Arrangement of messenger RNAs and protein coding sequences in the major late transcription unit of adenovirus 2

Genetic identification of adenovirus type 5 genes that influence viral spread

The mechanisms that control cell-to-cell spread of human adenoviruses (Ad) are not well understood. Two early viral proteins, E1B-19K and E3-ADP, appear to have opposing effects since viral mutants that are individually deficient in E1B-19K produce large plaques (G. Chinnadurai, Cell 33:759-766, 1983), while mutants deficient in E3-ADP produce small plaques (A. E. Tollefson et al., J. Virol. 70:2296-2306, 1996) on infected cell monolayers. We have used a genetic strategy to identify different viral genes that influence adenovirus type 5 (Ad5) spread in an epithelial cancer cell line. An Ad5 mutant (dl327; lacking most of the E3 region) with the restricted-spread (small-plaque) phenotype was randomly mutagenized with UV, and 27 large-plaque (lp) mutants were isolated. A combination of analyses of viral proteins and genomic DNA sequences have indicated that 23 mutants contained lesions in the E1B region affecting either 19K or both 19K and 55K proteins. Four other lp mutants contained lesions in early regions E1A and E4, in the early L1 region that codes for the i-leader protein, and in late regions that code for the viral structural proteins, penton base, and fiber. Our results suggest that the requirement of E3-ADP for Ad spread could be readily compensated for by abrogation of the functions of E1B-19K and provide genetic evidence that these two viral proteins influence viral spread in opposing manners. In addition to E1B and E3 proteins, other early and late proteins that regulate viral replication and infectivity also influence lateral viral spread. Our studies have identified novel mutations that could be exploited in designing efficient oncolytic Ad vectors.

DNA sequence analysis of the genes for the fowl adenovirus serotype 10 putative 33K and pVIII

The nucleotide sequence and genomic location of the fowl adenovirus serotype 10 (FAV-10) putative 33K and precursor protein VIII (pVIII) genes have been determined. The total genomic region sequenced was 1814 base pairs (bp) in length with the 33K coding region occupying the sequence from nucleotides 44 to 634 and the pVIII coding region nucleotides 949 to 1689. The location of both the 33K and pVIII genes have the same positional organization as their human adenovirus (HAV) counterparts which is 3 prime (3') to the 100K gene. Along with the 100K the 33K and pVIII form the late transcription unit 4 (L4). The FAV-10 putative 33K coding region could encode a polypeptide of 196 amino acids in length with a relative molecular mass of 21.9 kilodaltons (kDa) while the pVIII produces a polypeptide of 246 amino acids with a calculated relative mass of 26.7 kDa. Two possible splice acceptor sites were identified one 5' to the 33K and one 5' to the pVIII coding regions. A putative poly A recognition sequence of AATAAA was identified 3' to the pVIII, signaling the end of the L4 transcription unit.

Genomic location and nucleotide sequence of a porcine adenovirus penton base gene

The putative penton base gene of a porcine adenovirus serotype 3 (PAV3) has been identified, cloned and sequenced. The genomic location of the PAV3 penton base was deduced by probing a Southern blot with a polymerase chain reaction generated product containing the human adenovirus type 2 (HAV2) penton base gene. Sequencing revealed an open reading frame (ORF) of 1527 nucleotides coding for a polypeptide of 509 amino acids. However, cDNA analysis indicated an acceptor splice site one nucleotide upstream of the second ATG in the ORF. This produced an ORF of 1452 nucleotides coding for a polypeptide of 484 amino acids with a calculated molecular weight of 54.5 kDa. Comparison with the HAV2 penton base amino acid sequence revealed the putative PAV3 penton base homologue to be 87 amino acids shorter with an overall amino acid homology of approximately 65%. Comparison with the penton base proteins of other HAV types revealed a region between amino acid positions 283 and 379 with no similarity.

Adenovirus L1 52- and 55-kilodalton proteins are present within assembling virions and colocalize with nuclear structures distinct from replication centers

Analysis of a temperature-sensitive mutant, Ad5ts369, had indicated that the adenovirus L1 52- and 55-kDa proteins (52/55-kDa proteins) are required for the assembly of infectious virions. By using monoclonal antibodies directed against bacterially produced L1 52-kDa protein, the L1 52/55-kDa proteins were found to be differentially phosphorylated forms of a single 48-kDa polypeptide. Both phosphoforms were shown to be present within all suspected virus assembly intermediates (empty capsids, 50 to 100 molecules; young virions, 1 to 2 molecules) but not within mature virions. The mobilities of these proteins in polyacrylamide gels were affected by reducing agents, indicating that the 52/55-kDa proteins may exist as homodimers within the cell and within assembling particles. Immunofluorescence analysis revealed that the 52/55-kDa proteins localize to regions within the infected nucleus that are distinct from viral DNA replication centers, indicating that replication and assembly of viral components likely occur in separate nuclear compartments. Immunoelectron microscopic studies determined that the 52/55-kDa proteins are found in close association with structures that appear to contain assembling virions. These results are consistent with an active but transient role for the L1 products in assembly of the adenovirus particle, perhaps as scaffolding proteins.

Activation of the major late promoter in adenovirus transformed cells by 5-azacytidine

The adenovirus major late promoter (MLP) is normally not active in transformed cells. We investigated if it could be activated with 5-azacytidine. Three days of treatment with 10 microM 5-azacytidine induced transient activation of the MLP as shown by hybridization with an L1 r-strand-specific probe. The po/III-transcribed VA-RNAs were not activated. L1 activation was not accompanied by detectable changes in methylation of HpaII sites at the promoter or in the body of the transcript. Stably activated cell clones could be obtained at 20% frequency after long-term drug treatment.

Detailed kinetics of adenovirus type-5 steady-state transcripts during early infection

The appearance and steady-state accumulation of specific viral RNAs during the early phase of adenovirus type 5 (Ad5) infection was examined. HeLa cells were synchronously infected and harvested at 30 min intervals throughout the first 12 h of infection. Total cytoplasmic RNA was extracted from infected cells and analyzed by hybridization-selection and translation to identify the viral mRNAs from each early region on the basis of the protein products they encode. The same RNA samples were used for S-1 nuclease and Northern blot analyses to quantitatively compare the levels of individual viral RNAs that accumulate within each early transcription region (E1A, E1B, L1, E2A, E3 and E4). The salient features of this analysis show that RNA accumulation occurs first from E1A followed by E2A, E3 and E4, E1B and lastly, L1. Although the profile of RNA accumulation was unique for each early region, overlapping RNAs within E1A, E3, and E4, respectively, remained generally parallel to one another throughout early infection, in contrast to RNAs from E1B and L1, respectively. Since both the appearance and quantitative accumulation of specific early viral mRNAs were examined at many time points, a number of subtleties associated with the complex dynamics of early Ad5 gene expression were revealed. In particular, the L1 region was shown to transcribe from the major late promoter two early RNAs of 3.81 Kb and 3.5 Kb, either or both of which encode the 52,55 kDa proteins; the auxiliary i leader sequence was found on the 3.81 Kb RNA but not on the 3.5 Kb RNA.

Isolation and characterization of temperature-sensitive mutants of adenovirus type 7

Fifty temperature-sensitive mutants, which replicate at 32 degrees C but not at 39.5 degrees C, were isolated after mutagenesis of the vaccine strain of adenovirus type 7 with hydroxylamine (mutation frequency of 9.0%) or nitrous acid (mutation frequency of 3.8%). Intratypic complementation analyses separated 46 of these mutants into seven groups. Intertypic complementation tests with temperature-sensitive mutants of adenovirus type 5 showed that the mutant in complementation group A failed to complement H5ts125 (a DNA-binding protein mutant), that mutants in group B and C did not complement adenovirus type 5 hexon mutants, and that none of the mutants was defective in fiber production. Further phenotypic characterization showed that at the nonpermissive temperature the mutant in group A failed to make immunologically reactive DNA-binding protein, mutants in groups B and C were defective in transport of trimeric hexons to the nucleus, mutants in groups D, E, and F assembled empty capsids, and mutants in group G assembled DNA-containing capsids as well as empty capsids. The mutants of the complementation groups were physically mapped by marker rescue, and the mutations were localized between the following map coordinates: groups B and C between 50.4 and 60.2 map units (m.u.), groups D and E between 29.6 and 36.7 m.u., and group G between 36.7 and 42.0 m.u. or 44.0 and 47.0 m.u. The mutant in group A proved to be a double mutant.

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.

Biosynthesis and properties of the adenovirus 2 L1-encoded 52,000- and 55,000-Mr proteins

The adenovirus type 2 L1 region, which is located at 30.7 to 39.2 map units on the viral genome, is transcribed from the major late promoter during both early and late stages of virus replication, and a 52,000-Mr (52K) protein-55K protein doublet has been translated in vitro on L1-specific RNA. To investigate the biosynthesis and properties of the L1 52K and 55K proteins, we prepared antibody against a synthetic peptide encoded near the predicted N terminus. As determined by immunoprecipitation and immunoblot analysis, the antipeptide antibody recognized major 52K and 55K proteins synthesized in adenovirus type 2-infected cells that appeared to be identical to the 52K-55K doublet translated in vitro. The immunoprecipitated 52K and 55K proteins were very closely related, as shown by a peptide map analysis. Both L1 proteins were phosphorylated, and they were phosphorylated at similar sites. No precursor-product relationship was detected between the 52K and 55K proteins by a pulse-chase analysis. Biosynthesis of the L1 52K and 55K proteins began about 6 to 7 h postinfection, after biosynthesis of the early region 1A and early region 1B 19K (175R) T antigens, and reached a maximum rate at about 15 h; the maximum rate was maintained until at least 25 h postinfection. At all times, the 55K protein appeared to be synthesized at a severalfold-higher level than the 52K protein. Both proteins were quite stable and accumulated until late times after infection. Viral DNA replication was not essential for formation of the L1 proteins. Thus, the L1 52K-55K gene appears to be regulated in a manner different from the classical early and late viral genes but similar to the protein encoded by the i-leader (Symington et al., J. Virol. 57:849-856, 1986). The L1 proteins were detected in the cell nucleus by immunofluorescence microscopy with antipeptide antibody and were found to be primarily associated with the nuclear membrane by an immunoblot analysis of subcellular fractions.

Splicing of the E2A premessenger RNA of adenovirus serotype 2. Multiple pathways in spite of excision of the entire large intron

During the early period of infection, the 4.9 kb (kb = 10(3) bases) E2A premRNA of adenovirus serotype 2 is matured mainly into a 2.0 kb mRNA by excision of introns of 2233 and 626 nucleotides. In order to define all the possible steps of splicing occurring in vivo, we characterized splicing intermediates present after a limiting treatment of cells with cycloheximide. Three complementary methods of analysis were used: RNA transfer analysis, S1 nuclease mapping and complementary DNA-RNase assay. Our principal conclusions concerning the poly(A)+ species are as follows. The RNA intermediate family detected is more complex than expected, since two major RNA intermediates of 4.6 kb and 4.3 kb, two minor intermediates of 2.9 kb and 2.6 kb, and a 2.3 kb RNA, which represents a minor alternative mRNA form, are revealed. Despite its large size and the presence of multiple internal donor and acceptor signals, intron 1 is exclusively excised as a whole. Intron 2 is either primarily excised as a whole, removing the standard 626-nucleotide sequence, or a smaller sequence of 337 nucleotides is removed, generating the 2.3 kb alternative mRNA. Kinetics of the ligation reaction demonstrate that the minimal time for excision of intron 2 is no more than two minutes, indicating a high level of co-ordination of the multiple individual reactions occurring during excision of an intron. Besides the major pathway for E2A premRNA splicing, namely the excision first of intron 2, followed by the excision of intron 1 after a lag time of five minutes, a minor pathway (used with a frequency of 10%) can be detected where the order of intron excision was inverted. With the alternative variant of excision of intron 2, at least three different pathways are therefore used to mature the E2A premRNA. RNA intermediates resulting from the cleavage at the 5' end of introns and branching can be detected by S1 mapping experiments, but their low accumulative level (1% relatively to the initial premRNA) precluded their direction by RNA transfer experiments and their complete characterization.

Anatomy of region L1 from adenovirus type 2

The structure of r-strand-specific RNAs encoded between coordinates 26 and 32 on the adenovirus type 2 genome was mapped by a combination of S1 endonuclease analysis, primer extension, and in vitro transcription. The region includes the third leader segment (coordinates 26.8 to 27.0), the genes for the low-molecular-weight virus-associated RNAs (VA RNAs) (coordinates 29.5 to 30.7), and the amino-terminal end of the gene for the L1 52,000-55,000 polypeptide (coordinates 30.7 to 32.1). The positions at which the tripartite leader was attached to the three longest L1 mRNAs were mapped at the nucleotide level. The leader splice junction of species L1a was located at coordinate 26.8 and coincided with the 3' splice site for the third leader segment, whereas the leader-body splice junction of species L1b and L1c were located at coordinates 29.0 and 30.7, respectively. No protein products have so far been assigned to the L1a and L1b mRNAs, although it can be predicted from the nucleotide sequence that species L1b encodes a 8,300 polypeptide. The third RNA, species L1c, encodes the well-characterized 52,000-55,000 polypeptide. It was also shown that a previously unidentified class of VA RNAs exists predominantly in the poly(A)-fraction of late RNA preparations. These RNAs are heterogeneous in length (up to 3,000 nucleotides) because of irregular transcription termination and have 5' ends which map precisely to the initiation sites for VA RNAI and VA RNAII transcription. Finally it was shown that an RNA with a 5' end coinciding with the 5' splice site for the third leader segment exists in the poly(A)-fraction of late cytoplasmic RNA. This RNA species might represent an excised intron.

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.

A thermolabile mutant of adenovirus 5 resulting from a substitution mutation in the protein VIII gene

The mutant adenoviruses H5sub304 and H5RIr were isolated sequentially from adenovirus 5 wild type by selection for the loss of EcoRI restriction endonuclease sites by Jones and Shenk (Cell 13:181-188, 1978). sub304 lacks the site at 84.0 map units (m.u.), and RIr lacks both that and the site at 75.9 m.u. A set of derivatives of RIr that lack the site at 75.9 m.u. accumulated virus more slowly at 38.8 or 39.5 degrees C than those with the site present, as measured by low-multiplicity passage or single-step replication cycles, respectively. Since the EcoRI site at 75.9 m.u. is predicted to lie in the gene encoding the precursor to virion polypeptide VIII (pVIII), the failure to accumulate virus rapidly could lie either in some step in processing and assembly of virions or in an increased virion thermolability. The latter possibility was shown to be the case, as all strains mutated at the EcoRI 75.9 m.u. site were extremely thermolabile in vitro, even at 37 degrees C. CsCl equilibrium density centrifugation of heated crude stocks of RIr and sub304 demonstrated that loss of infectivity in RIr was accompanied by physical disruption of virions. Polyacrylamide gel electrophoresis of infected cell extracts or of purified virions showed that pVIII of RIr had an apparent molecular weight that was slightly greater than that of sub304, and mature RIr and sub304 virions displayed polypeptide VIIIs which appeared to be of identical molecular weights. Nucleotide sequence analysis of RIr demonstrated that it contained a 9-base-pair (bp) substitution for 6 bp found in sub304, leading to a loss of the EcoRI site and a predicted insertion of a single amino acid. Comparison of the sequence of sub304 with the published sequence of adenovirus 2 revealed two changes, a single transversion at bp 1,722 and a bp deletion at 1,749, leading to the loss of a TaqI site. The predicted reading frame change would lead to a stop codon at bp 1,885. This raises the question of whether adenovirus 2 and adenovirus 5 use the same reading fame for pVIII.

E1a regions of the human adenoviruses and of the highly oncogenic simian adenovirus 7 are closely related

Simian adenovirus 7 (SA7) is a highly oncogenic virus, capable of causing tumors in hamsters upon the direct injection of viral DNA. We determined the transcriptional organization of the transforming region and compared it with that of the human adenoviruses. This analysis demonstrated that there are two independently promoted transcription units similar to the E1a and E1b regions of the human adenoviruses. The nucleotide sequence of the SA7 E1a region demonstrated considerable homology with the human adenoviruses, both in the sequences that regulate E1a expression and in the encoded polypeptides. The amino acid homology was reflected in the ability of SA7 to complement the growth of human adenoviruses mutant in the E1a region. Furthermore, we found two regions of amino acid homology unique to SA7 and the highly oncogenic human adenovirus 12.

Splicing in adenovirus and other animal viruses

Splicing provides viruses with great genetic versatility. It is still too early to say whether this versatility is derived from ingeneous mechanisms evolved by necessity by the viruses, or whether the viruses indeed mimic cellular mechanisms. In any event, it is unlikely that cells will provide a single genomic cluster of genes that utilize splicing in such diverse ways as adenovirus, or the other viruses discussed here. And we may speculate that when the full role of splicing in adenovirus gene expression program is known, its import will continue to be a source of amazement!

Regulation of expression and nucleotide sequence of a late vaccinia virus gene

A subset of vaccinia virus genes are expressed only after DNA replication. To investigate the regulation of such transcriptional units, a representative gene encoding a major late polypeptide (Mr, 28,000) was mapped and sequenced. Translatable mRNAs were heterogeneous in length and overlapped several early genes downstream. The 5' end of the message was located, and the DNA segment upstream was excised and ligated to the coding sequence of the easily assayable procaryotic chloramphenicol acetyltransferase gene. The resulting chimeric gene was recombined into the thymidine kinase locus of the vaccinia virus genome, and infectious recombinant virus was isolated. Both the time of chloramphenicol acetyltransferase synthesis in infected cells and the requirement for DNA replication indicate that the sequence upstream of the late gene contains cis-acting transcriptional regulatory signals.

Organization of RNA transcripts from a vaccinia virus early gene cluster

The detailed organization of the RNAs transcribed from an early gene cluster encoded by vaccinia virus has been determined from the information derived from several complementary techniques. These include hybrid selection coupled with cell-free translation to locate DNA sequences complementary to mRNAs encoding specific polypeptides; RNA filter hybridization to size and locate on the DNA mature RNAs as well as higher-molecular-weight RNAs; S1 nuclease mapping to precisely locate the 5' and 3' ends of the RNAs; S1 nuclease mapping to precisely locate the 5' and 3' ends of the RNAs; and fractionation of hybrid-selected mRNAs in an agarose gel containing methyl mercury hydroxide followed by the cell-free translation of these mRNAs to definitively ascertain the size of the mRNA encoding each polypeptide. The early gene cluster is located between 21 and 26 kilobases from the left end of the vaccinia virus genome and is encoded by a 5.0-kilobase EcoRI fragment which spans the HindIII-N, -M, and -K fragments. Transcribed towards the left terminus are four mature mRNAs, 1,450, 950, 780, and 400 nucleotides in size, encoding polypeptides of 55, 30, 20, and 10 kilodaltons, respectively. These mRNAs are colinear with the DNA template and are closely spaced such that the 5' terminus of one mRNA is within 50 base pairs of the 3' terminus of the adjacent RNA. In addition to the mature size mRNAs, there are higher-molecular-weight RNAs, 5,000, 3,300, 2,350, 2,300, 1,800, 1,700, and 1,350 nucleotides in size. The 5' and 3' termini of the high-molecular-weight RNAs are coterminal with the 5' and 3' termini of the mature size mRNA. The implications of this arrangement and the biogenesis of these early mRNAs are discussed.

Organization of six early transcripts synthesized from a vaccinia virus EcoRI DNA fragment

Four early transcripts and the polypeptides they encode have been mapped to the vaccinia virus EcoRI F DNA fragment, which spans the vaccinia HindIII J and H fragments. In addition, two transcripts for which no encoded polypeptides have been identified have also been mapped. Elucidation of the organization of these six transcripts by hybrid selection, S1 nuclease mapping, translation of size-fractionated RNA, and by filter hybridization demonstrates that approximately 90% of this DNA fragment is transcribed during early infection. All but one of these RNAs (1.35 kilobases [kb]) are transcribed in a rightward direction. The leftmost transcript of 0.6 to 0.7 kb encodes a 19,000-dalton (19K) polypeptide that has been determined to be thymidine kinase (D.E. Hruby and L.A. Ball, J. Virol. 43:403-409, 1982; G. Bajszar et al., J. Virol. 45:62-72, 1983). Immediately following the 3' end of this RNA is the 1.7-kb transcript encoding a 36K polypeptide. The 5' end of a 1.25-kb RNA encoding a 22K polypeptide is downstream of the 5' end of the 1.7-kb RNA, and its 3' end may be coterminal with the 3' end of the 1.7-kb RNA. The 2.45-kb transcript is coterminal at its 5' end with the message encoding thymidine kinase and is coterminal at its 3' end with the adjacent 1.7-kb mRNA. This RNA was not demonstrated to encode a polypeptide. Approximately 300 nucleotides from the 3' end of the 1.7-kb RNA is a 3.6-kb transcript encoding a 110K polypeptide. The 3' end of this large RNA lies several hundred nucleotides from the 3' end of the 1.35-kb RNA which is transcribed in the opposite direction. No splicing of RNA has been detected with the S1 nuclease mapping technique of Berk and Sharp. The organization of three late messages, which overlap these early transcripts, has been determined, and these results are discussed in the accompanying paper.

Arrangement of late RNAs transcribed from a 7.1-kilobase EcoRI vaccinia virus DNA fragment

Three late transcripts have been mapped to the vaccinia virus 7.1-kilobase (kb) EcoRI F fragment, which is located approximately 85 kb from the left end of the viral genome. Hybrid selection and translation of RNA have demonstrated that these mRNAs encode three polypeptides with apparent molecular weights of 32,000 (32K), 26K, and 19K. The transcripts encoding the 32K and 19K polypeptides are synthesized in a leftward direction and overlap each other as well as the RNA encoding the early 110K polypeptide. In addition, the RNA encoding the 32K polypeptide also overlaps an early transcript of 1.35 kb (see accompanying paper). The transcript encoding the 26K polypeptide overlaps the early 2.45-, 0.6- to 0.7-, and 1.7-kb RNAs, and all four mRNAs are transcribed from left to right. The protein coding sequences for the 26K and 32K polypeptides lie outside the 7.1-kb DNA fragment. Due to their heterogeneity in size, each of the three late transcripts is undetectable as a distinct size by filter hybridization. In addition, although S1 mapping has detected the 5' terminus of the late RNA which maps entirely within this fragment, it has been unable to size and locate the 3' ends of all three transcripts, and this result indicates that the heterodisperse size of the RNAs is due to heterogeneity at the 3' ends of these transcripts. The cause of this heterogeneity in termination of transcription is not known.

Analysis of Ad5 hexon and 100K ts mutants using conformation-specific monoclonal antibodies

Adenovirus type 5 ts mutants deficient in hexon metabolism were investigated using conformation-specific monoclonal antibodies directed against hexon capsomeres and the viral 100K protein. The ts mutants map either in the hexon structural gene or in the gene encoding the 100K protein, a major, late nonstructural protein. All of the mutants examined (ts1, ts2, ts3, ts4, ts17, and ts20 of J. F. Williams, M. Gharpure, S. Ustacelebi, and S. McDonald (1971). J. Gen. Virol. 11, 95-101) were unable to produce the capsomeric form of hexon (a trimer of three hexon monomers) at the nonpermissive temperature. However, all of the mutants retained the ability to produce a complex of 100K and hexon which has been demonstrated to play a major role in the assembly of hexon trimers. The mutants accumulated nontrimerized hexon in this ts complex in the perinuclear region of the cell. Several of the mutants (ts1, ts2, ts3) were found to successfully assemble hexon synthesized at the nonpermissive temperature upon shift down to the permissive temperature, even in the presence of a protein synthesis inhibitor. The mutant, ts2, which maps in the hexon structural gene, was found to be dependent on protein synthesis for transport of hexon trimers into the nucleus during temperature shift down, while the 100K ts mutants, ts1 and ts3, were independent of protein synthesis for both hexon assembly and transport.

Methods utilizing cell-free protein-synthesizing systems for the identification of recombinant DNA molecules

Herein we outline three methods that, when coupled with cell-free protein synthesis, permit the identification of recombinant DNA molecules encoding specific polypeptides. RNAs enriched by fractionation on methylmercury hydroxide agarose gels are used to prepare sequence-specific probes. Recombinant DNA clones thus identified are further characterized as to their encoded polypeptides by either hybrid selection or hybrid arrest of translation.

Polypeptide structure and encoding location of the adenovirus serotype 2 late, nonstructural 33K protein

Radiochemical microsequence analysis of selected tryptic peptides of the adenovirus type 2 33K nonstructural protein has revealed the precise region of the genomic nucleotide sequence that encodes this protein. The initiation codon for the 33K protein lies 606 nucleotides to the right of the EcoRI restriction site at 70.7 map units and 281 nucleotides to the left of the postulated carboxyterminal codon of the adenovirus 100K protein. The coding regions for these two proteins thus overlap; however, the 33K protein is derived from the +1 frame with respect to the postulated 100K reading frame. Our results contradict an earlier published report suggesting that these two proteins share extensive amino acid sequence homology (N. Axelrod, Virology 87:366-383, 1978). The published nucleotide sequence of the Ad2 EcoRI-F fragment (70.7 to 75.9 map units) cannot accommodate in a single reading frame the peptide sequences of the 33K protein that we have determined. Sequence analysis of DNA fragments derived from virus has confirmed the published nucleotide sequence in all critical regions with respect to the coding region for the 33K protein. Consequently, our data are only consistent with the existence of an mRNA splice within the coding region for 33K. Consensus donor and acceptor splice sequences have been located that would predict the removal of 202 nucleotides from the transcripts for the 33K protein. Removal of these nucleotides would explain the structure of a peptide that cannot otherwise be directly encoded by the EcoRI-F fragment. Identification of the precise splice points by peptide sequencing has permitted a prediction of the complete amino acid sequence for the 33K protein.

Molecular cloning and expression during myogenesis of sequences coding for M-creatine kinase

Sequences complementary to muscle poly(A)+RNA were cloned in the plasmid pBR322 and the resulting colonies were screened by colony hybridization with labeled cDNA derived from skeletal muscle and smooth muscle (gizzard). The skeletal muscle-specific clones were further screened by RNA blotting hybridization for a muscle mRNA having the size expected for a putative type M creatine kinase (M-CK) mRNA. The remaining clones with the expected hybridization properties were finally characterized by hybrid-selected translation, and a cloned sequence was shown to contain DNA hybridizing to mRNA that could be translated into M-CK. This plasmid, pMCK1, was further characterized by restriction mapping. Blot analysis of total cell RNA from differentiating myogenic cell cultures showed accumulation of M-CK mRNA in cultures older than 42 hr but not in young little-differentiated cultures.

Sequential transcription-translation of simian virus 40 by using mammalian cell extracts

Ribonucleic acids (RNAs) transcribed in vitro by using the whole-cell extract system of Manley et al. (Proc. Natl. Acad. Sci. U.S.A. 77:3855-3859, 1980) were tested for their efficiency and fidelity in directing protein synthesis in reticulocyte lysates. Simian virus 40 deoxyribonucleic acid (DNA), cleaved by various restriction endonucleases, was used as the template. Successful translation of the small tumor antigen t, as well as the capsid proteins VP1, VP2, and VP3, was detected by immunoprecipitation analysis. Although no synthesis of large T antigen was detected, use of this technology allows detection of large T synthesis resulting from the correct splicing of as little as 0.2% of the in vitro RNA transcripts, making it ideal for use as an in vitro splicing assay. Transcripts synthesized in vitro were used as messages at least as efficiently as were viral messenger RNA's (mRNA's) synthesized in vivo; and in the case of small t, there was more efficient translation of small t mRNA synthesized in vitro than of small t mRNA synthesized in vivo. The transcripts that served as mRNA's for the various polypeptides were identified by using the following two criteria. (i) The sensitivity of synthesis of a given protein to digestion of the template DNA with restriction enzymes allowed the localization of the promoter and coding regions. (ii) Translation of size-fractionated RNA allowed confirmation of the transcript-mRNA assignments. With these techniques we found that VP2, VP3 and, in some cases, VP1 synthesis resulted from the initiation of translation at internal AUG codons. In fact, families of polypeptides were produced by initiation of translation at AUG codons within sequences coding for VP1 and T, presumably as a result of transcription initiation events that generated 5' ends immediately upstream from these AUGs. Application of this technology for the identification of coding regions within cloned DNA fragments is discussed.

Molecular cloning and characterization of double-stranded cDNA coding for bovine chymosin

A full-length cDNA copy of the mRNA encoding calf chymosin (also known as rennin), a proteolytic enzyme with commercial importance in the manufacture of cheese, has been cloned in an f1 bacteriophage vector. The nucleotide sequence of the cDNA was determined, and translation of that sequence into amino acids predicts that the zymogen prochymosin is actually synthesized in vivo as preprochymosin with a 16 amino acid signal peptide. In vitro translation of total poly(A)-enriched RNA from the calf fourth stomach (abomasum) and immunoprecipitation with antichymosin antiserum revealed that a form of chymosin (probably preprochymosin judging from the Mr-value) is the major in vitro translation product of RNA from that tissue. Gel-transfer hybridization of restriction endonuclease-cleaved bovine chromosomal DNA with labeled cDNA probes indicated that the two known forms of chymosin, A and B, must be products of two different alleles of a single chymosin gene.

Expression of the gene encoding the adenovirus DNA terminal protein precursor in productively infected and transformed cells

The major product of in vitro translation of early RNA prepared from H5ts125-infected cells and selected by hybridization to adenoviral DNA fragments spanning the region from 14.7 to 31.5 map units had been shown to be identical to the 87-kilodalton terminal protein precursor. A 72- to 75-kilodalton polypeptide whose rRNA can be selected by DNA from this same region and made in the presence of anisomycin was indistinguishable from the 72-kilodalton single-stranded DNA-binding protein encoded by the region from 60.1 to 66.6 map units. The accumulation of cytoplasmic RNA sequences complementary to these l-strand genes under various conditions of infection and in certain lines of transformed cells has been investigated by solution hybridization of cytoplasmic RNA to the separated strands of restriction endonuclease fragments of adenoviral DNA. During the early phase, RNA sequences complementary to the region from 11.6 to 36.7 map units were present at a concentration of 10 to 60 copies per cell, regardless of the nature of the block used to inhibit viral DNA synthesis. By 24 h after infection in the absence of any such block, sequences complementary to the regions from 11.6 to 18.2 map units (IVa2) and from 18.6 to 36.7 map units (E2B) accumulated to concentrations of 4,800 and 280 copies per cell, respectively. The ratio of cytoplasmic E2A RNA sequences to E2B RNA sequences remained close to 10:1 throughout the time period investigated. Of the transformed cell lines which retained E2B DNA sequences that were examined, only the T2C4 line expressed these sequences in cytoplasmic RNA. The implications of these observations for regulation of expression of the adenoviral early l-strand genes are discussed.

Late nonstructural 100,000- and 33,000-dalton proteins of adenovirus type 2. II. Immunological and protein chemical analysis

For an immunological analysis of the late adenovirus type 2 nonstructural 100,000-dalton (100K) and 33K proteins, we prepared antisera against sodium dodecyl sulfate-denatured, gel-purified 100K and 33K proteins. These antisera were tested for potential cross-reactivity, since according to a previous report (Axelrod, Virology 87:366--383, 1978) these two proteins exhibit extensive amino acid homologies. However, immunoprecipitations of 100K and 33K proteins, as well as a sensitive immune replica technique, did not reveal any immunological relationship between these proteins. Therefore, using fingerprint peptide analysis, we investigated the structural relationship between 100K and 33K proteins labeled with a 14C-amino acid mixture or with [14C]proline after digestion with trypsin. We detected only minor, if any, amino acid homologies, indicating that the 100K and 33K proteins are not structurally related.

Characterization of two temperature-sensitive mutants of type 5 adenovirus with mutations in the 100,000-dalton protein gene

Complementation analysis assigned the mutations of strains H5ts115 and H5ts116, two hexon-minus mutants, to the 100,000-dalton (100K) protein gene. Heterotypic marker rescue (i.e., type 5 adenovirus [Ad5] temperature-sensitive mutants DNA X EcoRI restriction fragments of Ad2 DNA) confirmed the results of previous marker rescue mapping studies, and the heterotypic recombinants yielded unique hybrid (Ad5-Ad2) 100K proteins which were intermediate in size between Ad5 and Ad2 proteins and appeared to be as functionally active as the wild-type 100K protein. Phenotypic characterization of these mutants showed that both the hexon polypeptides and the 100K polypeptides were unstable at the nonpermissive temperature, whereas fiber and penton were not degraded, and that the 100K protein made at 39.5 degrees C could not be utilized after a shift to the permissive temperature (32 degrees C). The role of the 100K protein in the assembly of the hexon trimer was also examined by in vitro protein synthesis. Normally, hexon polypeptides synthesized during an in vitro reaction are assembled into immunoreactive hexons. However, this assembly was inhibited by preincubation of the cell extract with anti-100K immunoglobulin G; neither anti-fiber immunoglobulin G nor normal rabbit immunoglobulin G inhibited hexon assembly. It is postulated that an interaction between the 100K protein and hexon polypeptides is required for effective assembly of hexon trimers.

Sequential transcription-translation of simian virus 40 by using mammalian cell extracts

Ribonucleic acids (RNAs) transcribed in vitro by using the whole-cell extract system of Manley et al. (Proc. Natl. Acad. Sci. U.S.A. 77:3855-3859, 1980) were tested for their efficiency and fidelity in directing protein synthesis in reticulocyte lysates. Simian virus 40 deoxyribonucleic acid (DNA), cleaved by various restriction endonucleases, was used as the template. Successful translation of the small tumor antigen t, as well as the capsid proteins VP1, VP2, and VP3, was detected by immunoprecipitation analysis. Although no synthesis of large T antigen was detected, use of this technology allows detection of large T synthesis resulting from the correct splicing of as little as 0.2% of the in vitro RNA transcripts, making it ideal for use as an in vitro splicing assay. Transcripts synthesized in vitro were used as messages at least as efficiently as were viral messenger RNA's (mRNA's) synthesized in vivo; and in the case of small t, there was more efficient translation of small t mRNA synthesized in vitro than of small t mRNA synthesized in vivo. The transcripts that served as mRNA's for the various polypeptides were identified by using the following two criteria. (i) The sensitivity of synthesis of a given protein to digestion of the template DNA with restriction enzymes allowed the localization of the promoter and coding regions. (ii) Translation of size-fractionated RNA allowed confirmation of the transcript-mRNA assignments. With these techniques we found that VP2, VP3 and, in some cases, VP1 synthesis resulted from the initiation of translation at internal AUG codons. In fact, families of polypeptides were produced by initiation of translation at AUG codons within sequences coding for VP1 and T, presumably as a result of transcription initiation events that generated 5' ends immediately upstream from these AUGs. Application of this technology for the identification of coding regions within cloned DNA fragments is discussed.