The nucleotide sequence of the inverted terminal repetition of the tree shrew adenovirus DNA

The termini of the tupaia (tree shrew) adenovirus (TAV) DNA have been sequenced. The inverted terminal repetitions (ITR) are 166 bp long containing the A + T-rich, highly conserved sequence present in all adenovirus DNAs so far analysed. An unusual feature within the TAV ITR is the presence of four sets of a conserved sequence TGACCG which occur at or near the ends of many adenovirus ITR.     

Adenovirus sequences required for replication in vivo.

We have studied the in vivo replication properties of plasmids carrying deletion mutations within cloned adenovirus terminal sequences. Deletion mapping located the adenovirus DNA replication origin entirely within the first 67 bp of the adenovirus inverted terminal repeat. This region could be further subdivided into two functional domains: a minimal replication origin and an adjacent auxillary region which boosted the efficiency of replication by more than 100-fold. The minimal origin occupies the first 18 to 21 bp and includes sequences conserved between all adenovirus serotypes. The adjacent auxillary region extends past nucleotide 36 but not past nucleotide 67 and contains the binding site for nuclear factor I.     

Template requirements for in vivo replication of adenovirus DNA.

The adenovirus (Ad) DNA origin of replication was defined through an analysis of the DNA sequences necessary for the replication of plasmid DNAs with purified viral and cellular proteins. Results from several laboratories have shown that the origin consists of two functionally distinct domains: a 10-base-pair sequence present in the inverted terminal repetition (ITR) of all human serotypes and an adjacent sequence constituting the binding site for a cellular protein, nuclear factor I. To determine whether the same nucleotide sequences are necessary for origin function in vivo, we developed an assay for the replication of plasmid DNAs transfected into Ad5-infected cells. The assay is similar to that described by Hay et al. (J. Mol. Biol. 175:493-510, 1984). With this assay, plasmid DNA replication is dependent upon prior infection of cells with virus and only occurs with linear DNA molecules containing viral terminal sequences at each end. Replicated DNA is resistant to digestion with lambda-exonuclease, suggesting that a protein is covalently bound at both termini. A plasmid containing only the first 67 base pairs of the Ad2 ITR replicates as well as plasmids containing the entire ITR. Deletions or point mutations which reduce the binding of nuclear factor I to DNA in vitro reduce the efficiency of plasmid replication in vivo. A point mutation within the 10-base-pair conserved sequence has a similar effect upon replication. These results suggest that the two sequence domains of the Ad origin identified by in vitro studies are in fact important for viral DNA replication in infected cells. In addition, we found that two separate point mutations which lie outside these two sequence domains, and which have little or no effect upon DNA replication in vitro, also reduce the apparent efficiency of plasmid replication in vivo. Thus, there may be elements of the Ad DNA origin of replication which have not yet been identified by in vitro studies.     

The origin of adenovirus DNA replication: minimal DNA sequence requirement in vivo.

Adenovirus mini-chromosomes which contain two cloned, inverted adenovirus termini replicate in vivo when supplied with non-defective adenovirus as a helper. This system has been used to define the minimum cis acting DNA sequences required for adenovirus DNA replication in vivo. Deletions into each end of the adenovirus inverted terminal repeat (ITR) were generated with Bal31 exonuclease and the resulting molecules constructed into plasmids which contained two inverted copies of the deleted ITR separated by the bacterial neomycin phosphotransferase gene. To determine the effect of the deletion in vivo plasmids cleaved to expose the adenovirus termini were co-transfected with adenovirus type 2 DNA into tissue culture cells. The replicative ability of the molecules bearing adenovirus termini was assayed by Southern blotting of extracted DNA which had been treated with DpnI, a restriction enzyme which cleaves only methylated and therefore unreplicated, input DNA. Molecules containing the terminal 45 bp of the viral genome were fully active whereas molecules containing only 36 bp were in-active in this assay. Therefore sequences required for DNA replication are contained entirely within the terminal 45 bp of the viral genome. Thus, both the previously described highly conserved region (nucleotides 9-18) and the binding site for the cellular nuclear factor I (nucleotides 19-48) are essential for adenovirus DNA replication in vivo.     

Identification of two distinct regions within the adenovirus minimal origin of replication that are required for adenovirus type 4 DNA replication in vitro.

The adenovirus type 4 origins of replication are located at each end of the linear, protein-linked viral DNA molecule and consist of the terminal 18 bp of the viral genome. The sequence of the first 8 bp of the viral genome varies among different adenovirus serotypes, but the sequence from bp 9 to 18 is conserved in all human serotypes, suggesting that it may be of critical importance to origin function. Using an in vitro system in which purified fractions or crude extracts of adenovirus type 4-infected HeLa cells can support initiation and elongation on linearized plasmid templates containing cloned origin sequences, we examined the effect of single base changes in positions 9 to 18 of the adenovirus origin on DNA replication in vitro. Changes in positions 12 to 16 have little effect, whereas alterations at positions 9, 10, 11, 17, and 18 all reduce the efficiency of initiation of DNA replication by between 50 and 90%. Our results show that the region from bp 9 to 18 contains two sets of bases essential for DNA replication which are separated by 5 bp in which single base changes can be accommodated. The likely role of the region from bp 9 to 18 as containing the recognition sequence for a DNA-protein interaction essential for viral DNA replication is discussed.     

Sequence of inverted terminal repetitions from different adenoviruses: demonstration of conserved sequences and homology between SA7 termini and SV40 DNA.

We have established the nucleotide sequence for the inverted terminal repetition of human adenovirus type 3, a subgroup B adenovirus. The repetition, which is 136 bp long, shows a high degree of homology with the known sequence for the inverted repetition of adenovirus type 5 (Steenbergh et al., 1977) a subgroup C adenovirus. Partial sequence information convering 120 bp of the inverted terminal repetitions of human serotype 12, a subgroup A member, and of simian adenovirus type 7 has also been obtained. A comparison of the established sequences shows that the terminal repetitions, in particular the first 50 bp from the ends, contain sequences that have been well conserved in adenovirus evolution. For instance, only six mismatched base pairs were detected among the first 50 bp in the repetitions of simian adenovirus type 7 and human adenovirus type 5, although the homology between simian adenovirus 7 and human subgroup C adenoviruses was estimated to be only 30%. A 14 bp sequence located 9-22 nucleotides from the ends is present in DNAs from all the human serotypes examined as well as in simian adenovirus 7 DNA. Furthermore, the simian adenovirus 7 repetition contains a 21 bp sequence which is present in SV40 DNA, close to the origin of DNA replication.     

Sequence requirements for protein-primed DNA replication of bacteriophage PRD1

In vitro studies have demonstrated that linear duplex, protein-free DNA molecules containing an inverted terminal repeat (ITR) sequence of the PRD1 genome at one end can undergo replication by a protein-primed mechanism. No DNA replication was observed when the ITR sequence was deleted or was not exposed at the terminus of the template DNA. We have determined the minimal origin of replication by analyzing the template activity of various deletion derivatives. Our results showed that the terminal 20 base-pairs of ITR are required for efficient in vitro DNA replication. We have found that, within the minimal replication origin region, there are complementary sequences. A site-specific mutagenesis analysis showed that most of the point mutations in the complementary sequences markedly reduced the template activity. The analyses of the results obtained with synthetic oligonucleotides have revealed that the specificity of the replication origin is strand specific and even on a single-stranded template a particular DNA sequence including a 3'-terminal C residue is required for the initiation of PRD1 DNA replication in vitro.     

In vitro replication directed by a cloned adenovirus origin

A 5.7-kb recombinant plasmid, called XD-7, contains the terminal XbaI-E fragment from the left end of type 2 adenovirus cloned into the EcoRI site of pBR322. An average of 9% +/- 1% of input supercoiled, protein-free XD-7 DNA replicated as rolling circles with single-stranded tails ranging up to unit length and longer in reaction mixtures containing nuclear and cytoplasmic extracts from adenovirus-infected, but not uninfected, HeLa cells. The adenovirus origin was mapped on XD-7 by electron microscopy at the left boundary of the cloned adenovirus segment. Since replication proceeded rightwards, we conclude that the adenovirus l strand was displaced during replication. No origin was located at or near the EcoRI site on pBR322. Reversing the orientation of the adenovirus origin reversed the direction of replication, and deletion of the adenovirus origin abolished replication.     

Phylogenetic relationships between adenoviruses as inferred from nucleotide sequences of inverted terminal repeats

The nucleotide (nt) sequences of inverted terminal repeats (ITR) from human adenovirus (Ad) 19, bovine Ad1 (BAd1), bovine Ad3 (BAd3), canine Ad2 (CAd2) and an avian Ad, EDS-76, were determined. The length of the ITR sequence was 160 bp in Ad19, 159 bp in BAd1, 195 bp in BAd3, 196 bp in CAd2 and 52 bp in EDS-76. CAd2 had the longest ITR among the examined Ads, BAd3 the second longest, and EDS-76 had the shortest ITR. A TAAT sequence located between the 10th and 13th nt counted from the ends was conserved in all Ads examined so far. To determine phylogenetic relationships among human and animal Ads, sequences of their ITRs were compared, and a phylogenetic tree was constructed by using the maximum-likelihood method. It is the method involving statistical analysis of computing the probability of a particular set of sequences on a given tree and maximizing this probability over all evolutionary trees [Felsenstein, J. Mol. Evol. 17 (1981) 368-376]. From these analyses, it was found that members belonging to the same human Ad subgenus are related closely to each other, whereas representatives of different human subgenera are distributed rather divergently among animal Ads.     

Inverted terminal repeats and terminal proteins of the genomes of pneumococcal phages

The nucleotide (nt) sequence at the ends of the genomes of the Streptococcus pneumoniae phages Cp-5 and Cp-7 has been determined and compared with the corresponding sequence of phage Cp-1. The genomes of phages Cp-5 and Cp-7 have inverted terminal repeats (ITRs) 343 and 347 bp long, respectively. In Cp-1 DNA the ITR is 236 bp long and the following 116 bp are 93% homologous. Some regions within the ITRs are conserved in the three genomes although the complete sequence of the ITRs is no more conserved than the rest of their genomes. The chromatographic behavior of their tryptic peptides suggests that the terminal proteins (TPs) of at least two of the phages are similar and that the TPs of the three pneumococcal phages differ markedly from that of the Bacillus subtilis phage psi 29.     

禽腺病毒江苏株（JS）复制非必需片段的确定

利用PCR方法从一株Ⅰ群禽腺病毒的分离物(FAVI-JS)中扩增出其基因组的两个末端L片段和r片段、ITR片段,并分别克隆进pGEM-T easy载体,然后将L片段、r片段和ITR片段同时克隆进pHC粘粒载体中,获得质粒pHC-FAVI-r-ITR-L,再在该克隆片段中插入增强型绿色荧光蛋白(eGFP)基因,获得转移质粒载体pFAVI-eGFP.将pFAVI-eGFP转染已被该野生型Ⅰ群禽腺病毒分离物感染了的鸡胚肾细胞进行同源重组,通过无限稀释法筛选重组病毒,结果获得了表达增强型绿色荧光蛋白的重组Ⅰ群禽腺病毒rFAVI-eGFP,证明位于基因组右末端r片段和ITR片段之间的位点为病毒复制非必需区,为禽腺病毒的重组基因工程疫苗的研究奠定了基础.     

Nucleotide sequence and functional properties of DNA encoding incompatibility in the broad host-range plasmid R1162

Summary A 370 base pair (bp) fragment of R1162 DNA encoding the incompatibility determinant has been cloned and sequenced. The DNA is located between 6.1 and 6.5 on the R1162 map, near the origin of replication. The sequence contains three perfectly conserved 20 bp direct repeats, with 11 bp of this sequence repeated a fourth time. The direct repeat unit shows some homology with that of another, unrelated broad host-range plasmid, RK2. The cloned DNA has two other properties: it lowers the copy number of R1162 when cloned into this plasmid, and it is required in cis for replication of R1162 satellite plasmids.     

A common sequence in the inverted terminal repetitions of human and avian adenoviruses

The termini of the avian chick embryo lethal orphan (CELO) virus DNA have been sequenced. The results revealed a 63-bp-long inverted terminal repetition (ITR) which shared the sequence ATAATA with all adenovirus termini, thus far analyzed. The CELO virus ITR differed from those of the mammalian adenoviruses in two major aspects: (i) it is not a perfect duplication; (ii) it begins with a 5'-guanylic acid residue instead of the cytidylic acid normally observed in adenoviruses.     

An unstable mutant gene of the am locus of Neurospora results from a small duplication

We have cloned the unstable am mutant gene, am126, as well as the am gene from an am126 revertant. The mutation is a result of a 33-bp duplication that repeats a sequence starting 13 bp upstream of the 3' splice junction between intron 1 and exon 2 and extends 20 bp into exon 2. In addition, there is a G----A transition 2 bp upstream of the first copy of the duplicated sequence. In the revertant gene the wild-type sequence is precisely recovered, involving both the loss of the duplication and a reversion (A----G) of the associated transition. Our data suggest that only the more 5' of the two 3' splice junctions present in the duplicated version of the gene is used. This favors a 5'----3' scanning mechanism for exon splicing.     

Structure and function of the adenovirus origin of replication

Efficient initiation of adenovirus DNA replication requires the presence of specific terminal nucleotide sequences that collectively constitute the viral origin of replication. Using plasmids with deletions or base substitutions in a cloned segment of DNA derived from the terminus of the adenovirus 2 genome, we have demonstrated that the origin contains two functionally distinct regions. The first 18 bp of the viral genome are sufficient to support a limited degree of initiation. However, the presence of a sequence in the region between nucleotides 19 and 67 greatly enhances the efficiency of the initiation reaction. This region contains a specific binding site for a protein present in uninfected cells (KD = 2 X 10(-11) M). The bound protein protects the DNA segment between base pairs 19 and 43 from attack by DNAase I. Studies with deletion mutants indicate that binding of the cellular protein is responsible for the enhancement of initiation.     

Encapsidation of adenovirus 16 DNA is directed by a small DNA sequence at the left end of the genome

We have identified a DNA sequence in adenovirus type 16 which contains recognition signals for encapsidation of the viral DNA. The sequence acts in cis to direct the encapsidation of DNA from the end of the viral genome where it is located. The sequence is normally contained in the first 390–400 bp of the left end of the genome. The location was determined by analyzing a series of spontaneous mutants of Ad16 which carried reduplications of 200 to >500 bp of left end sequences at the right end of the genome, thus giving rise to enlarged inverted terminal repetitions (ITR). In plaque-purified (PP) Ad16 prototype virus the subgenomic DNA found in incomplete virus particles exclusively represents left end sequences. When the reduplication mutants were analyzed, we found that a reduplication of about 390 bp enabled subgenomic DNA molecules containing the right end to be encapsidated into incomplete particles as well. A reduplication of about 290 bp, however, did not allow subgenomic DNA containing the right end to be encapsidated. The difference in encapsidation described could not be attributed to an asymetric DNA replication in the mutants, since subgenomic DNA originating from both ends of the genome was produced in equal amounts in the infected cells. We conclude that an essential part of the encapsidation sequence must be located between 290 and 390 bp from the left end of the Ad16 genome.     

Sequence, organization, and evolution of the A+T region of Drosophila melanogaster mitochondrial DNA

The long (4.6-kb) A+T region of Drosophila melanogaster mitochondrial DNA has been cloned and sequenced. The A+T region is organized in two large arrays of tandemly repeated DNA sequence elements, with nonrepetitive intervening and flanking sequences comprising only 22% of its length. The first repeat array consists of five repeats of 338-373 bp. The second consists of four intact 464-bp repeats and a fifth partial repeat of 137 bp. Three DNA sequence elements are found to be highly conserved in D. melanogaster and in several Drosophila species with short A+T regions. These include a 300-bp DNA sequence element that overlaps the DNA replication origin and two thymidylate stretches identified on opposite DNA strands. We conclude that the length heterogeneity observed in the A+T regulatory region in mitochondrial DNAs from the genus Drosophila results from the expansion (and contraction) of the number of repeated DNA sequence elements. We also propose that the 300-bp conserved DNA sequence element, in conjunction with another primary sequence determinant, perhaps the adjacent thymidylate stretch, functions in the regulation of mitochondrial DNA replication.      

Specific binding of the adenovirus terminal protein precursor-DNA polymerase complex to the origin of DNA replication

Initiation of adenovirus DNA replication is dependent on a complex of the precursor of the terminal protein and the adenovirus-coded DNA polymerase (pTP-pol complex). This complex catalyzes the formation of a covalent linkage between dCMP and pTP in the presence of a functional origin of DNA replication residing in the terminal nucleotide sequence of adenovirus DNA. We have purified the pTP-pol complex of adenovirus type 5 and studied its binding to double-stranded DNA. Using DNA-cellulose chromatography it could be shown that the pTP-pol complex has a higher affinity for adenovirus DNA than for calf thymus or pBR322 DNA. From the differential binding of the pTP-pol complex to plasmids containing adenovirus terminal sequences with different deletions, it has been concluded that a sequence of 14 nucleotide pairs at positions 9-22 plays a crucial role in the binding of pTP-pol to adenovirus DNA. This region is conserved in the DNA's of all human adenovirus serotypes and is obviously an important structural element of the adenovirus origin of DNA replication. Comparative binding studies with adenovirus DNA polymerase and pTP-pol indicated that pTP is responsible for the binding. The nature of the binding of pTP-pol to the conserved sequence will be discussed.