Faculty Bibliography

We report that the rate of transcription of cellular beta-tubulin genes increases during the early phase of adenovirus infection of HeLa cells, with kinetics very similar to those routinely found for viral genes. This activation depends upon adenovirus early region E1a, which encodes products that activate early virus transcription. To compare the responses of viral and cellular genes to E1a, we infected HeLa cells with dl312, a transcriptionally inactive deletion mutant that lacks a functional E1a gene. We then superinfected the cells with a helper virus, dl327, which encodes active E1a products, and measured changes in the rates of transcription of various cell and viral genes. Early region E3 of dl312 was activated 0 to 6 h postinfection and then repressed at 8 h postinfection, thus reproducing the two-step kinetics characteristic of a wild-type infection. Synthesis of beta-tubulin nuclear RNA was also transiently induced two- to six-fold, rising and falling in a manner similar to E3 transcription. An increase in helper virus multiplicity gave an increase in beta-tubulin stimulation, but dl312 alone, even at a high multiplicity of infection, gave no induction, confirming the requirement for E1a. beta-Actin nuclear RNA was actively synthesized before infection, but it was not further stimulated by the virus. Cellular beta-globin gene transcription was not stimulated by the virus, although transcription of a transfected beta-globin plasmid was induced by the virus or from a cotransfected E1a expression plasmid. We conclude that adenovirus 5 can stimulate beta-tubulin gene transcription. We discuss the significance for the viral life cycle of viral stimulation of cell genes and consider possible mechanisms in the light of the results obtained with beta-actin and beta-tubulin

Transcription of the c-fos proto-oncogene is greatly increased within minutes of administering purified growth factors to quiescent 3T3 cells. This stimulation is the most rapid transcriptional response to peptide growth factors yet described, and implies a role for c-fos in cell-cycle control. Transformation by c-fos may result from a temporal deregulation of this control

The adenovirus type 2 (Ad-2) "i" leader is an RNA segment which is preserved in some mRNA species from the Ad-2 late transcription unit. It maps between the second and third segments of the standard tripartite leader. We located the boundaries of the i leader in genomic Ad-2 DNA and determined its nucleotide sequence. The leader contains an ATG initiator near its 5' boundary, followed by a reading frame which is open for translation. We suggest that the i leader constitutes an Ad-2 coding sequence whose novel position within the leader of major late transcription unit messengers allows it to be translated in preference to coding sequences in mRNA main bodies. The i leader potentially contributes to the coding sequences of a family of proteins. Also, a Northern blot analysis of late mRNAs containing the i leader suggests that it may be retained in the leaders of many different late transcription unit mRNAs. We compare the i leader to the simian virus 40 agnogene.

The transcription of adenovirus type 2 genes proceeds through a broad three-phase program. From 1 to 4 h postinfection six early transcription units (EIa, EIb, EII, EIII, EIV, and the promoter-proximal segment of the late transcription unit) are activated. From 4 to 6 h postinfection transcription of the early genes is depressed. After the onset of viral DNA replication at approximately 6 h postinfection, the transcript from the late promoter is antiterminated, and this transcript dominates viral RNA synthesis. The early activation period also proceeds through a series of stages; early regions EIa and EIV are activated first, followed by early region EII. We show that in the presence of anisomycin, a stringent inhibitor of protein synthesis, nuclear RNA and cytoplasmic polyadenylated RNA from regions EIa and EIV accumulate at normal rates, whereas RNAs from regions EII and EIII do not accumulate. We also show that failure to accumulate RNAs from regions EII and EIII is due to reduction of the rate of transcription by greater than 90%. We conclude that the regulation of the promoters for early regions EII and EIII is distinct from the mechanism that operates on the other early transcription units. The promoters for early regions EII and EIII diverge and lie approximately 500 nucleotides apart. We examined the structure of viral chromatin in this region early during infection by mild DNase I digestion in isolated nuclei and indirect end labeling with a DNA probe near these promoters. In control, drug-free cells where EII and EIII are transcribed and in anisomycin-treated cells where EII and EIII are not transcribed we detect the same regular DNase I pattern. We suggest that regulation of EII and EIII is not mediated through a change in gross chromatin structure, but rather by a viral effector, possibly a product of region EIa

A series of recombinants of adenovirus DNA fragments and pBR322 was used to test the transcriptional activity of the nine known adenovirus promoters in a cell-free extract. Specific initiation was seen at all five early promoters as well as at the major late promotor and at the intermediate promoter for polypeptide IX. The system failed to recognize the two other adenovirus promoters, which were prominent in vivo only at intermediate and late stages in infection. Microheterogeneity of 5' termini at several adenovirus promoters, previously shown in vivo, was reproduced in the in vitro reaction and indeed appeared to result from heterogeneous initiation rather than 5' processing. To test for the presence of soluble factors involved in regulation of nRNA synthesis, the activity of extracts prepared from early and late stages of infection was compared on an assortment of viral promoter sites. Although mock and early extracts showed identical transcription patterns, extracts prepared from late stages gave 5- to 10-fold relative enhancement of the late and polypeptide IX promoters as compared with early promoters

The major late promoter of adeovirus-2 is located at coordinate 16.45 and initiates synthesis of nuclear precursors that are processed into mRNAs which fall into five 3- co-terminal families, L1-L5. These mRNAs all share a common tripartite 5' leader with a capped terminus encoded at th RNA initiation site. We show that the coorindate 16.45 RNA initiation site is also an early promoter, and yields transcripts detectable as early as 1 hr post-infection, prior to DNA replication and the early-late switch at 6-8 hr. Polyadenylated cytoplasmic RNA from the first 3- co-terminal family, L1, is also produced from the earliest stages of infection. L1 mRNA accumulates in the cytoplasm in the presence of cycloheximide, which blocks DNA replication and the onset of the late phase. Early nuclear RNA contains the same capped 5' terminal RNAase T-1 undecanucleotide and promoter proximal oligonucleotides present in late transcripts. This implies that precisely the same transcription start site is utilized for early L1 mRNA synthesis as is used during the late stage for L1-L5 late mRNA synthesis. In contrast to the early apperance of L1 mRNA, neither L2 nor L3 mRNAs are detected until 5-6 hr post infection. We cnclude that a major event in the Ad-2 early-late switch is a novel form of control which activates L2-L5 mRNA production