Adenoviruses with nonidentical terminal sequences are viable

Interregional Coevolution Analysis Revealing Functional and Structural Interrelatedness between Different Genomic Regions in Human Mastadenovirus D

Human mastadenovirus D (HAdV-D) is exceptionally rich in type among the seven human adenovirus species. This feature is attributed to frequent intertypic recombination events that have reshuffled orthologous genomic regions between different HAdV-D types. However, this trend appears to be paradoxical, as it has been demonstrated that the replacement of some of the interacting proteins for a specific function with other orthologues causes malfunction, indicating that intertypic recombination events may be deleterious. In order to understand why the paradoxical trend has been possible in HAdV-D evolution, we conducted an interregional coevolution analysis between different genomic regions of 45 different HAdV-D types and found that ca. 70% of the genome has coevolved, even though these are fragmented into several pieces via short intertypic recombination hot spot regions. Since it is statistically and biologically unlikely that all of the coevolving fragments have synchronously recombined between different genomes, it is probable that these regions have stayed in their original genomes during evolution as a platform for frequent intertypic recombination events in limited regions. It is also unlikely that the same genomic regions have remained almost untouched during frequent recombination events, independently, in all different types, by chance. In addition, the coevolving regions contain the coding regions of physically interacting proteins for important functions. Therefore, the coevolution of these regions should be attributed at least in part to natural selection due to common biological constraints operating on all types, including protein-protein interactions for essential functions. Our results predict additional unknown protein interactions.

IMPORTANCE

Human mastadenovirus D, an exceptionally type-rich human adenovirus species and causative agent of different diseases in a wide variety of tissues, including that of ocular region and digestive tract, as well as an opportunistic infection in immunocompromised patients, is known to have highly diverged through frequent intertypic recombination events; however, it has also been demonstrated that the replacement of a component protein of a multiprotein system with a homologous protein causes malfunction. The present study solved this apparent paradox by looking at which genomic parts have coevolved using a newly developed method. The results revealed that intertypic recombination events have occurred in limited genomic regions and been avoided in the genomic regions encoding proteins that physically interact for a given function. This approach detects purifying selection against recombination events causing the replacement of partial components of multiprotein systems and therefore predicts physical and functional interactions between different proteins and/or genomic elements.

A 40 kDa isoform of the type 5 adenovirus IVa2 protein is sufficient for virus viability

The multifunctional IVa2 protein is essential for adenovirus replication [J. Virol. 77 (2003) 3586], but the relative importance of the transcriptional and encapsidation functions is unknown. As part of a study of IVa2 function, we created a set of mutations in the IVa2 gene in the correct location in the viral genome. Unexpectedly, an opal stop codon at position 6 was recovered in virus twice. Isolate #2 showed defective viral replication, but produced late proteins at almost wild-type levels. Analysis of IVa2 mRNA showed an additional species, larger and more abundant than the equivalent wild-type species. It was a hybrid of the 5' UTR of L3 23 kDa attached to the IVa2 second exon, so that M75 is the 5' proximal methionine. This mRNA arises from a corresponding hybrid DNA, present in the virus stock. A protein of approximately 40 kDa, consistent with translation from the hybrid mRNA, was detected. It is able to bind to the packaging sequence and to the MLP downstream elements (DE1/2). Isolate #8 was more defective in replication than #2. No hybrid mRNA or DNA was detected, but it also produces a 40 kDa isoform, which is present in wild-type-infected cells. Mutational analysis of M75 and M101 revealed that the 40 kDa isoform is produced by initiation at Met75. This might be the origin of the previously unidentified 40 kDa factor present in the heterodimer DEF-A, which binds to DE1 and DE2a.

The novel early region 3 protein E3/49K is specifically expressed by adenoviruses of subgenus D: implications for epidemic keratoconjunctivitis and adenovirus evolution

The early transcription unit 3 (E3) of adenoviruses (Ads) encodes immunomodulatory functions. We previously described a novel gene of 49K within the E3 region of Ad19a, an Ad of subgenus D that is similar to Ad8 and Ad37 causes epidemic keratoconjunctivitis (EKC). Interestingly, 49K was reported not to be present in Ad9 and Ad17, other subgenus D Ads not causing EKC. Therefore, we investigated whether 49K is selectively expressed in EKC-causing Ads. Using specific DNA probes, we detect 49K-homologous genes in all subgenus D Ads tested. Moreover, 49K-specific antibodies recognize a high molecular weight protein in cells infected with all subgenus D serotypes irrespective of their ability to cause EKC. Sequencing of several 49K genes reveals a high homology without a distinct feature recognizable for those of EKC-associated Ad strains. Thus, E3/49K is a subgenus D specific E3 protein whose expression does not correlate with the EKC-causing phenotype and thus may rather be implicated in illnesses commonly caused by this subgenus. Interestingly, the 49K sequences of Ad19a and Ad37 are identical. To estimate the extent of the sequence identity between these two viruses, we initially sequenced the right ITR and the hexon. This analysis revealed that the right ITR of Ad19a is identical to Ad37, while the hexon sequence is Ad19p-like. This suggested that the region of identity is much larger and that Ad19a arose by recombination of Ad37 with an Ad19p-like Ad. Further sequencing mapped the crossover within the DNA binding protein. Thus, Ad19a contains a large sequence block ( approximately 13 kb), from the 100K gene to the right ITR, identical to Ad37. The implications of these findings in light of the temporal appearance of the EKC-causing Ad strains are discussed.

A novel system for the production of fully deleted adenovirus vectors that does not require helper adenovirus

Fully deleted adenovirus vectors (FD-AdVs) would appear to be promising tools for gene therapy. Since these vectors are deleted of all adenoviral genes, they require a helper adenovirus for their propagation. The contamination of the vector preparation by the helper limits the utility of currently existing FD-AdVs in gene therapy applications. We have developed an alternative system for the propagation of FD-AdVs, in which the adenoviral genes essential for replication and packaging of the vector are delivered into producer cells by a baculovirus-adenovirus hybrid. A hybrid baculovirus Bac-B4 was constructed to carry a Cre recombinase-excisable copy of the packaging-deficient adenovirus genome. Although the total size of the DNA insert in Bac-B4 was 38 kb, the genetic structure of this recombinant baculovirus was stable. Bac-B4 gave high yields in Sf9 insect cells, with titers of 5 x 10(8)p.f.u./ml before concentration. Transfection of 293-Cre cells with lacZ-expressing FD-AdV plasmid DNA followed by infection by Bac-B4 at a MOI of 2000 p.f.u./ml resulted in rescue of the helper-free vector. Subsequent passaging of the obtained FD-AdV using Bac-B4 as a helper resulted in approximately 100-fold increases of the vector titer at each passage. This resulting vector was completely free of helper virus and was able to transduce cultured 293 cells. However, scaling-up of FD-AdV production was prevented by the eventual emergence of replication-competent adenovirus (RCA). Experiments are underway to optimize this system for the large-scale production of helper virus-free FD-AdVs and to minimize the possibility of generation of replication-competent adenovirus (RCA) during vector production. This baculovirus-based system will be a very useful alternative to current methods for the production of FD-AdVs.

Characterization of replication-competent adenovirus isolates from large-scale production of a recombinant adenoviral vector

Replication-deficient adenoviral vectors have been developed for the delivery of DNA sequences encoding a variety of proteins intended for the management of disease through gene therapy. One concern is the occurrence of replication-competent adenovirus (RCA) in the population of replication-deficient adenoviral vectors as a result of recombination or contamination. To address this concern, it is necessary to determine the frequency of occurrence and to fully characterize the molecular structure and biological infectivity of RCA. rAd/p53 is a pIX-deleted p53 gene therapy vector that is designed to lower the RCA occurrence and to deliver the tumor suppressor gene p53 for treatment of various cancers. Multiple preparations of the replication-deficient adenoviral vector rAd/p53 were tested for the presence of RCA, employing a sensitive biological assay. Single plaques from RCA-positive preparations of rAd/p53 were isolated for molecular characterization. All of the RCA isolates displayed a single unique structure that contains the complete E1 sequence of adenovirus type 5 but lacks the p53 sequence. The detailed sequence analysis of the RCA suggests that it is most likely generated as a result of recombination events between the rAd/p53 DNA and the 293 host adenoviral sequence. Results from viral infectivity analysis by flow cytometry demonstrate no substantial difference in infectivity of RCA, rAd/p53, and wild-type adenovirus type 5 in 293 cells.

A novel family of linear plasmids with homology to plasmid pAL2-1 of Podospora anserina

Three recently isolated wild-type strains of the ascomycete Podospora anserina were analyzed for the presence of linear mitochondrial plasmids. In one of these strains, designated Wat, at least 12 distinct plasmid-like elements were identified. From molecular analyses a minimum number of 78 individual linear molecules with proteins bound to their 5' ends was estimated. In addition, the different members of this family of typical linear plasmids were shown to possess a common central region and terminal sequences which differ from one plasmid to another due to the presence of different numbers of a 2.4 kb sequence module. Finally, the pWa6 plasmids share a high degree of sequence similarity with pAL2-1, a linear plasmid previously identified in mitochondria of a long-lived mutant of P.anserina. A mechanism is proposed which explains the generation of these distinct, closely related extra-chromosomal genetic traits.

Evidence for a life span-prolonging effect of a linear plasmid in a longevity mutant of Podospora anserina

The linear mitochondrial plasmid pAL2-1 of the long-lived mutant AL2 of Podospora anserina was demonstrated to be able to integrate into the high molecular weight mitochondrial DNA (mtDNA). Hybridization analysis and densitometric evaluation of the mitochondrial genome isolated from cultures of different ages revealed that the mtDNA is highly stable during the whole life span of the mutant. In addition, and in sharp contrast to the situation in certain senescence-prone Neurospora strains, the mutated P. anserina mtDNA molecules containing integrated plasmid copies are not suppressive to wild-type genomes. As demonstrated by hybridization and polymerase chain reaction (PCR) analysis, the proportion of mtDNA molecules affected by the integration of pAL2-1 fluctuates between 10% and 50%. Comparative sequence analysis of free and integrated plasmid copies revealed four differences within the terminal inverted repeats (TIRs). These point mutations are not caused by the integration event since they occur subsequent to integration and at various ages. Interestingly, both repeats contain identical sequences indicating that the mechanism involved in the maintenance of perfect TIRs is active on both free and integrated plasmid copies. Finally, in reciprocal crosses between AL2 and the wild-type strain A, some abnormal progeny were obtained. One group of strains did not contain detectable amounts of plasmid pAL2-1, although the mtDNA was clearly of the type found in the long-lived mutant AL2. These strains exhibited a short-lived phenotype. In contrast, one strain was selected that was found to contain wild-type A-specific mitochondrial genomes and traces of pAL2-1. This strain was characterized by an increased life span. Altogether these data suggest that the linear plasmid pAL2-1 is involved in the expression of longevity in mutant AL2.

Protein-primed DNA replication: role of inverted terminal repeats in the Escherichia coli bacteriophage PRD1 life cycle

Escherichia coli bacteriophage PRD1 and its relatives contain linear double-stranded DNA genomes, the replication of which proceeds via a protein-primed mechanism. Characteristically, these molecules contain 5'-covalently bound terminal proteins and inverted terminal nucleotide sequences (inverted terminal repeats [ITRs]). The ITRs of each PRD1 phage species have evolved in parallel, suggesting communication between the molecule ends during the life cycle of these viruses. This process was studied by constructing chimeric PRD1 phage DNA molecules with dissimilar end sequences. These molecules were created by combining two closely related phage genomes (i) in vivo by homologous recombination and (ii) in vitro by ligation of appropriate DNA restriction fragments. The fate of the ITRs after propagation of single genomes was monitored by DNA sequence analysis. Recombinants created in vivo showed that phages with nonidentical genome termini are viable and relatively stable, and hybrid phages made in vitro verified this observation. However, genomes in which the dissimilar DNA termini had regained identical sequences were also detected. These observations are explained by a DNA replication model involving two not mutually exclusive pathways. The generality of this model in protein-primed DNA replication is discussed.

Sequence conversion during postreplicative adenovirus overlap recombination

Sequence conversion efficiently transfers genetic information in high yield during postreplicative adenovirus overlap recombination. This process is intrinsically nonreciprocal, depends on adenovirus-specific strand-displacement replication by both partner molecules, and requires that complementary sequences on displaced strands must exceed a minimal length to form a heteroduplex intermediate.

Redundant elements in the adenovirus type 5 inverted terminal repeat promote bidirectional transcription in vitro and are important for virus growth in vivo

The adenovirus inverted terminal repeat (ITR) contains a number of cis-acting elements that are involved in the initiation of viral DNA replication, as well as multiple binding motifs for the cellular transcription factors SP1 and ATF. In this study, we utilized a Hela cell transcription extract to demonstrate that the adenovirus type 5 ITR promotes bidirectional transcription in vitro. Primer extension analyses demonstrated that the ITR directed transcription at initiation sites both within the terminal repeat and at fixed distances outside of the ITR. The ITR also strongly stimulated transcription at the early region 1A (E1A) initiation site when it was situated immediately upstream of the E1A TATA box region. Deletion and point mutational analyses demonstrated that two distinct cis-acting elements were involved in these ITR-dependent transcriptional activities in vitro. Cellular transcription factors SP1 and ATF were previously shown to bind to these two regions. Analysis of viral mutants in vivo demonstrated that the NFIII/OCT-1 binding site and a conserved ATF motif were important for efficient viral growth. Regulatory elements in the ITR flanking region were found to functionally substitute for these sites.

Inverted repeats direct repair of adenovirus minichromosome ends

Adenovirus DNA initiates strand-displacement replication from origins located in identical inverted terminal repetitions (ITRs). Panhandle structures, formed by base pairing between ITRs on the displaced strands, have been proposed as replication intermediates for complementary strand synthesis. We have used a model system, which separates adenovirus replication origin sequences from those involved in panhandle formation, to study the length and sequence integrity of panhandles. By making a series of unidirectional deletion in the panhandle sequence, we show that 31 bp are necessary for panhandle formation. Removal of long stretches of 3'-unpaired nucleotides distal to the panhandle is extremely efficient. Our results argue for the formation of panhandles during adenovirus DNA replication and provide a mechanism for maintaining sequence identity between distantly located inverted repetitions. The size constraint may explain why the adenovirus ITRs are larger than the viral DNA replication origins.