to caspase-3 was evident and the level of caspase-8 and -9 increased as early as 30 min post-infection. When treated with a pancaspase inhibitor, the GIV-induced apoptosis event was abolished. These observations indicate that GIV-induced apoptosis is caspase-dependent, and that both the external and internal routes in the caspase-dependent pathway are likely involved in the apoptosis process.

Constitutive expression of thymidylate synthase from LCDV-C induces a transformed phenotype in fish cells.

Thymidylate synthase (TS), an essential enzyme in DNA synthesis and repair, plays a key role in the events of cell cycle regulation and tumor formation. Here, an investigation was presented about subcellular location and biological function of viral TS from lymphocystis disease virus from China (LCDV-C) in fish cells. Fluorescence microscopy revealed that LCDV-C TS was predominantly localized in the cytoplasm in fish cells. Cell cycle analysis demonstrated that LCDV-C TS promoted cell cycle progression into S and G2/M phase in the constitutive expressed cells. As a result, the cells have a faster growth rate compared with the control cells as revealed by cell growth curves. For foci assay, the TS-expressed cells gave rise to foci 4-5 weeks after incubation. Microscopic examination of the TS-induced foci revealed multilayered growth and crisscross morphology characteristic of transformed cells. Moreover, LCDV-C TS predisposed the transfected cells to acquire an anchorage-independent phenotype and could grow in 0.3% soft agar. So the data reveal LCDV-C TS is sufficient to induce a transformed phenotype in fish cells in vitro and exhibits its potential ability in cell transformation. To our knowledge, it is the first report on viral TS sequences associated with transforming activity.

RING finger proteins of infectious spleen and kidney necrosis virus (ISKNV) function as ubiquitin ligase enzymes.

Infectious spleen and kidney necrosis virus (ISKNV) is the etiological agent that causes a pandemic and severe disease in fish characteristic of enlarged and damaged spleen and kidney. To identify viral proteins involved in infection and pathogenesis, we characterized five open reading frames (ORFs) of the ISKNV genome, ORF12, ORF65, ORF66, ORF99 and ORF111, which encode RING finger proteins (RFPs). We assessed the ubiquitin ligase (E3) activity of these recombinant RFPs fused to maltose-binding protein (MBP) using an in vitro ubiquitination assay and demonstrated that ORF12, ORF65, ORF66 and ORF111 possess the E3 activity in the presence of ubiquitin activating enzyme (E1), ubiquitin conjugating enzyme (E2), ubiquitin and zinc ion. E3 activity of ISKNV RFPs strictly depends on the UbcH5 E2 subfamily (ORF12 and ORF65 depend on UbcH5a/c, ORF66 and ORF111 depend on UbcH5a/b/c). Furthermore, point mutation in the RING domain completely abrogated ORF66 E3 activity, indicating the RING motif was essential for RFP of ISKNV. In addition, zinc ion was required as an enhancer for ISKNV RFP to exert its E3 function. Investigation of RFPs of ISKNV helps to understand their functions in the infection process and in the virus-host interaction.

Characterization of the Rana grylio virus 3beta-hydroxysteroid dehydrogenase and its novel role in suppressing virus-induced cytopathic effect.

The 3beta-hydroxysteroid dehydrogenase (3beta-HSD) isoenzymes play a key role in cellular steroid hormone synthesis. Here, a 3beta-HSD gene homolog was cloned from Rana grylio virus (RGV), a member of family Iridoviridae. RGV 3beta-HSD gene has 1068bp, encoding a 355aa predicted protein. Transcription analyses showed that RGV 3beta-HSD gene was transcribed immediate-early during infection from an initiation site 19 nucleotides upstream of the translation start site. Confocal microscopy revealed that the 3beta-HSD-EGFP fusion protein was exclusively colocalized with the mitochondria marker (pDsRed2-Mito) in EPC cells. Upon morphological observation and MTT assay, it was revealed that overexpression of RGV 3beta-HSD in EPC cells could apparently suppress RGV-induced cytopathic effect (CPE). The present studies indicate that the RGV immediate-early 3beta-HSD gene encodes a mitochondria-localized protein, which has a novel role in suppressing virus-induced CPE. All these suggest that RGV 3beta-HSD might be a protein involved in host-virus interaction.

Phylogenetic position of the Diadromus pulchellus ascovirus DNA polymerase among viruses with large double-stranded DNA genomes.

The ASCOVIRIDAE: is a family of large double-stranded (ds) DNA insect viruses that contains four species, the Spodoptera frugiperda (SfAV1), Trichoplusia ni (TnAV2), Heliothis virescens (HvAV3) and Diadromus pulchellus (DpAV4) ascoviruses. These are unique among insect viruses in that the primary means of transmission among their lepidopteran hosts is generally by being vectored mechanically by hymenopteran parasitoids. Ascoviruses are similar in virion structure, but their relationships with their parasitoid vectors vary from being opportunistic to obligate. Little is known, however, about the relatedness of these viruses to one another or to other large dsDNA viruses. We therefore cloned and sequenced the delta DNA polymerase gene of DpAV4, characterized it and compared it to 59 eukaryotic and viral delta and epsilon DNA polymerases. Phylogenetic analyses based on these genes revealed that the ascoviruses DpAV4 and SfAV1 formed a group of virus species distinct from, but closely related to, species of the family IRIDOVIRIDAE: Detailed analyses of the relatedness of ascovirus species based on conserved delta DNA polymerase motifs showed two groups within the family ASCOVIRIDAE:, one containing DpAV4 and the other containing SfAV1, TnAV2 and HvAV3, which was consistent with their host-vector relationships. Despite significant differences in capsid symmetry between ascoviruses and iridoviruses, these results suggest that these viruses may have originated from a common ancestral virus.

Identification of a gene cluster within the genome of Chilo iridescent virus encoding enzymes involved in viral DNA replication and processing.

The nucleotide sequence of the genome of Chilo iridescent virus (CIV) between the genome coordinates 0.974 and 0.101 comprising 27,079 bp was determined. Computer-assisted analysis of the DNA sequence of this particular region of the CIV genome revealed the presence of 42 potential open reading frames (ORFs) with coding capacities for polypeptides ranging from 50 to 1,273 amino acid residues. The analysis of the amino acid sequences deduced from the individual ORFs resulted in the identification of 10 potential viral genes that show significant homology to functionally characterized proteins of other species. A cluster of five viral genes that encode enzymes involved in the viral DNA replication was identified including the DNA topoisomerase II (A039L,1,132 amino acids (aa)), the DNA polymerase (ORF A031L,1,273 aa), a helicase (ORF A027L, 530 aa), a nucleoside triphosphatase I (ORF A025L, 1,171 aa), and an exonuclease II (ORF A019L, 624aa), all ORFs possessing the same genomic orientation. The DNA polymerase of CIV showed the highest homology (24.8% identity) to the DNA polymerase of lymphocystis disease virus lymphocystis disease virus 1 (LCDV-1), a member of the family Iridoviridae, indicating the close relatedness of the two viruses. In addition, four putative gene products were found to be significantly homologous to previously identified hypothetical proteins of CIV.

Identification of a thymidylate synthase gene within the genome of Chilo iridescent virus.

The thymidylate synthase (TS, EC 2.1.1.45) is essential for the de novo synthesis of dTMP in pro- and eucaryotic organisms. Consequently it plays a major role in the replication of the DNA genome of a cell or a DNA virus. The gene encoding the TS of Chilo iridescent virus (CIV) was identified by nucleotide sequence analysis of the viral genome and was mapped within the EcoRI CIV DNA fragments G and R. Computer assisted analysis of the DNA nucleotide sequence between the genome coordinates 0.482 and 0.489 revealed an open reading frame (ORF) of 885 nucleotides. This ORF was found to encode a polypeptide of 295 amino acid residues (33.9 kDa) that showed significant homologies to known TS of different species including mammals, plants, fungi, protozoa, bacteria, and DNA viruses. The highest amino acid homologies were found between the CIV-TS and the TS of herpesvirus ateles (54.0%), Saccharomyces cerevisiae (51.8%), herpesvirus saimiri (51.0%), rhesus monkey rhadinovirus (50.7%), mouse (50.5%), rat (50.2%), varicella-zoster virus (50.2%), equine herpesvirus 2 (50.0%), and the human TS (48.4%). The CIV-TS contains six amino acid domains that are highly conserved in the TS of other species. Within these domains the major amino acid residues are present for which a functional role has been reported. The CIV-TS was found to be more closely related to the TS of eucaryotes than to the TS of procaryotes indicating the phylogenetic origin of the CIV-TS gene. The identification of a TS gene in the genome of CIV is the first report of a viral TS that is not encoded by a herpesvirus or a bacteriophage.

Identification of the gene encoding the DNA (cytosine-5) methyltransferase of lymphocystis disease virus.

The gene encoding the DNA (cytosine-5) methyltransferase (m5C-MTase) of lymphocystis disease virus (flounder isolate, LCDV-1) has been identified by polymerase chain reaction (PCR) using oligonucleotide primers synthesized corresponding to different regions of the m5C-MTase gene of frog virus 3 (FV3). A DNA fragment of 487 bp was amplified using oligonucleotide primers L3 and R4 which correspond to the nucleotide positions 87 to 109 and 530 to 550 of the m5C-MTase gene of FV3, respectively. The DNA nucleotide sequence of the PCR product was determined by direct cycle sequencing. The alignment of the deduced amino acid sequence derived from the PCR product and the m5C-MTase protein of FV3 revealed a homology of 55.4% identity and 29.1% similarity. The amino acid sequence which was found to be significantly homologous to the amino acid sequence deduced from the nucleotide sequence of the PCR product was located at the amino acid position 37 to 175 of the m5C-MTase of FV3 indicating the specificity of the amplified PCR product. The DNA nucleotide sequence of the LCDV-1 genome corresponding to the 5' and 3' termini of the m5C-MTase gene was determined by primer walking. The locus of the m5C-MTase gene of LCDV-1 was identified within the EcoRI DNA fragment G of LCDV-1 (7.9 kbp; 0.947 to 0.034 map units). The m5C-MTase gene of LCDV-1 comprises 684 nucleotides coding for a putative protein of 228 amino acid residues. A high degree of amino acid sequence homology (53.3% identity and 25.8% similarity) was detected between the m5C-MTase of LCDV-1 and FV3.

Identification and properties of the largest subunit of the DNA-dependent RNA polymerase of fish lymphocystis disease virus: dramatic difference in the domain organization in the family Iridoviridae.

Cytoplasmic DNA viruses encode a DNA-dependent RNA polymerase (DdRP) that is essential for transcription of viral genes. The amino acid sequences of the known largest subunits of DdRPs from different species contain highly conserved regions. Oligonucleotide primers, deduced from two conserved domains (RQP[T/S]LH and NADFDGDE) were used for detecting the corresponding gene of fish lymphocystis disease virus (FLCDV), a member of the family Iridoviridae, which replicates in the cytoplasm of infected cells of flatfish. The gene coding for the largest subunit of the DdRP was identified using a PCR-derived probe. The screening of the complete EcoRI gene library of the viral genome led to the identification of the gene locus of the largest subunit of the DdRP within the EcoRI DNA fragment B (12.4 kbp, 0.034 to 0.165 map units). The nucleotide sequence of a part (8334 bp) of the EcoRI DNA fragment B was determined and a large ORF on the lower strand (ATG = 5787; TAA = 2190) was detected which encodes a protein of 1199 amino acids. Comparison of the amino acid sequences of the largest subunits of the DdRP (RPO1) of FLCDV and Chilo iridescent virus (CIV) revealed a dramatic difference in their domain organization. Unlike the 1051 aa RPO1 of CIV, which lacks the C-terminal domain conserved in eukaryotic, eubacterial and other viral RNA polymerases, the 1199 aa RPO1 of FLCDV is fully collinear with its cellular and viral homologues. Despite this difference, comparative analysis of the amino acid sequences of viral and cellular RNA polymerases suggests a common origin for the largest RNA polymerase subunits of FLCDV and CIV.

Evolution of viral DNA-dependent RNA polymerases.

The DNA-dependent RNA polymerase (DdRP or RNAP) is an essential enzyme of transcription of replicating systems of prokaryotic and eukaryotic organisms as well as cytoplasmic DNA viruses. DdRPs are complex multisubunit enzymes consisting of 8-14 subunits, including two large subunits and several smaller polypeptides (small subunits). An extensive search between the amino acid sequences of the known largest subunit of DNA-dependent RNA polymerases (RPO1) of different organisms indicates that all these polypeptides possess a universal heptapeptide NADFDGD in domain D. All RPO1 harbor a second well-conserved hexapeptide RQP(TS)LH upstream (26-31 amino acids) of the universal motif. The genes encoding the largest subunit of DdRP of insect iridescent virus type 6 (IIV6), fish lymphocystis disease virus (LCDV), and molluscum contagiosum virus (MCV-1), all members of the group of cytoplasmic DNA viruses, were identified by PCR technology. With the exception of IIV6, all other viral RPO1 possess the two C-terminal conserved regions G and H. The lack of C-terminal repetitive heptapeptide (YSPTSPS), which is a common feature of the largest subunit of eukaryotic RNAPII, is an additional characteristic of RPO1 proteins of LCDV and of MCV-1. All viral RPO1 proteins were found to be lacking the amino acid N at a distinct position in domain F. This amino acid is known to be highly conserved in alpha-amanitin-sensitive eukaryotic RNA polymerases II. Comparison of the amino acid sequences of the RPO1 polypeptides of IIV6, LCDV, and MCV-1 with the corresponding prokaryotic, eukaryotic, and viral proteins revealed differences in amino acid similarity and phylogenetic relationships. IIV6 RPO1 possesses the closest similarity to the homologous subunit of eukaryotic RNAPII and lower but also significant similarity to that of eukaryotic RNAPI and RNAPIII, archaeal, eubacterial, and viral polymerases. The similarity between RPO1 of IIV6 and the cellular polymerase subunits is consistently higher than to the RPO1 of other cytoplasmic DNA viruses, for example, vaccinia and variola virus, African swine fever virus (ASFV), and MCV-1. The RPO1 of LCDV shows the highest similarity to the RPO1 of IIV6 and significant lower similarity to the eukaryotic polymerases II and III as well as to the archaebacteral subunit. However, it is still considerably more similar to the cellular polymerase subunits than to the homologous viral proteins. The RPO1 of IIV6 possesses more similarity to cellular polymerases than the complete RPO1 of LCDV, indicating that there is a substantial difference in the organization of the RPO1 genes between these members of two genera of the Iridoviridae family. Analysis of the MCV-1 RPO1 revealed high amino acid homologies to the corresponding polypeptides of vaccinia and variola virus. The viral RPO1 proteins, including vaccinia and variola virus, MCV-1, ASFV, IIV6, and LCDV, share the common feature of showing the highest similarity to the largest subunit of eukaryotic RNAPII than to that of RNAPI, RNAPIII, and RPO1 of archaebacterias, eubacterias, ASFV, IIV6, and LCDV. Evolution of the individual largest subunit of DdRPs was tentatively investigated by generating phylogenetic trees using multiple amino acid alignments. These indicate that the RPO1 proteins of IIV6 and LCDV might have evolved from the largest subunit of eukaryotic RNAPII after divergence from the homologous subunits of RNAPI and RNAPIII. In contrast, evolutionary development of the RPO1 of vaccinia and variola virus, MCV-1, and ASFV seems to be quite different, with their common ancestor diverging from cellular homologues before the separation of the three types of eukaryotic ploymerases and having probably diverged earlier from their common lineage with cellular proteins.

Metabolism of host and viral mRNAs in frog virus 3-infected cells.

Treatment of purified frog virus 3 (FV3) with nonionic detergent and high salt released an endoribonucleolytic activity and confirmed earlier findings of a virion-associated endonuclease. This observation, coupled with evidence implicating host and viral message destabilization in herpesvirus and poxvirus biogenesis, raised the question of what role, if any, mRNA degradation plays in FV3 replication. To answer this question, Northern analyses of mock- and virus-infected cells were performed using probes for representative host and viral messages. These studies demonstrated that the steady state level of host messages progressively declined during the course of productive FV3 infection, whereas the steady state level of viral messages was not affected. To determine whether the decline in the steady state level of host mRNA was due to virus-induced degradation or to normal turnover coupled to virus-mediated transcriptional shut-off, actin mRNA levels were examined in mock- and virus-infected cells in the presence and absence of actinomycin D. Under these conditions, actin mRNA levels declined more quickly in actinomycin D-treated, virus-infected cells, than in mock-infected cells incubated in the presence of actinomycin D suggesting that the decline in the steady state level of actin mRNA was due to degradation. However, although it appears as if host message degradation is responsible for virus-mediated translational shut-off, the ability of heat-inactivated FV3 to block cellular translation without destabilizing cellular messages indicates that message degradation is not required for translational inhibition. As noted above, the degradation of early FV3 messages was not involved in controlling the transition from early to late gene expression. Furthermore, the presence of abundant, but nontranslated, early messages late in infection, coupled with the inefficient translation of late messages in vitro supported earlier suggestions that FV3 gene expression is controlled, at least in part, at the translational level. Taken together, these results suggest that FV3 regulates gene expression in a unique manner and may be a good model to examine the mechanics of translational control.

The primary structure of the thymidine kinase gene of fish lymphocystis disease virus.

The DNA nucleotide sequence of the thymidine kinase (TK) gene of fish lymphocystis disease virus (FLDV) which has been localized between the coordinates 0.678 to 0.688 of the viral genome was determined. The analysis of the DNA nucleotide sequence located between the recognition sites of HindIII (0.669 map unit; nucleotide position 1) and AccI (nucleotide position 2032) revealed the presence of an open reading frame of 954 bp on the lower strand of this region between nucleotide positions 1868 (ATG) and 915 (TAA). It encodes for a protein of 318 amino acid residues. The evolutionary relationships of the TK gene of FLDV to the other known TK genes was investigated using the method of progressive sequence alignment. These analyses revealed a high degree of diversity between the protein sequence of FLDV TK gene and the amino acid composition of other TKs tested. However, significant conservations were detected at several regions of amino acid residues of the FLDV TK protein when compared to the amino acid sequence of TKs of African swine fever virus, fowlpox virus, shope fibroma virus, and vaccinia virus and to the amino acid sequences of the cellular cytoplasmic TK of chicken, mouse, and man.

Evidence for an acid phosphatase in African swine fever virus.

An acid phosphatase activity has been detected in purified preparations of African swine fever virus. Purified viral cores obtained after Nonidet-P40 and 2-mercaptoethanol treatment of the virus retained the activity as assayed with nitrophenyl phosphate as substrate at pH 5. Enzyme cytochemistry by electron microscopy showed that the acid phosphatase activity is localized mainly inside the core of the virion. The molecular weight and the isoelectric point of the virus acid phosphatase activity confirmed that it was distinct from the host cellular enzyme.

Interferon cures cells lytically and persistently infected with African swine fever virus in vitro.

Human interferon alpha (IFN-alpha) and interferon gamma (IFN-gamma) inhibit African swine fever (ASF) virus replication in Vero cells. IFN-alpha and IFN-gamma exert a synergistic inhibition. Human tumor necrosis factor (TNF) does not inhibit ASF virus replication in this cell line, but in combination with IFNs it has antiviral enhancing activity. Analysis of the mechanism of inhibition suggests that the action of these cytokines blocks a step that comes prior to DNA replication. The 2'-5' A synthetase activity is induced in Vero cells by treatment with these cytokines and is activated after ASF virus infection. More interesting is the finding that continuous treatment with IFN-alpha cures Vero cells from lytic and persistent infections with ASF virus. A potential application of IFN for the treatment of animals carrying the virus is suggested.

Transcription of methylated viral DNA by eukaryotic RNA polymerase II.

The genome of the large icosahedral DNA virus, frog virus 3 (FV3), is heavily methylated at the cytosine residues of dCdG dinucleotide pairs, with more than 22% of the total cytosine residues in the form of 5-methylcytosine (5mC). This methylation is carried out postreplicatively in the cytoplasm of infected cells by a virus-encoded DNA methyltransferase. DNA methyltransferase activity was shown to copurify with a 26 kD virus-induced, DNA-binding protein that had an altered mobility in extracts from cells infected with a DNA-methyl-transferase deficient mutant of FV3. Immediately after infection, the highly methylated parental DNA is transcribed in the nucleus by the host cell RNA polymerase II. As FV3 induces the synthesis of a protein that can override the inhibitory effect of methylation on the transcription of exogenous promoters methylation in vitro, we suggest that this protein is a factor evolved by this virus to allow transcription from methylated promoters by eukaryotic RNA polymerase II.

Identification, mapping and cloning of the thymidine kinase gene of fish lymphocystis disease virus.

The thymidine kinase (TK) gene of fish lymphocystis disease virus (FLDV) was identified by biochemical transformation of 3T3 TK negative (TK-) to 3T3 TK positive (TK+) cells using specific viral DNA sequences. DNA fragments of the viral genome used in this study were obtained from a defined gene library of FLDV genome containing the complete viral DNA sequences. The selection of the converted cells was carried out under the condition of the HAT selection procedure. The results of these experiments revealed that the EcoRI FLDV DNA fragment C (11.2 kbp; 0.611 to 0.718 map units) is able to transform 3T3 TK- to 3T3 TK+ cells. Additional experiments using the subclones of EcoRI DNA fragment C revealed that DNA sequences of 4.1 kbp size between the coordinates 0.669 to 0.718 of the FLDV genome possessed the ability for biochemical transformation, indicating that the TK gene locus is located in this particular region.

Mutation in a DNA-binding protein reveals an association between DNA-methyltransferase activity and a 26,000-Da polypeptide in frog virus 3-infected cells.

The DNA of frog virus 3 (FV3), an iridovirus, is highly methylated; more than 20% of the cytosine bases are methylated at the 5-carbon position by an FV3-induced DNA methyltransferase (DNA-mt). To determine the role of this enzyme in virus replication and regulation of gene expression, we have analyzed an FV3 mutant that lacks DNA-mt activity and is resistant to 5-azacytidine (an inhibitor of DNA-mt). Comparative polypeptide analysis, using cytoplasmic extracts from the wild-type FV3 and mutant-infected cells, revealed that a single protein of 26,000 (26K) molecular weight was altered in the mutant-infected cells. The altered polypeptide migrated faster in SDS-polyacrylamide gel as compared to the wild-type FV3 26K protein. Five spontaneous revertants derived from the mutant regained the migrational characteristic of the wild-type 26K protein, DNA-mt activity, and methylation of their DNA. We further show that the 26K polypeptide is a DNA-binding protein and that 80% of the enzyme activity can be eluted from an ssDNA affinity column. Taken together, these data support the conclusion that the 26K polypeptide is associated with DNA-mt activity.