Adenovirus terminal protein precursor. Partial amino acid sequence and the site of covalent linkage to virus DNA

Natural history of eukaryotic DNA viruses with double jelly-roll major capsid proteins

The phylum Preplasmiviricota (kingdom Bamfordvirae, realm Varidnaviria) is a broad assemblage of diverse viruses with comparatively short double-stranded DNA genomes (<50 kbp) that produce icosahedral capsids built from double jelly-roll major capsid proteins. Preplasmiviricots infect hosts from all cellular domains, testifying to their ancient origin, and, in particular, are associated with six of the seven supergroups of eukaryotes. Preplasmiviricots comprise four major groups of viruses, namely, polintons, polinton-like viruses (PLVs), virophages, and adenovirids. We used protein structure modeling and analysis to show that protein-primed DNA polymerases (pPolBs) of polintons, virophages, and cytoplasmic linear plasmids encompass an N-terminal domain homologous to the terminal proteins (TPs) of prokaryotic PRD1-like tectivirids and eukaryotic adenovirids that are involved in protein-primed replication initiation, followed by a viral ovarian tumor-like cysteine deubiquitinylase (vOTU) domain. The vOTU domain is likely responsible for the cleavage of the TP from the large pPolB polypeptide and is inactivated in adenovirids, in which TP is a separate protein. Many PLVs and transpovirons encode a distinct derivative of polinton-like pPolB that retains the TP, vOTU, and pPolB polymerization palm domains but lacks the exonuclease domain and instead contains a superfamily 1 helicase domain. Analysis of the presence/absence and inactivation of the vOTU domains and replacement of pPolB with other DNA polymerases in eukaryotic preplasmiviricots enabled us to outline a complete scenario for their origin and evolution.

Natural history of eukaryotic DNA viruses with double jelly-roll major capsid proteins

The phylum Preplasmiviricota (kingdom Bamfordvirae, realm Varidnaviria) is a broad assemblage of diverse viruses with comparatively short double-stranded DNA genomes (<50 kbp) that produce icosahedral capsids built from double jelly-roll major capsid proteins. Preplasmiviricots infect hosts from all cellular domains, testifying to their ancient origin and, in particular, are associated with six of the seven supergroups of eukaryotes. Preplasmiviricots comprise four major groups of viruses, namely, polintons, polinton-like viruses (PLVs), virophages, and adenovirids. We employed protein structure modeling and analysis to show that protein-primed DNA polymerases (pPolBs) of polintons, virophages, and cytoplasmic linear plasmids encompass an N-terminal domain homologous to the terminal proteins (TPs) of prokaryotic PRD1-like tectivirids and eukaryotic adenovirids that are involved in protein-primed replication initiation, followed by a viral ovarian tumor-like cysteine deubiquitinylase (vOTU) domain. The vOTU domain is likely responsible for the cleavage of the TP from the large pPolB polypeptide and is inactivated in adenovirids, in which TP is a separate protein. Many PLVs and transpovirons encode a distinct derivative of polinton-like pPolB that retains the TP, vOTU and pPolB polymerization palm domains but lacks the exonuclease domain and instead contains a supefamily 1 helicase domain. Analysis of the presence/absence and inactivation of the vOTU domains, and replacement of pPolB with other DNA polymerases in eukaryotic preplasmiviricots enabled us to outline a complete scenario for their origin and evolution.

Cancer immunotherapies: A hope for the uncurable?

The use of cancer immunotherapies is not novel but has been used over the decades in the clinic. Only recently have we found the true potential of stimulating an anti-tumor response after the breakthrough of checkpoint inhibitors. Cancer immunotherapies have become the first line treatment for many malignancies at various stages. Nevertheless, the clinical results in terms of overall survival and progression free survival were not as anticipated. Majority of cancer patients do not respond to immunotherapies and the reasons differ. Hence, further improvements for cancer immunotherapies are crucially needed. In the review, we will discuss various forms of cancer immunotherapies that are being tested or already in the clinic. Moreover, we also highlight future directions to improve such therapies.

Lessons learned from adenovirus (1970-2019)

Animal viruses are well recognized for their ability to uncover fundamental cell and molecular processes, and adenovirus certainly provides a prime example. This review illustrates the lessons learned from studying adenovirus over the past five decades. We take a look back at the key studies of adenovirus structure and biophysical properties, which revealed the mechanisms of adenovirus association with antibody, cell receptor, and immune molecules that regulate infection. In addition, we discuss the critical contribution of studies of adenovirus gene expression to elucidation of fundamental reactions in pre-mRNA processing and its regulation. Other pioneering studies furnished the first examples of protein-primed initiation of DNA synthesis and viral small RNAs. As a nonenveloped virus, adenoviruses have furnished insights into the modes of virus attachment, entry, and penetration of host cells, and we discuss the diversity of cell receptors that support these processes, as well as membrane penetration. As a result of these extensive studies, adenovirus vectors were among the first to be developed for therapeutic applications. We highlight some of the early (unsuccessful) trials and the lessons learned from them.

Viral and cellular interactions during adenovirus DNA replication

Adenoviruses represent ubiquitous and clinically significant human pathogens, gene-delivery vectors, and oncolytic agents. The study of adenovirus-infected cells has long been used as an excellent model to investigate fundamental aspects of both DNA virus infection and cellular biology. While many key details supporting a well-established model of adenovirus replication have been elucidated over a period spanning several decades, more recent findings suggest that we have only started to appreciate the complex interplay between viral genome replication and cellular processes. Here, we present a concise overview of adenovirus DNA replication, including the biochemical process of replication, the spatial organization of replication within the host cell nucleus, and insights into the complex plethora of virus-host interactions that influence viral genome replication. Finally, we identify emerging areas of research relating to the replication of adenovirus genomes.

An alternative to the adenovirus inverted terminal repeat sequence increases the viral genome replication rate and provides a selective advantage in vitro

During the development of human adenovirus 35-derived replication-incompetent (rAd35) vaccine vectors for prevention of infectious diseases, we detected mutations in the terminal 8 nt of the inverted terminal repeats (ITRs) of rAd35. The switch from the plasmid-encoded sequence 5'-CATCATCA-3' to the alternative sequence 5'-CTATCTAT-3' in the ITRs was found to be a general in vitro propagation phenomenon, as shown for several vectors carrying different transgenes or being derived from different adenovirus serotypes. In each tested case, the plasmid-encoded ITR sequence changed to exactly the same alternative ITR sequence, 5'-CTATCTAT-3'. The outgrowth of this alternative ITR version should result from a growth advantage conferred by the alternative ITR sequence. Indeed, replication kinetics studies of rAd35 harbouring either the original or alternative ITR sequence confirmed an increase in replication speed for rAd35 vectors with the alternative ITR sequence. These findings can be applied to generate recombinant adenoviral vectors harbouring the alternative ITR sequence, which will facilitate the generation of genetically homogeneous seed virus batches. Moreover, vector production may be accelerated by taking advantage of the observed improved replication kinetics associated with the alternative ITR sequence.

Mutational analysis of the terminal protein Tpg of Streptomyces chromosomes: identification of the deoxynucleotidylation site

The linear chromosomes and linear plasmids of Streptomyces are capped by terminal proteins (TPs) covalently bound to the 5' ends of the DNA. The TPs serve as primers for DNA synthesis that patches in the single-stranded gaps at the telomeres resulting from the bi-directional replication ('end patching'). Typical Streptomyces TPs, designated Tpgs, are conserved in sequence and size (about 185 amino acids), and contain a predicted helix-turn-helix domain and a functional nuclear localization signal. The Tpg-encoding gene (tpg) is often accompanied by an upstream gene tap that encodes an essential telomere-associating protein. Five lone tpg variants (not accompanied by tap) from various Streptomyces species were tested, and three were found to be pseudogenes. The lone tpg variant on the SLP2 plasmid, although functional, still requires the presence of tap on the chromosome for end patching. Using a combination of in vitro deoxynucleotidylation, physical localization, and genetic analysis, we identified the threonine at position 114 (T114) in Tpg of Streptomyces lividans chromosome as the deoxynucleotidylated site. Interestingly, T114 could be substituted by a serine without destroying the priming activity of Tpg in vitro and in vivo. Such T114S substitution is seen in and a number of pseudogenes as well as functional Tpgs. T114 lies in a predicted coil flanked by two short helixes in a highly hydrophilic region. The location and structural arrangement of the deoxynucleotidylated site in Tpg is similar to those in the TPs of phage ø 29 and adenoviruses. However, these TPs are distinct in their sequences and sizes, indicating that they have evolved independently during evolution. Using naturally occurring and artificially created tpg variants, we further identified several amino acid residues in the N-terminus and the helix-turn-helix domain that were important for functionality.

Reduced infectivity of adenovirus type 5 particles and degradation of entering viral genomes associated with incomplete processing of the preterminal protein

To investigate further the contribution of the adenovirus type 5 (Ad5) E1B 55-kDa protein to genome replication, viral DNA accumulation was examined in primary human fibroblasts and epithelial cells infected with Ad5 or the E1B 55-kDa-null mutant Hr6. Unexpectedly, all cell types were observed to contain a significantly higher concentration of entering Hr6 than of Ad5 DNA, as did an infectious unit of Hr6. However, the great majority of the Hr6 genomes were degraded soon after entry. As this unusual phenotype cannot be ascribed to the Hr6 E1B frameshift mutation (J. S. Chahal and S. J. Flint, J. Virol. 86:3064-3072, 2012), the sequences of the Ad5 and Hr6 genomes were compared by using high-throughput sequencing. Seven previously unrecognized mutations were identified in the Hr6 genome, two of which result in substitutions in virion proteins, G315V in the preterminal protein (preTP) and A406V in fiber protein IV. Previous observations and the visualization by immunofluorescence of greater numbers of viral genomes entering the cytosol of Hr6-infected cells than of Ad5-infected cells indicated that the fiber mutation could not be responsible for the low-infectivity phenotype of Hr6. However, comparison of the forms of terminal protein present in purified virus particles indicated that the production of mature terminal protein from a processing intermediate is impaired in Hr6 particles. We therefore propose that complete processing of preTP within virus particles is necessary for the ability of viral genomes to become localized at appropriate sites and persist in infected cells.

Adenovirus: a blueprint for non-viral gene delivery

Although adenoviral vectors may not find a direct clinical role in gene therapy, an understanding of the mechanisms of DNA delivery that adenoviruses use is of vital importance to the design of next-generation non-viral gene delivery systems. Adenoviruses overcome a series of biological barriers, including endosomal escape, intracellular trafficking, capsid dissociation, and nuclear import of DNA, to deliver their genome to the host cell nucleus. The understanding of these processes at the molecular level is progressing and is set to inform the design of synthetic gene delivery systems.

In vitro deoxynucleotidylation of the terminal protein of Streptomyces linear chromosomes

Single-stranded gaps at the 3' ends of Streptomyces linear replicons are patched by DNA synthesis primed by terminal proteins (TP) during replication. We devised an in vitro system that specifically incorporated dCMP, the first nucleotide at the 5' ends, onto a threonine residue of the TP of Streptomyces coelicolor.

Relaxed template specificity in fowl adenovirus 1 DNA replication initiation

The fowl adenovirus 1 (FAdV-1) isolates PHELPS and OTE are highly similar, but have striking differences in the repeat region of the inverted terminal repeat (ITR). Whilst the repeat region in OTE conforms to the conventional human adenovirus repeat region (5'-CATCATC), that of PHELPS contains guanidine residues at positions 1, 4 and 7 (5'-GATGATG). This implies that the FAdV-1 isolates PHELPS and OTE have either distinct template specificity at replication initiation or, alternatively, a relaxed specificity for replication initiation. In this study, the distinct sequence variation at the origin of DNA replication in the ITRs of the FAdV-1 PHELPS and OTE isolates was confirmed. Sequence analyses of the pTP and Pol genes of both PHELPS and OTE did not reveal differences that could explain the distinct template specificity. Replication assays demonstrated that linear DNA fragments flanked by either 5'-CATCATC or 5'-GATGATG termini replicated in cells upon infection with FAdV-1 OTE and FAdV-1 PHELPS. This was evident from the appearance of DpnI-resistant fragments in a minireplicon assay. From these data, it is concluded that FAdV-1 has relaxed, rather than changed, its template specificity at replication initiation.

Characterization of the complete genome of the Tupaia (tree shrew) adenovirus

The members of the family Adenoviridae are widely spread among vertebrate host species and normally cause acute but innocuous infections. Special attention is focused on adenoviruses because of their ability to transform host cells, their possible application in vector technology, and their phylogeny. The primary structure of the genome of Tupaia adenovirus (TAV), which infects Tupaia spp. (tree shrew) was determined. Tree shrews are taxonomically assumed to be at the base of the phylogenetic tree of mammals and are frequently used as laboratory animals in neurological and behavior research. The TAV genome is 33,501 bp in length with a G+C content of 49.96% and has 166-bp inverted terminal repeats. Analysis of the complete nucleotide sequence resulted in the identification of 109 open reading frames (ORFs) with a coding capacity of at least 40 amino acid residues. Thirty-eight of them are predicted to encode viral proteins based on the presence of transcription and translation signals and sequence and positional conservation. Thirty viral ORFs were found to show significant similarities to known adenoviral genes, arranged into discrete early and late genome regions as they are known from mastadenoviruses. Analysis of the nucleotide content of the TAV genome revealed a significant CG dinucleotide depletion at the genome ends that suggests methylation of these genomic regions during the viral life cycle. Phylogenetic analysis of the viral gene products, including penton and hexon proteins, viral protease, terminal protein, protein VIII, DNA polymerase, protein IVa2, and 100,000-molecular-weight protein, revealed that the evolutionary lineage of TAV forms a separate branch within the phylogenetic tree of the Mastadenovirus genus.

Molecular architecture of adenovirus DNA polymerase and location of the protein primer

Adenovirus (Ad) DNA polymerase (pol) belongs to the distinct subclass of the polalpha family of DNA pols that employs the precursor terminal protein (pTP) as primer. Ad pol forms a stable heterodimer with this primer, and together, they bind specifically to the core origin in order to start replication. After initiation of Ad replication, the resulting pTP-trinucleotide intermediate jumps back and pTP starts to dissociate. Compared to free Ad pol, the pTP-pol complex shows reduced polymerase and exonuclease activities, but the reason for this is not understood. Furthermore, the interaction domains between these proteins have not been defined and the contribution of each protein to origin binding is unclear. To address these questions, we used oligonucleotides with a translocation block and show here that pTP binds at the entrance of the primer binding groove of Ad pol, thereby explaining the decreased synthetic activities of the pTP-pol complex and providing insight into how pTP primes Ad replication. Employing an exonuclease-deficient mutant polymerase, we further show that the polymerase and exonuclease active sites of Ad pol are spatially distinct and that the exonuclease activity of Ad pol is located at the N-terminal part of the protein. In addition, by probing the distances between both active sites and the surface of Ad pol, we show that Ad pol binds a DNA region of 14 to 15 nucleotides. Based on these results, a model for binding of the pTP-pol complex at the origin of replication is proposed.

The complete nucleotide sequence of porcine adenovirus serotype 5

The complete nucleotide sequence of porcine adenovirus serotype 5 (PAdV-5) has been determined and the putative genomic map was constructed. The size of the genome was found to be 32621 nucleotides. Twenty-eight putative ORFs were identified by their homology to other adenovirus or other virus and eukaryotic genes. Several special protein sequence motifs were identified by their homology to similar protein motifs. The putative promoter regions, polyadenylation and splice sites were predicted and the early and late transcription units were determined. Based on sequence analysis and RNA secondary structure prediction, sequences for virus-associated RNA could not be recognized. Phylogenetic analysis showed that PAdV-5 was more closely related to certain bovine adenoviruses than to other porcine adenoviruses.

Nucleotide sequence and transcription map of porcine adenovirus type 3

The complete nucleotide sequence of porcine adenovirus type 3 was determined and a transcriptional map for the genome was constructed. The size of the genome is 34094 bp in length with an unusually high G + C content (63.7%), the highest thus far reported for any adenovirus. Overall organization of the genome is similar to that for previously sequenced adenoviral DNAs, but there also were distinct differences. The late regions genes are organized into six families, instead of five as they are in human adenovirus type 2. In contrast to bovine adenovirus type 3 and ovine adenovirus, which lack virion-associated RNA genes, the nucleotide sequence analysis of the viral genome indicates that it encodes one short VA RNA species. With the exception of the fiber and a 33-kDa nonstructural protein, the predicted amino acid sequences of the open reading frames in the late regions and the E2 region and IVa2 exhibited a high level of homology, whereas the deduced amino acid sequences of ORFs in E1, E3, and E4 regions, and the pIX showed a lesser homology with the corresponding proteins of other adenoviruses. The proteins V, VII, and IX are unusually long, and the protein VII lacks the consensus protease cleavage site. Genomic and cDNA sequence analysis has identified promoters, cap sites, intron-exon boundaries, polyadenylation signals, and polyadenylation sites in the viral genome.

The complete DNA sequence and genome organization of the avian adenovirus, hemorrhagic enteritis virus

Hemorrhagic enteritis virus (HEV) belongs to the Adenoviridae family, a subgroup of adenoviruses (Ads) that infect avian species. In this article, the complete DNA sequence and the genome organization of the virus are described. The full-length of the genome was found to be 26,263 bp, shorter than the DNA of any other Ad described so far. The G + C content of the genome is 34.93%. There are short terminal repeats (39 bp), as described for other Ads. Genes were identified by comparison of the DNA and predicted amino acid sequences with published sequences of other Ads. The organization of the genome in respect to late genes (52K, IIIa, penton base, core protein, hexon, endopeptidase, 100K, pVIII, and fiber), early region 2 genes (polymerase, terminal protein, and DNA binding protein), and intermediate gene IVa2 was found to be similar to that of other human and avian Ad genomes. No sequences similar to E1 and E4 regions were found. Very low similarity to ovine E3 region was found. Open reading frames were identified with no similarity to any published Ad sequence.

Completion of the DNA sequence of mouse adenovirus type 1: sequence of E2B, L1, and L2 (18-51 map units)

The DNA sequence of 9991 nt, corresponding to 18-51 map units of mouse adenovirus type 1 (MAV-1), was determined, completing the sequence of the Larsen strain of MAV-1. The length of the complete MAV-1 genome is 30,946 nucleotides, consistent with previous experimental estimates. The 18-51 map unit region encodes early region 2B proteins necessary for adenoviral replication as well as late region L1 and L2 structural and packaging proteins. Sequence comparison in this region with human adenoviruses indicates broad similarities, including colinear preservation of all recognized open reading frames (ORFs), with highest amino acid identity occurring in the DNA polymerase and polypeptide III (penton base subunit) ORFs. Virus-associated (VA) RNA is not encoded in the region where VA RNAs are found in the human adenoviruses, between E2B and L1, nor is it encoded anywhere in the entire MAV-1 genome. The MAV-1 polypeptide III lacks the arginine-glycine-aspartic acid (RGD) motif which is involved in an association with cell-surface integrins. Only one RGD sequence is found in an identified coding region in the entire MAV-1 genome. Similar to the porcine adenovirus, this RGD sequence is found in the C-terminus of the MAV-1 fiber protein.

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.

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.

Adenovirus DNA replication: the function of the covalently bound terminal protein

Initiation of Adenovirus DNA replication in vitro requires the presence of three viral proteins (pTP, pol, DBP) and two cellular transcription factors, NFI and Oct-1, that stimulate replication more than 100-fold. NFI assists in binding and positioning of the DNA polymerase in the origin whereas Oct-1 changes the structure of origin DNA. Optimal templates contain, in addition to origin sequences, the covalently bound viral terminal protein (TP). This terminal protein stimulates the template activity over 20 fold compared to protein-free templates. To study the way in which TP exerts its function in vitro we devised a novel method to isolate and label a short origin containing fragment in which the TP was bound in a functional form. This fragment replicated very efficiently and could be used for studying the binding of other replication proteins. Employing alpha-chymotrypsin digestion we show that for enhancement of replication in vitro only a small part of TP is required.

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.

Nucleotide sequence and regulation of the adenovirus type 3 E2A early promoter

The nucleotide sequence of the adenovirus serotype 3 E2A early promoter has been determined. In contrast to Ad2, the Ad3 E2A early promoter possessed only one TATA-like box and one nuclear transcription factor E2F binding site and lacked the silencer sequences; however, as in Ad2, the ATF binding site was present. Moreover, the Ad3 E2A promoter harbored a protein binding sequence recognized by the SP1 factor. By transient expression analysis in HeLa cells, we demonstrated that the E1A gene products of Ad3 and Ad2 stimulated Ad3 E2A transcription. In competition experiments, the Ad3 E2A promoter was used in preference to the Ad2 E2A promoter.

Adenovirus terminal protein mediates both nuclear matrix association and efficient transcription of adenovirus DNA

Adenovirus DNA is tightly bound to the nuclear matrix throughout the course of infection. Analysis of adenovirus DNA from infected HeLa cell nuclei after extraction with lithium diiodosalicylate and digestion with restriction enzymes demonstrated that the sites of tightest attachment occur in the terminal fragments of the linear viral chromosome. Analysis of viruses mutated in the precursor terminal protein coding sequence demonstrated that the terminal protein, which is covalently attached to the 5' end of each DNA strand, mediates the tight binding. Virions containing chromosomes with mutant terminal proteins were unpackaged and viral DNA accumulated in the nucleus at a normal rate and competed for the limiting component during transcription complex formation, but their early genes were transcribed at reduced efficiency by both RNA polymerases II and III. The transcriptional defects were not complemented by coinfection with a wild-type virus. We propose that the adenovirus chromosome may exist as a single chromatin domain during infection and that binding of DNA to the nuclear matrix may play a critical role in adenovirus transcription.

Adenovirus proteins and MHC expression

Adenoviruses are able to specifically down-regulate the cell surface expression of MHC class I antigens. Most viral serotypes achieve these ends by synthesizing a protein that binds to class I antigens in the endoplasmic reticulum (ER) and impedes the transport of these molecules to the cell surface. However, viruses belonging to the highly oncogenic subgenus A do not affect the class I antigen expression during acute infection. Instead, they are distinct from other adenoviruses in that they specifically down-regulate the level of mRNAs, encoding MHC class I antigens, in virally transformed cells. The virus-induced reduction of class I antigen expression drastically diminishes the ability of CTLs to recognize cells infected or transformed by adenovirus. A number of issues concerning these viral mechanisms for class I antigen modulation need to be addressed. The molecular mechanism by which the E1A gene product of subgenus A viruses diminishes class I mRNA levels has not been elucidated. Also, the details of the interaction between the E19 protein and class I molecules should be studied, preferably by X-ray crystallography of the complexes. This would clarify the role of the antigen-binding site as well as other portions of the class I molecule in the binding to the E19 protein. Of general importance for our understanding of the sorting and intracellular transport of proteins is the exact delimitation of the signal for ER localization, which is present in the COOH-terminus of the E19 protein. The putative interaction of this peptide sequence with components of the ER membrane should also be studied. Finally, the study of the pathophysiological role of the MHC class I down-regulation will undoubtedly yield new insights into how the immune system combats virally infected and transformed cells.

Nuclear transport of adenovirus DNA polymerase is facilitated by interaction with preterminal protein

The mRNAs for the 80 kd adenovirus preterminal protein (pTP) and the 140 kd DNA polymerase (AdPol) contain several exons spliced to the main open reading frames (m-ORFs) located in the early transcription unit E2B. These proteins were transiently expressed in monkey kidney cells (CV1) utilizing the first ATG (pTP1 and AdPol1) or the ATG of a linker inserted at the beginning of the m-ORFs (pTP2 and AdPol2). Only pTP2 and AdPol2 were functionally active in an in vitro replication initiation assay. Both pTP1 and pTP2 were transported to the nucleus. The sequence RLPV(R)6VP, which is present in both pTPs, is identified as their nuclear localization signal. In contrast, AdPol1 was cytoplasmically localized, whereas AdPol2 was distributed in both compartments, suggesting that the nuclear localization signal for AdPol is within the first 139 amino acids. Interestingly, when AdPol1 and pTP1 or AdPol2 and pTP2 were coexpressed in the transfected cells, the nuclear distribution of AdPol1 or AdPol2 was significantly increased. We demonstrate that the nuclear transport of AdPol is facilitated, irrespective of the presence of its nuclear localization signal, by interaction with pTP.

The precise structure and coding capacity of mRNAs from early region 2B of human adenovirus serotype 2

Replication of human adenovirus (Ad) DNA requires three virus-encoded proteins that are coordinately transcribed from a single promoter at early times after infection. The mRNAs for two of these proteins, the precursor to the terminal protein (pTP) and the Ad DNA polymerase (Ad Pol), share several exons, including one encoded near Ad genome coordinate 39. The positions of the splice points of these mRNAs have been mapped by S1 nuclease mapping, by RNA sequencing, and by cDNA cloning. As a result of RNA splicing events, a short open reading frame (ORF) encoded at genome coordinate 39 is connected to the beginning of both the pTP and Ad Pol coding sequences; inclusion of this upstream ORF is essential for expression of functional pTP and Ad Pol proteins.

Characterization of a low-molecular-weight virus-associated (VA) RNA encoded by simian adenovirus type 7 which functionally can substitute for adenovirus type 5 VA RNAI

Human adenoviruses (Ads), like Ad type 2 (Ad2) and Ad5, encode a low-molecular-weight RNA (designated virus-associated [VA] RNAI) which is required for the efficient translation of viral mRNAs late after infection. We cloned and characterized a VA RNA gene from simian adenovirus type 7 (SA7) which appears to have biological activity analogous to that of Ad2 VA RNAI. Thus, SA7 VA RNA stimulates protein synthesis in a transient expression assay and can also functionally substitute for VA RNAI during lytic growth of human Ad5. The SA7 genome encodes only one VA RNA species, in contrast to human Ad2, which encodes two distinct species. This RNA is transcribed by RNA polymerase III in the rightward direction from a gene located at about coordinate 30 on the viral genome, like its Ad2 counterparts. SA7 VA RNA shows only a limited primary sequence homology with the Ad2 VA RNAs (approximately 55%); the flanking sequences, in fact, are better conserved than the VA RNA gene itself. The predicted secondary structure of SA7 VA RNA is, however, very similar to that of Ad2 VA RNAI, inferring that the double-stranded nature rather than the primary sequence of VA RNA is important for its biological activity.

Antibodies specific for the phi 29 terminal protein inhibit the initiation of DNA replication in vitro

The phi 29 DNA-terminal protein serves as a primer for the initiation of DNA replication by covalently binding the first nucleotide in the DNA chain. Two distinct antibodies were used for functional analysis of this protein. One antibody was raised against sonicated phi 29 DNA-protein complex isolated from phage virions (anti-TP). The other antibody was raised against a conjugate of bovine serum albumin and a synthetic peptide corresponding to the carboxy-terminal of the phi 29 terminal protein (anti-gp3C), which was predicted from the nucleotide sequence of phi 29 DNA. Both antibodies react with native phi 29 terminal protein as determined by immunoprecipitation and enzyme-linked immunosorbent assay. Both antibodies specifically inhibit the complex-forming reaction between the phi 29 terminal protein and dAMP, the first nucleotide of phi 29 DNA.

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).

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.