Complementation of translational defect for growth of human adenovirus type 2 in Simian cells by a Simian virus 40-induced factor

The defective step which leads human adenovirus type 2 infection of African green monkey kidney cells (clone C14) to be abortive and its complementation in simian virus 40-transformed cells (clone T22) were studied by comparing the synthesis and function of macromolecules in these cell lines. Neither a quantitative nor a qualitative difference was detected in virus DNA replication and in virus mRNA synthesis in these cells, while a definite difference was observed in protein synthesis. The capsid proteins, such as hexon or penton, were synthesized in T22 cells but not in C14 cells. Inability of polyribosomes to synthesize the capsid proteins in C14 cells infected with adenovirus type 2 may not be due to a defect in elongation of nascent polypeptides or their release, since nascent polypeptides pulse-labelled with [³H]leucine were completely released from polyribosomes after the chase. The electrophoretic analysis of proteins synthesized in vitro with polyribosomes from either infected T22 or C14 cells using the pH 5 enzyme and S100 fraction from T22 cells revealed that hexon was synthesized with polyribosomes from T22 cells but not from C14 cells, thereby suggesting that the defect is not ascribed to a component in the pH 5 enzyme and S100 fraction, but resides in polyribosomes. The analysis of late adenovirus mRNA associated with polyribosomes in the infected T22 and C14 cells by hybridization competition or by sedimentation revealed that all the species of virus mRNA were present in the cytoplasm of these cells; however, certain species of virus mRNA larger than 20 S were absent in polyribosomes of the infected C14 cells. Sedimentation analysis of late adenovirus mRNA following separation on poly(U)-Sepharose or by membrane filtration gave the same results. These results suggest that the defect of C14 cells to support growth of adenoviruses is due to the inability of ribosomes to associate with certain species of late virus mRNA to form polyribosomes and suggest that a factor complementing this defect is induced by simian virus 40.     

Coordinate regulation of two cytoplasmic RNA species transcribed from early region 2 of the adenovirus 2 genome

Early region 2 (E2) of the adenovirus 2 genome specifies a 72,000-dalton DNA-binding protein that is required for viral DNA replication. Electron microscopy studies have detected two major forms of 20S E2 mRNA, one species with a 5' leader from map position 75 and a second form having a leader from position 72 (Chow et al., J. Mol. Biol. 134:265-303, 1979). Only the species with a leader from position 75 was detected at early times; however, both forms were found at late times. We have analyzed the temporal regulation of E2 expression by documenting mRNA accumulation in the cytoplasm. Kinetic studies of pulse-labeled RNAs demonstrated a peak of E2 cytoplasmic RNa synthesis at 10 to 12 h, coinciding with the time of maximal synthesis of the 72,000-dalton DNA binding protein and viral DNA. To estimate the relative abundances of the two major E2 RNA species at various times during infection, total E2 cytoplasmic and polysomal 20S RNAs were isolated by hybridization-selection with specific DNA probes. The leader sequences in the selected RNAs were then quantitated by further RNA-DNA hybridization. We found that the elevated accumulation rate for E2 cytoplasmic RNA at late times reflected an increase in formation of both major species. Moreover, for all time points examined 66% of the mRNA species had a 5' end from map position 75, and 33% had a 5' terminus from position 72. Continuous labeling experiments provided evidence that both RNA forms have comparable half-lives. The results suggest that the two major species encoded by E2 are regulated in a coordinate fashion late in infection.     

Nucleotide sequence analysis of the leader segments in a cloned copy of adenovirus 2 fiber mRNA.

Fiber mRNA of adenovirus 2 has been used as a template for RNA-dependent DNA polymerase. The resulting cDNA/RNA hybrids have been inserted at the Pst I site of the plasmid vector pBR322 after A:T tailing. One recombinant plasmid, pJAW 43, has been characterized in detail and shown to contain sequences from the main body of fiber mRNA, the three leaders common to most late adenoviral mRNAs and a fourth leader found in some species of fiber mRNA. The complete DNA sequence of the leader region has been determined and does not contain the initiation codon AUG, although this codon does occur immediately downstream from the junction between the fourth leader and the main body of the fiber mRNA. The first leader (map coordinate 16.6) is 41 nucleotides long, the second (from 19.6) is 71 nucleotides, the third (from 26.6) is 88 nucleotides and the fourth (from 78.5) is 181 nucleotides. The location of junctions between viral leaders and intervening sequences has been determined by reference, where possible, to sequences of the adenovirus 2 genome. Although the presence of short repeated sequences at the boundaries of intervening sequences and leaders makes it impossible to locate the splice point unambiguously, all of the leader-intervening sequence junctions can be arranged to stress a common feature--the presence of the dinucleotides GT and AG at the 5' and 3' ends, respectively, of the intervening sequences. This prototype sequence, which has also been recognized at or near the splice points in other eucaryotic systems, is possibly part of a larger unit which serves as a recognition site for specific excision-ligation events that ultimately lead to the production of mature mRNAs.     

Translation of adenovirus 2 late mRNAs microinjected into cultured African green monkey kidney cells.

Adenovirus 2-infected monkey cells fail to synthesize fiber, a 62,000 Mr virion polypeptide expressed at late times in productively infected cells. Yet these cells contain fiber mRNA that, after isolation, can be translated in vitro. The reason for the failure of monkey cells to translate fiber mRNA has been approached by microinjecting adenovirus mRNA into the cytoplasm of cultured monkey cells. Late adenovirus 2 mRNA, isolated from infected HeLa cells, was efficiently expressed when microinjected into the African green monkey kidney cell line CV-C. Expressed viral proteins identified by immunoprecipitation included the adenovirus fiber polypeptide. This result demonstrates that the monkey cell translational apparatus is capable of recognizing and expressing functional adenovirus fiber mRNA. Microinjection of late virus mRNA into cells previously infected with wild-type adenovirus 2 failed to increase significantly the yield of infectious virus.     

Cap-independent translation of tobacco etch virus is conferred by an RNA pseudoknot in the 5'-leader

The tobacco etch virus (TEV) 5'-leader promotes cap-independent translation in a 5'-proximal position and promotes internal initiation when present in the intercistronic region of a dicistronic mRNA, indicating that the leader contains an internal ribosome entry site. The TEV 143-nucleotide 5'-leader folds into a structure that contains two domains, each of which contains an RNA pseudoknot. Mutational analysis of the TEV 5'-leader identified pseudoknot (PK) 1 within the 5'-proximal domain and an upstream single-stranded region flanking PK1 as necessary to promote cap-independent translation. Mutations to either stem or to loops 2 or 3 of PK1 substantially disrupted cap-independent translation. The sequence of loop 3 in PK1 is complementary to a region in 18 S rRNA that is conserved throughout eukaryotes. Mutations within L3 that disrupted its potential base pairing with 18 S rRNA reduced cap-independent translation, whereas mutations that maintained the potential for base pairing with 18 S rRNA had little effect. These results indicated that the TEV 5'-leader functionally substitutes for a 5'-cap and promotes cap-independent translation through a 45-nucleotide pseudoknot-containing domain.     

An adenovirus agnogene.

The nucleotide sequence of a 550 base pairs long segment, located between map positions 21 and 22.5 in the adenovirus type 2 genome has been determined. S1 nuclease mapping and sequence analysis of cDNA copies of adenovirus mRNA demonstrated that the established sequence includes the i-leader which is spliced to the 5'-end of certain adenovirus mRNAs (1). The i-leader which is 440 nucleotides long contains an open translational reading frame which is preceded by an AUG triplet and which terminates in the third segment of the tripartite leader. A polypeptide with the same molecular weight as predicted from the DNA sequence was identified by in vitro translation of mRNA which had been selected by hybridization to DNA fragments, containing sequences from the i-leader. The results thus suggest that the i-leader, unlike other adenovirus leader segments, is used for translation.     

Pet111 Acts in the 5''-Leader of the Saccharomyces Cerevisiae Mitochondrial Cox2 mRNA to Promote Its Translation

PET111 is a yeast nuclear gene specifically required for the expression of the mitochondrial gene COX2, encoding cytochrome c oxidase subunit II (coxII). Previous studies have shown that PET111 activates translation of the COX2 mRNA. To map the site of PET111 action we have constructed, in vitro, genes coding for chimeric mRNAs, introduced them into mitochondria by transformation and studied their expression. Translation of a chimeric mRNA with the 612-base 5'-untranslated leader of the COX3 mRNA fused precisely to the structural gene for the coxII-precursor protein is independent of PET111, but does require a COX3 mRNA-specific translational activator known to work on the COX3 5'-leader. This result demonstrates that PET111 is not required for any posttranslational step. Translation of a chimeric mRNA with the 54-base 5'-leader of the COX2 mRNA fused precisely to the structural gene for cytochrome c oxidase subunit III was dependent on PET111 activity. These results demonstrate that PET111 acts specifically at a site in the short COX2 5'-leader to activate translation of downstream coding sequences.     

Evidence that the penton base of adenovirus is involved in potentiation of toxicity of Pseudomonas exotoxin conjugated to epidermal growth factor.

When KB cells are incubated for 1 h with human adenovirus type 2 or type 5 (1 microgram/ml) and a conjugate of epidermal growth factor and Pseudomonas exotoxin (EGF-PE), protein synthesis is inhibited by 80 to 90%. Under these conditions, neither adenovirus nor EGF-PE alone has any effect on host protein synthesis. Thus, adenovirus enhances the toxicity of EGF-PE. A number of antibodies to intact virus and capsid components were tested for their ability to block the enhancing activity and virus uptake. At appropriate dilutions, antibodies prepared against intact virus and penton base blocked the enhancing activity without affecting virus uptake. Antibodies against hexon and fiber blocked virus uptake and enhancing activity in parallel. These studies suggest that the penton base is important in lysis of the vesicles which contain adenovirus and EGF-PE, and this base allows virus and toxin to enter the cytoplasm.     

Sequences from the beginning of the fiber messenger RNA of adenovirus-2.

Small restriction fragments, from around co-ordinate 86.6 on the adenovirus-2 genome, have been used as primers for direct DNA sequence analysis by Sanger's (Sanger et al., 1977) chain termination method with Ad2² DNA as template. The genomic sequences obtained have been compared with sequences deduced using fiber messenger RNA from Ad2 or Ad2⁺ ND5-infected cells as template. With one primer, Hha 54, the sequences complementary to mRNA match those of the genome for 10 nucleotides but then differ from those found on the genome because this primer hybridizes near the point at which the leader sequence becomes joined to the main body of fiber mRNA. Using Ad2⁺ ND5 fiber mRNA as template, the sequence beyond the point of divergence matches the known sequence of the third leader component of one of the late Ad2 mRNAs, that encoding the hexon polypeptide. With Ad2 fiber mRNA, a heterogeneous sequence continuation is found, in accordance with earlier findings that two major species of fiber mRNA are present, which differ in the nature of the leader component joined to the main body of fiber mRNA (Chow &; Broker, 1978). Nevertheless, the data suggest that both leader components appear to become joined to the same nucleotide at the start of the main body of fiber mRNA.The AUG codon, which probably encodes the N-terminus of the fiber polypeptide, occurs just two nucleotides beyond the point at which these leader segments become spliced to the main body of fiber mRNA.