DNA sequence analysis of the region encoding the terminal protein and the hypothetical N-gene product of adenovirus type 2

Heat Shock Protein 90 Chaperones E1A Early Protein of Adenovirus 5 and Is Essential for Replication of the Virus

Adenovirus infections tend to be mild, but they may pose a serious threat for young and immunocompromised individuals. The treatment is complicated because there are no approved safe and specific drugs for adenovirus infections. Here, we present evidence that 17-(Allylamino)-17-demethoxygeldanamycin (17-AAG), an inhibitor of Hsp90 chaperone, decreases the rate of human adenovirus 5 (HAdV-5) replication in cell cultures by 95%. 17-AAG inhibited the transcription of early and late genes of HAdV-5, replication of viral DNA, and expression of viral proteins. 6 h after infection, Hsp90 inhibition results in a 6.3-fold reduction of the newly synthesized E1A protein level without a decrease in the E1A mRNA level. However, the Hsp90 inhibition does not increase the decay rate of the E1A protein that was constitutively expressed in the cell before exposure to the inhibitor. The co-immunoprecipitation proved that E1A protein interacted with Hsp90. Altogether, the presented results show, for the first time. that Hsp90 chaperones newly synthesized, but not mature, E1A protein. Because E1A serves as a transcriptional co-activator of adenovirus early genes, the anti-adenoviral activity of the Hsp90 inhibitor might be explained by the decreased E1A level.

Identification of the adenovirus type 2 C-168 protein

A hitherto predicted but undetected protein, C-168, in adenovirus type 2 (Ad2) has been identified using mass spectrometry (MS) based proteomics. The gene of this 17.7kDa protein is located on the forward strand in the major late transcription unit between base pairs 9294 and 9797. A tryptic peptide, derived from the C-terminal part of the protein, was identified with high amino acid sequence coverage. A candidate splice site for the corresponding mRNA is also presented. The protein sequence is unusual with repeats of serine, glycine and arginine. A bioinformatics prediction of protein function and localization is presented.

Identification of transcripts and promoter regions of ovine adenovirus OAV287

The ovine adenovirus isolated OAV287 represents a new group of adenoviruses that are distinct from the Mast- and Aviadenoviruses by several criteria, including genome arrangement. The OAV major late promoter and some late transcripts were previously mapped. To better define the probable coding sequences and to identify the approximate location of early promoters a partial transcription map of the genome was elucidated using a PCR-based approach. This was possible because the complete nucleotide sequence of the genome was known. The strategy permitted the identification of transcription start sites and RNA splice junctions and allowed the approximate location of promoters in the lefthand end, IVa2, E2, P32K, and E4 regions to be deduced. The data showed that lefthand end and E4 regions are controlled by three and two temporally distinct promoters, respectively. The E2 region is controlled by a single promoter, in contrast to Mastadenoviruses, where E2 expression is controlled by the E2A and E2B promoters. The p32kDa structural protein at the lefthand end and the IVa2 protein are also expressed from their own promoters. These data contribute to the first overview of transcription from a non-Mastadenovirus genome.

The terminal protein of the linear DNA plasmid pGKL2 shares an N-terminal domain of the plasmid-encoded DNA polymerase

The 36K protein attached at the 5' end of the linear DNA plasmid pGKL2 from the yeast Kluyveromyces lactis was first purified and characterized. The terminal protein was purified from cells (1 kg wet weight) by ammonium sulphate precipitation and two rounds of centrifugation to equilibrium in CsCl gradients. The pGKL2 was present only in the post-microsomal supernatant. Approximately 10 mg of the purified pGKL2 was recovered and digested with DNase I. The terminal protein (final ca. 0 center dot 8 mg) was homogeneous by electrophoresis and we determined the N-terminal amino acid sequence up to ten residues, showing that it existed in the cryptic N-terminal domain of pGKL2-ORF2 (DNA polymerase) sequence.

Evolution of linear plasmids

Linear plasmids are genetic elements commonly found in yeast, filamentous fungi, and higher plants. In contrast to all other plasmids they possess terminal inverted repeats and terminal bound proteins and encode their own DNA and RNA polymerases. Here we present alignments of conserved amino acid sequences of both the DNA and RNA polymerases encoded by those linear plasmids for which DNA sequence data are available. Additionally these sequences are compared to a number of polymerases encoded by related viral and cellular entities. Phylogenetic trees have been established for both types of polymerases. These trees appear to exhibit very similar subgroupings, proving the accuracy of the method employed.

The linear mitochondrial plasmid pAL2-1 of a long-lived Podospora anserina mutant is an invertron encoding a DNA and RNA polymerase

The molecular characterization of an additional DNA species (pAL2-1) which was identified previously in a long-lived extrachromosomal mutant (AL2) of Podospora anserina revealed that this element is a mitochondrial linear plasmid. pAL2-1 is absent from the corresponding wild-type strain, has a size of 8395 bp and contains perfect long terminal inverted repeats (TIRs) of 975 bp. Exonuclease digestion experiments indicated that proteins are covalently bound at the 5' termini of the plasmid. Two long, non-overlapping open reading frames, ORF1 (3,594 bp) and ORF2 (2847 bp), have been identified, which are located on opposite strands and potentially encode a DNA and an RNA polymerase, respectively. The ORF1-encoded polypeptide contains three conserved regions which may be responsible for a 3'-5' exonuclease activity and the typical consensus sequences for DNA polymerases of the D type. In addition, an amino-acid sequence motif (YSRLRT), recently shown to be conserved in terminal proteins from various bacteriophages, has been identified in the amino-terminal part of the putative protein. According to these properties, this first linear plasmid identified in P. anserina shares all characteristics with invertrons, a group of linear mobile genetic elements.

Molecular mimicry and the autoimmune response to the peripheral nerve myelin P0 glycoprotein

In the Lewis rat immunisation with the myelin P0 glycoprotein can induce an inflammatory demyelinating disease of the peripheral nervous system, experimental allergic neuritis (EAN), which has many clinical and histopathological parallels with the human disease the Guillain-Barre syndrome. In view of the reported association of GBS with a number of infectious agents we have investigated whether "molecular mimicry" may occur between microbial antigens and the P0 protein that could possibly trigger a similar pathogenic autoimmune response in man. A computer search of the available protein sequence data bases identified several absolute sequence homologies between P0 and viral proteins that involve five or more consecutive amino acid residues. Four of these sequence homologies involved viral pathogens previously associated with the Guillain-Barre syndrome, namely Epstein-Barr virus (EBV), cytomegalovirus (CMV), Varicella zoster virus (VZV) and human immunodeficiency virus I (HIV I). Although, sequence homologies were also found between viral peptides and the neuritogenic determinants of P0, residues 56-71 and 180-199, these homologies proved incapable of eliciting EAN in the Lewis rat. These observations are discussed with reference to the role that molecular mimicry between T cell epitopes on pathogen derived antigens and the P0 protein may play in the pathogenesis of the Guillain-Barre syndrome.

The kalilo linear senescence-inducing plasmid of Neurospora is an invertron and encodes DNA and RNA polymerases

The nucleotide sequence of kalilo, a linear plasmid that induces senescence in Neurospora by integrating into the mitochondrial chromosome, reveals structural and genetic features germane to the unique properties of this element. Prominent features include: (1) very long perfect terminal inverted repeats of nucleotide sequences which are devoid of obvious genetic functions, but are unusually GC-rich near both ends of the linear DNA; (2) small imperfect palindromes that are situated at the termini of the plasmid and are cognate with the active sites for plasmid integration into mtDNA; (3) two large, non-overlapping open-reading frames, ORF-1 and ORF-2, which are located on opposite strands of the plasmid and potentially encode RNA and DNA polymerases, respectively, and (4) a set of imperfect palindromes that coincide with similar structures that have been detected at more or less identical locations in the nucleotide sequences of other linear mitochondrial plasmids. The nucleotide sequence does not reveal a distinct gene that codes for the protein that is attached to the ends of the plasmid. However, a 335-amino acid, cryptic, N-terminal domain of the putative DNA polymerase might function as the terminal protein. Although the plasmid has been co-purified with nuclei and mitochondria, its nucleotide composition and codon usage indicate that it is a mitochondrial genetic element.

Genome organization of the linear plasmid, pSKL, isolated from Saccharomyces kluyveri

We have determined the complete nucleotide sequence of the linear DNA plasmid, pSKL, isolated from Saccharomyces kluyveri. Sequence analysis showed that pSKL has a high (A + T) content of 71.7%, and that there are 10 open reading frames (ORFs) larger than 250 nucleotides. All 10 ORFs were shown to be transcribed in S. kluyveri cells by S1 nuclease mapping analysis. The localization of ORFs, direction of transcription, and the predicted amino acid sequences of each ORF were quite similar to that of pGKL2, one of the killer plasmids found in Kluyveromyces lactis. The amino acid sequences of the largest two ORFs (ORF2 and ORF6) have homology with several DNA polymerases and RNA polymerases, respectively.

Linker mutation scanning of the genes encoding the adenovirus type 5 terminal protein precursor and DNA polymerase

The replication of adenovirus DNA requires, in addition to several host factors, three virus-encoded proteins: a DNA binding protein, the precursor of the terminal protein (pTP), and a DNA polymerase (Ad pol). Ad pol and pTP form a tight complex that is necessary for the initiation step in DNA replication. To perform mutation scanning of the adenovirus type 5 pTP and Ad pol a series of in-frame linker insertions of a 12-mer oligonucleotide d(CCCATCGATGGG) were introduced into cloned viral DNA fragments containing coding sequences of these proteins. The insertions are located at recognition sites for several blunt end-cutting restriction endonucleases. Forty different sites were mutagenized and the mutated genes were transferred to a plasmid that contains the left 42% of the adenovirus genome. They were rebuilt into the viral genome by means of in vivo recombination between plasmid DNA and digested adenovirus DNA-TP complex. The resulting viral genomes were tested for viability and rescued virus was analyzed for the presence of the inserted linker oligonucleotide. This procedure resulted in recovery of a number of viable virus mutants with insertions in the pTP or Ad pol genes, all of which are phenotypically silent. The other mutations did not allow virus production. The positions of these apparent lethal codon insertion mutations were useful to identify regions of functional importance in both proteins. It can be concluded that the precursor-specific region of pTP plays an important role in virus multiplication.

Identification and sequencing of the Choristoneura biennis entomopoxvirus DNA polymerase gene

A degenerate oligonucleotide probe corresponding to a highly conserved amino acid sequence in several DNA polymerases was used to locate the DNA polymerase gene in the Choristoneura biennis entomopoxvirus. Southern blot analysis of the entomopoxvirus genome using the degenerate oligonucleotide probe showed specific interaction between the probe and an eight kilobasepair EcoRI fragment from the entomopoxvirus genome. Sequencing this EcoRI fragment revealed an open reading frame 2892 nucleotides in length, capable of encoding a protein about 115 kilodaltons. Homology search of this open reading frame against other proteins indicated a high degree of homology in four distinct regions with DNA polymerases from other organisms. The highest degree of homology (24.9% at the amino acid level) was found between the vaccinia DNA polymerase gene and the entomopoxvirus open reading frame.

Physical mapping of two temperature-sensitive adenovirus mutants affected in the DNA polymerase and DNA binding protein

We have determined the exact nature of two thermosensitive (ts) adenovirus mutants, H5ts19 and H5ts149, which map to different genes in the E2 transcription unit. The H5ts19 mutation appears to stem from a single base-pair change of A-T to G-C at position 1840 (numbering as in ref. 1), corresponding to codon 154 of the gene coding for DBP. This results in a glutamine-to-arginine change in the amino-terminal domain of the protein. H5ts19 is defective in a late stage of infection, during virus assembly. This phenotype strongly differs from that described for the limited number of known DBP mutants, indicating that DBP is not only functional during DNA replication, but also plays a role in the late phase of the infection cycle. The defect of the (N group) mutant H5ts149 affects the initiation of viral DNA replication. Marker rescue experiments followed by nucleotide sequence analysis of H5ts149 DNA revealed a single point mutation in the gene coding for the Ad pol. A transition of C-G to A-T at position 7563 (numbering as in ref. 2) changes amino acid residue 411 of Ad pol, a leucine residue, to phenylalanine. This mutation is located in a region conserved among various DNA polymerases, which suggests an important role of this domain in DNA replication.

A conserved 3'----5' exonuclease active site in prokaryotic and eukaryotic DNA polymerases

The 3'----5' exonuclease active site of E. coli DNA polymerase I is predicted to be conserved for both prokaryotic and eukaryotic DNA polymerases based on amino acid sequence homology. Three amino acid regions containing the critical residues in the E. coli DNA polymerase I involved in metal binding, single-stranded DNA binding, and catalysis of the exonuclease reaction are located in the amino-terminal half and in the same linear arrangement in several prokaryotic and eukaryotic DNA polymerases. Site-directed mutagenesis at the predicted exonuclease active site of the phi 29 DNA polymerase, a model enzyme for prokaryotic and eukaryotic alpha-like DNA polymerases, specifically inactivated the 3'----5' exonuclease activity of the enzyme. These results reflect a high evolutionary conservation of this catalytic domain. Based on structural and functional data, a modular organization of enzymatic activities in prokaryotic and eukaryotic DNA polymerases is also proposed.

The linear mitochondrial plasmid pClK1 of the phytopathogenic fungus Claviceps purpurea may code for a DNA polymerase and an RNA polymerase

Plasmid pClK1, a linear mitochondrial plasmid of Claviceps purpurea, was completely sequenced. The sequence contains two long open reading frames (ORF1, 3291 bp; ORF2, 2910 bp), and at least four smaller ORFs. The potential polypeptide derived from ORF1 shows homology to the family B type DNA polymerases. The product of ORF2 has significant homology to the mitochondrial RNA polymerase of yeast and RNA polymerases from bacteriophages. ORF1 and ORF2 show homology to URF3 and URF1 of the maize plasmids S1 and S2, respectively. No homology to any published protein sequence was found for the smaller ORFs. The origin of the terminal protein attached to the 5' ends of pClK1 remains open; several alternatives for its origin are discussed. The sequence data as a whole confirm the virus-like character of pClK1 already postulated from structural properties. Thus pClK1 together with S plasmids of maize and several other linear plasmids make up a distinct class of DNA species of plants and fungi probably derived from a common virus-like ancestor.

The herpes simplex virus DNA polymerase: analysis of the functional domains

The structural and functional organization of the herpes simplex virus type I (HSV-1) DNA polymerase enzyme of strain ANG was studied by a combination of sequence and immunobiochemical analyses. Comparison of the HSV-1 ANG DNA polymerase sequence with those of pro- and eukaryotic DNA polymerases resulted in the allocation of eleven conserved regions within the HSV-1 DNA polymerase. From the analysis of all currently identified mutations of temperature-sensitive and drug-resistant HSV-1 DNA polymerase mutants as well as from the degree of conservancy observed, it could be deduced that the amino-acid residues 597-961, comprising the homologous sequence regions IV-IX, constitute the major structural components of the catalytic domain of the enzyme which should accommodate the sites for polymerizing and 3'-to-5' exonucleolytic functions. Further insight into the structural organization was gained by the use of polyclonal antibodies responding specifically to the N-terminal, central and C-terminal polypeptide domains of the ANG polymerase. Each of the antisera was able to immunostain as well as to immunoprecipitate a viral polypeptide of 132 +/- 5 kDa that corresponded well to the molecular mass of 136 kDa predicted from the coding sequences. Enzyme-binding and neutralization studies confirmed that both functions, polymerase and 3'-to-5' exonuclease, are intimately related to each other, and revealed that, in addition to the sequences of the proposed catalytic domain, the very C-terminal sequences, except for amino-acid residues 1072-1146, are important for the catalytic functions of the enzyme, most likely effecting the binding to DNA.

Amino acid changes coded by bacteriophage T4 DNA polymerase mutator mutants. Relating structure to function

Previous studies on the selection of bacteriophage T4 mutator mutants have been extended and a method to regulate the mutator activity of DNA polymerase mutator strains has been developed. The nucleotide changes of 17 bacteriophage T4 DNA polymerase mutations that confer a mutator phenotype and the nucleotide substitutions of several other T4 DNA polymerase mutations have been determined. The most striking observation is that the distribution of DNA polymerase mutator mutations is not random; almost all mutator mutations are located in the N-terminal half of the DNA polymerase. It has been shown that the T4 DNA polymerase shares several regions of homology at the protein sequence level with DNA polymerases of herpes, adeno and pox viruses. From studies of bacteriophage T4 and herpes DNA polymerase mutants, and from analyses of similar protein sequences from several organisms, we conclude that DNA polymerase synthetic activities are located in the C-terminal half of the DNA polymerase and that exonucleolytic activity is located nearer the N terminus.

Viral RNA polymerases

Recent progress in molecular biological techniques revealed that genomes of animal viruses are complex in structure, for example, with respect to the chemical nature (DNA or RNA), strandedness (double or single), genetic sense (positive or negative), circularity (circle or linear), and so on. In agreement with this complexity in the genome structure, the modes of transcription and replication are various among virus families. The purpose of this article is to review and bring up to date the literature on viral RNA polymerases involved in transcription of animal DNA viruses and in both transcription and replication of RNA viruses. This review shows that the viral RNA polymerases are complex in both structure and function, being composed of multiple subunits and carrying multiple functions. The functions exposed seem to be controlled through structural interconversion.

The complete nucleotide sequence of the left very early region of Escherichia coli bacteriophage PRD1 coding for the terminal protein and the DNA polymerase

DNA molecules replicating in a linear form have been found in certain viruses and plasmids of both prokaryotic and eukaryotic origin. Characteristic of this type of molecules are the proteins covalently linked to their 5' ends and inverted terminal nucleotide sequences. The molecules replicate via a protein-priming mechanism, where participants include terminal protein and a specific polymerase. We report here the nucleotide sequence of the left very early region of Escherichia coli bacteriophage PRD1. This region codes for the terminal protein and the phage DNA polymerase. The predicted amino acid sequence of the terminal protein does not share homology with those of other known terminal proteins. The PRD1 DNA polymerase shows four regions of extensive homology to that of Bacillus subtilis phage phi 29. One of these conserved regions is also found in several animal virus DNA polymerases.

Nucleotide sequence of the DNA polymerase gene of herpes simplex virus type 2 and comparison with the type 1 counterpart

The complete nucleotide sequence of the DNA polymerase gene of herpes simplex virus (HSV) type 2 strain 186 has been determined. The gene included a 3720-bp major open reading frame capable of encoding 1240 amino acids. The predicted primary translation product had an Mr of 137,354, which was slightly larger than its HSV-1 counterpart. A comparison of the predicted functional amino acid sequences of the HSV-1 and HSV-2 DNA polymerases revealed 95.5% overall amino acid homology, the value of which was the highest among those of the other known polypeptides encoded by HSV-1 and HSV-2. The functional amino acid changes were spread in the N-terminal one-third of the protein, whereas the C-terminal two-third was almost identical between the two types except a particular hydrophilic region. A highly conserved sequence of 6 aa, YGDTDS, which has been observed in DNA polymerases of HSV-1, Epstein-Barr virus, adenovirus, and vaccinia virus, was also present at positions 889 to 894 in the C-terminal region of HSV-2 DNA polymerase.

A major internal initiation site for the in vitro translation of the adenovirus DNA polymerase

An open reading frame which encodes at least 90% of the adenovirus type 2 DNA polymerase gene was cloned behind the SP6 promoter and transcribed in vitro using the SP6 RNA polymerase. The resultant RNA was translated in a rabbit reticulocyte cell free system. In addition to the translation of a 120-kDa protein corresponding to the size of the complete open reading frame, the synthesis of a 62-kDa polypeptide was demonstrated. Data is presented to show that the synthesis of the 62-kDa polypeptide resulted from internal initiation of translation in frame in the middle of the message at the 11th or 12th AUG. Capping of the mRNA resulted in an increase in synthesis of the 120-kDa protein and a concordant decrease of the internally initiated polypeptide. We propose that there may be competition between the binding of the translational preinitiation complex at or near the 5' end of the mRNA and at the internal initiation site. Because of inhibition of synthesis of the 120-kDa but not the 62-kDa polypeptide by hybrid arrested translation using DNA complementary to approximately one third of the 5' Ad Pol mRNA sequences, scanning of the ribosome from the 5' end of the mRNA to the internal initiation site seemed unlikely. The sequence proximal to the 12th AUG is ACCCACCCCAUG which is similar to a noncontinuous sequence 5'AUCCACC(X)nAUG complementary to the 3' end of the 18 S rRNA. This sequence is a favored ribosome binding site based on the observation that it is the most commonly observed one at or near the 5' end of 162 mRNA's analyzed (D. R. Sargan, S. P. Gregory, and P. H. W. Butterworth, 1982, FEBS Lett. 147, 133-136).

Nucleotide sequence of the genes encoded in early region 2b of human adenovirus type 12

The nucleotide (nt) sequence of a cloned DNA segment containing the early 2b region of the class A adenovirus Ad12 has been determined. When compared to the corresponding region of Ad2 or Ad7, there is a high degree of nt and predicted amino acid (aa) sequence homology within the r-strand regions that encode the preterminal protein and the viral DNA polymerase. A gene coding region comparable to the Mr 13,600 gene product found in Ad2 can be identified; this hypothetical gene product shares 30% aa homology with its Ad2 counterpart and has a very similar hydropathy profile.

Presence in infected cells of nonvirion proteins encoded by adenovirus messenger RNAs of the major late transcription regions L0 and L1

The adenovirus major late promoter functions at early and intermediate times to produce a limited set of mRNAs that appear in the cytoplasm of productively infected HeLa cells. These mRNAs may be translated in cell-free systems to produce two unrelated polypeptides of approximately 13,500 Mr (L0-13.5K and L0-13.6K) and a pair of related polypeptides of approximately 55,000 Mr (the L1-52K/55K proteins). Radiochemical protein sequence analysis of in vitro synthesized proteins has identified the N-terminal sequences of the L0-13.5K and L0-13.6K proteins (J. B. Lewis and C. W. Anderson (1983), Virology 127, 112-123). Additional sequence analyses confirmed the identification of the open reading frame for the L0-13.5K protein, and identified the ATG encoded by nucleotides 11,040 to 11,042 from the left end of the adenovirus genome as the initial codon of the L1-52K/55K protein. Antisera raised against synthetic peptides homologous to these three amino termini were used to demonstrate the presence of the L0-13.5K protein, the L0-13.6K protein, and the L1-52K/55K proteins in extracts of HeLa cells infected by adenovirus 2. The L0-13.5K protein was detected at early, intermediate, and late times after infection. The L0-13.6K and L1-52K/55K proteins were detected only at late times. Immunofluorescence microscopy indicated that the L0-13.6K protein is distributed around the periphery of the nucleus and along fibers running the length of the cell. Nonpermeabilized infected cells were stained by anti-L0-13.6K peptide serum at a single spot on the cell surface. Neither the L0-13.6K nor the L1-52K/55K proteins were detected in purified virus.

Restriction maps of human adenovirus types 2, 5, and 3 for BstEII, MluI, NdeI, NruI and SfiI endonucleases

The positions of cleavage sites for BstEII, MluI, NdeI, NruI and SfiI restriction endonucleases in the DNA from human adenovirus (Ad) serotypes 2, 5 and 3 were determined. In addition, the sites of cleavage for BglII in Ad3 DNA were located. All these enzymes possess a narrow specificity and generated a small number of discrete DNA fragments. Ad3 DNA was not cleaved by MluI and SfiI. It was the first observation of the absence of cleavage of an adenovirus DNA by a restriction endonuclease.

Accumulation of early and intermediate mRNA species during subgroup C adenovirus productive infections

The cytoplasmic, poly(A)-containing RNA species complementary to all regions of the adenovirus type 2 (Ad2) genome expressed before the onset of viral DNA synthesis have been examined by "Northern" blotting. HeLa cells infected with low multiplicities of Ad2 were harvested at 2-hr intervals until late in the infectious cycle to establish the temporal patterns of expression of each viral gene. Under these conditions, such late mRNA products as those of the L3 and L5 families were not detected until 14 hr after infection. Although individual mRNA species complementary to several genes showed different patterns of expression, the order of appearance in the cytoplasm of substantial concentrations of adenoviral mRNA species was E1A, E3, and E4 (4 to 6 hr), E2A and E2B (8 hr), 3.7- and 4.1-kb L1 mRNA species (10-12 hr), IX and IVa2 mRNAs (12 hr), and those encoded in the major late transcriptional unit, such as members of the L3 and L5 families (14 hr). The mRNA species encoding polypeptides IX and IVa2 were not produced when viral DNA synthesis was blocked, whereas the larger L1 mRNA species was made under these conditions. Two E2B mRNA species, some 5.0 and 7 kb, were observed at low concentrations at 8 hr after infection and their concentration increased until 24 hr after infection, as did that of the E2A mRNA species: the products of the E2 transcription unit appeared to be expressed coordinately and at a constant ratio throughout infection. Few of the early mRNA species decreased in concentration after the onset of the late phase of infection. Examination of the viral mRNA produced when protein synthesis was inhibited by 10 microM anisomycin added 3 hr after infection suggested that processing of certain viral, early transcripts was altered in the presence of the drug.

Nucleotide sequence of a cloned duck hepatitis B virus genome: comparison with woodchuck and human hepatitis B virus sequences

The nucleotide sequence of an EcoRI duck hepatitis B virus (DHBV) clone was elucidated by using the Maxam and Gilbert method. This sequence, which is 3,021 nucleotides long, was compared with the two previously analyzed hepatitis B-like viruses (human and woodchuck). From this comparison, it was shown that DHBV is derived from an ancestor common to the two others but has a slightly different genomic organization. There was no intergenic region between genes 5 and 8, which were fused into a single open reading frame in DHBV. Genes for the surface and core proteins were assigned to open reading frames 7 and 5/8. Amino acid comparisons showed some structural relationship between gene 6 product and avian reverse transcriptase, suggesting either evolution from a common ancestor or convergence to some particular structure to fulfill a specific function. This should be correlated with the synthesis of an RNA intermediate during DNA replication. This is also taken as an argument in favor of the hypothesis that gene 6 codes for the DNA polymerase that is found within the virion. DNA sequence comparison also showed that the two mammalian hepatitis B viruses are more homologous to each other than they are to DHBV, indicating that DHBV starts to evolve on its own earlier than the two other viruses, as do birds compared with mammals. From this it is proposed that the viruses evolved in a fashion parallel to the species they infect.

The nucleotide sequence of fragment HindIII-C of human adenovirus type 5 DNA (map positions 17.1-31.7)

This paper describes the sequence of nucleotides 6246-11570 between the two HindIII sites at map positions (m.p.) 17.1 and 31.7 of human adenovirus serotype 5 (Ad5) DNA. It is 99% homologous with the corresponding HindIII-B fragment of adenovirus type 2 (Ad2; Gingeras et al., 1982; Aleström et al., 1982) which has been shown to encode the second, "i", and third leaders of the major late RNAs, the virus-associated RNAs VAI and VAII (all rightward transcripts), and in the opposite sense the early-region E2b mRNAs for a DNA polymerase and for the terminal protein precursor (pTP). Except for the latter, it was possible to determine the coordinates of the corresponding Ad5 RNAs, either by sequence homology with Ad2, or by nuclease S1 analysis. The Ad5 DNA sequence contains the same open reading frames as that of Ad2. The longest of these lie in the r-strand and would specify proteins of Mr 120377 (DNA polymerase) and 74558 (pTP).

Proteins encoded near the adenovirus late messenger RNA leader segments

Small fragments of adenovirus 2 DNA cloned into the single-strand phage M13 were used to select adenoviral messenger RNAs transcribed from the R-strand between map positions 16 and 30. Cell-free translation of these mRNAs produced proteins of 13.5K, 13.6K, and 11.5K, respectively encoded between the first and second segments of the tripartite major late leader, within the "i"-leader segment, and immediately preceding the third leader segment. Partial sequence analysis of the 13.6K protein is consistent with the hypothesis that it is encoded within the i-leader segment.

Temperature-sensitive initiation and elongation of adenovirus DNA replication in vitro with nuclear extracts from H5ts36-, H5ts149-, and H5ts125-infected HeLa cells

Adenovirus DNA replication was studied in vitro in nuclear extracts prepared from HeLa cells infected at the permissive temperature with H5ts125, H5ts36, or H5ts149, three DNA-negative mutants belonging to two different complementation groups. At the restrictive temperature, H5ts125 extracts, containing a thermolabile 72-kilodalton DNA-binding protein, enable the formation of an initiation complex between the 82-kilodalton terminal protein precursor (pTP) and dCTP, but further elongation of this complex is inhibited. Wild-type DNA-binding protein or a 47-kilodalton chymotryptic DNA-binding fragment can complement the mutant protein in the elongation reaction. No difference in heat inactivation was observed between wild-type extracts and H5ts36 or H5ts149 extracts when the replication of terminal XbaI fragments of adenovirus type 5 DNA-terminal protein complex was studied. In contrast, the formation of a pTP-dCMP initiation complex, as well as the partial elongation reaction up to nucleotide 26, were consistently more temperature sensitive in mutant extracts. The results suggest that the H5ts36/H5ts149 gene product is required for initiation of adenovirus type 5 DNA replication and that the 72-kilodalton DNA-binding protein functions early in elongation.

The genetic analysis of adenovirus recombination in triparental and superinfection crosses

Previous genetic and molecular data suggest that adenovirus genomes can undergo several rounds of recombination before being encapsidated (C. S. H. Young and S. J. Silverstein, Virology 101, 503-515). Two predictions of this hypothesis have been tested. The first is that infection with three differentially marked parental viruses should lead to the appearance of recombinants with genetic contributions from all three parents. In a triparental cross, involving two strains with different ts mutations in chimeric Ad5/Ad2+ND1 backgrounds, and a third strain containing both ts mutations in an Ad5 background, it was demonstrated that multiple recombinations, involving distinguishable restriction endonuclease sites and host range markers from all three parents, were common. The second prediction, from previous kinetic data, is that cells are recombinationally proficient from the eclipse period well into the exponential rise period. This has been tested by superinfecting singly infected cultures, both during eclipse and in early exponential phase. Recombinant viruses were produced in these superinfections, demonstrating that the early to late switch in the replicative cycle does not inhibit recombination. From the temporal appearance of recombinants moreover, it seems likely that recombination functions, and the DNA structures necessary to initiate recombination, are present well into the late phase of replication.

Purification of an adenovirus-coded DNA polymerase that is required for initiation of DNA replication

Temperature-sensitive mutants in the N complementation group of human adenovirus type 5 are defective at the nonpermissive temperature for replication of virus DNA and for transformation of rat embryo cells. We show that nuclear extracts prepared from Ad5ts 149-infected cells grown at the nonpermissive temperature fail to replicate DNA in vitro. The defect lies in the first step in the initiation of viral DNA synthesis, the formation of a covalent linkage between the terminal protein precursor (pTP) and dCMP. A 140 kilodalton (140 kd) protein which complements these defective extracts and contains DNA polymerase activity has been purified from HeLa cells infected with wild-type Ad2. It is tightly associated with the 80 kd pTP in a replication complex. Both of these proteins are products of the E2B region of the adenovirus genome, and the 140 kd protein coding sequences lie immediately downstream from those encoding the 80 kd protein. These results demonstrate that adenovirus encodes a novel DNA polymerase that is required for priming of DNA synthesis at the origin of replication. This protein may also function in the initiation of transformation of cultured cells.