Processing of alpha-globin and ICP0 mRNA in cells infected with herpes simplex virus type 1 ICP27 mutants.

Herpes simplex virus (HSV) ICP27 is an essential and multifunctional regulator of viral gene expression that modulates RNA splicing, polyadenylation, and nuclear export. We have previously reported that ICP27 causes the cytoplasmic accumulation of unspliced alpha-globin pre-mRNA. Here we examined the effects of a series of ICP27 mutations that alter important functional regions of the protein on the processing and nuclear transport of alpha-globin and HSV ICP0 RNA. The results demonstrate that ICP27 mutants that are impaired for growth in noncomplementing cells, including mutants in the N- and C-terminal regions, are defective in the accumulation of alpha-globin pre-mRNA. Unexpectedly, several mutants that are competent to repress the expression of reporter genes in transient transfection assays failed to accumulate unspliced RNA, implying that different mechanisms are responsible for transrepression and pre-mRNA accumulation. Several mutants caused a marked increase in the length and heterogeneity of the alpha-globin mRNA poly(A) tail, suggesting that ICP27 may directly or indirectly affect the regulation of poly(A) polymerase. ICP27 was also required for the accumulation of multiple ICP0 intron-bearing transcripts, but this effect displayed a mutational sensitivity profile different from that of accumulation of unspliced alpha-globin RNA. Moreover, unlike spliced and unspliced alpha-globin RNAs, which were efficiently exported to the cytoplasm, spliced and intron-containing ICP0 transcripts were predominantly nuclear in localization, and ICP27 was not required for nuclear retention of the spliced message. We propose that these transcript- and ICP27 allele-specific differences may be explained by the presence of a strong cis-acting ICP27 response element in the alpha-globin transcript.

Herpes simplex virus ICP27 induces cytoplasmic accumulation of unspliced polyadenylated alpha-globin pre-mRNA in infected HeLa cells.

Transcripts of most intron-bearing cellular genes must be processed by the splicing machinery in order to efficiently accumulate and gain access to the cytoplasm. However, we found that herpes simplex virus induces cytoplasmic accumulation of both spliced and unspliced polyadenylated alpha-globin RNAs in infected HeLa cells. Accumulation of the unspliced RNA required the immediate-early protein ICP27, and ICP27 was sufficient (in combination with ICP4) to produce this effect in a transient-transfection assay. However, expression of ICP27 did not markedly alter the levels of fully spliced alpha-globin transcripts in infected cells. These data demonstrate that the previously documented effects of ICP27 on the cellular splicing apparatus do not greatly inhibit splicing of alpha-globin RNA and argue that ICP27 induces a splicing-independent pathway for alpha-globin RNA accumulation and nuclear export.

Mutations in active-site residues of the uracil-DNA glycosylase encoded by vaccinia virus are incompatible with virus viability.

The D4R gene of vaccinia virus encodes a functional uracil-DNA glycosylase that is essential for viral viability (D. T. Stuart, C. Upton, M. A. Higman, E. G. Niles, and G. McFadden, J. Virol. 67:2503-2513, 1993), and a D4R mutant, ts4149, confers a conditional lethal defect in viral DNA replication (A. K. Millns, M. S. Carpenter, and A. M. DeLange, Virology 198:504-513, 1994). The mutant ts4149 protein was expressed in vitro and assayed for uracil-DNA glycosylase activity. Less than 6% of wild-type activity was observed at permissive temperatures, but the ts4149 protein was completely inactive at the nonpermissive temperature. Mutagenesis of the ts4149 gene back to wild type (Arg-179-->Gly) restored full activity. The ts4149 protein was considerably reduced in lysates of cells infected at the permissive temperature, and its activity was undetectable, even in the presence of the uracil glycosylase inhibitor protein, which inhibits the host uracil-DNA glycosylases but not that of vaccinia virus. Thus the ts4149 protein is thermolabile, correlating uracil removal with vaccinia virus DNA replication. Three active-site amino acids of the vaccinia virus uracil-DNA glycosylase were mutated (Asp-68-->Asn, Asn-120-->Val, and His-181-->Leu), producing proteins that were completely defective in uracil excision but still retained the ability to bind DNA. Each mutated D4R gene was transfected into vaccinia virus ts4149-infected cells in order to assess the recombination events that allowed virus survival at 40 degrees C. Genetic analysis and sequencing studies revealed that the only viruses to survive were those in which recombination eliminated the mutant locus. We conclude that the uracil cleavage activity of the D4R protein is essential for its function in vaccinia virus DNA replication, suggesting that the removal of uracil residues plays an obligatory role.

Expression of a ubiquitin derivative that conjugates to protein irreversibly produces phenotypes consistent with a ubiquitin deficiency.

Ubiquitin (Ub) exists in a dynamic equilibrium between the free form and the conjugated form. This equilibrium is maintained and regulated through the antagonistic actions of the conjugation system and a class of enzymes referred to collectively as the Ub-protein hydrolases. Using a previously described epitope-tagged Ub approach (Ellison, M., and Hochstrasser, M. (1991) J. Biol. Chem. 266, 21150-21157) we show here that a single amino acid substitution at the carboxyl terminus of Ub (Gly-76 to Ala-76) results in a derivative of Ub (UbA-76) that becomes irreversibly conjugated to protein when expressed in the yeast Saccharomyces cerevisiae, producing a profound effect on the Ub-conjugate equilibrium. The major target of UbA-76 conjugation is itself (and presumably wild-type Ub) producing unanchored chains at the expense of the free form. Unsurprisingly, the expression of UbA-76 results in yeast phenotypes that would be expected in situations of Ub deprivation. Such cells show slow growth characteristics and sensitivity to various forms of environmental stress and to ultraviolet light. In view of these findings, the expression of UbA-76 in higher organisms may represent a convenient epigenetic strategy for examining the physiological consequences of Ub deprivation or Ub-protein hydrolase disfunction in living cells without the need for gene disruption or replacement. The observation that UbA-76 couples to itself irreversibly also provides an effective tool for elucidating the role of Ub as the proteolytic signal.

A site-directed approach for constructing temperature-sensitive ubiquitin-conjugating enzymes reveals a cell cycle function and growth function for RAD6.

We have determined the gene sequence of a temperature-sensitive allele of the cell cycle-related ubiquitin-conjugating enzyme CDC34 (UBC 3) from Saccharomyces cerevisiae. The basis of temperature sensitivity is a missense mutation resulting in a proline to serine substitution at a residue that is conserved in all ubiquitin-conjugating enzymes identified thus far. This observation raised the possibility that other temperature-sensitive ubiquitin-conjugating enzymes could be generated in the same way. We therefore created the corresponding substitution in the DNA repair-related ubiquitin-conjugating enzyme, RAD6 (UBC2), and examined the effect of temperature on the cell proliferation and DNA repair-related functions of this altered polypeptide. Yeast strains carrying this mutation proved to be temperature-sensitive with respect to cell proliferation but not with respect to the DNA damage-processing phenotypes exhibited by other rad6 mutants. Upon further investigation of the proliferation defect exhibited by this mutant, we discovered that other rad6 gene mutants deleted for the gene undergo cell cycle arrest at the nonpermissive temperature, whereas the engineered temperature-sensitive allele showed no evidence of a cell cycle defect. From these findings, we conclude that the proliferation function of RAD6 can be subdivided into a growth component and a cell division cycle component and that the growth component is unrelated to the DNA repair functions of RAD6. A reasonable interpretation of these results is that different proteins are targeted for ubiquitination in each case. The conserved proline residue of RAD6 and CDC34 is part of a turn motif common to all ubiquitin-conjugating enzymes. It is therefore likely that site-directed substitution of prolines located in turns can be generally applied for the creation of other temperature-sensitive ubiquitin-conjugating enzymes and possibly other proteins as well.

Site-specific mutagenesis by O6-alkylguanines located in the chromosomes of mammalian cells: influence of the mammalian O6-alkylguanine-DNA alkyltransferase.

A plasmid was constructed in which a single guanine residue was replaced with either O6-methylguanine or O6-ethylguanine, two of the DNA adducts formed by carcinogenic alkylating agents. The vectors were introduced in parallel into a pair of Chinese hamster ovary cells, in which one member of the pair was deficient in the repair enzyme O6-alkylguanine-DNA alkyltransferase (mex-) and the other was proficient in this activity (mex+). The vectors integrated into and replicated within the respective host genomes. After intrachromosomal replication, the DNA sequence in the vicinity of the originally adducted site of each integrated vector was amplified from the host genome by using the polymerase chain reaction and was analyzed for mutations. High levels of mutation were observed from the O6-methylguanine- and O6-ethylguanine-containing vectors replicated in mex- cells (approximately 19% for O6-methylguanine and approximately 11% for O6-ethylguanine). DNA sequencing revealed the induced mutations to be almost exclusively G----A transitions. By contrast, little or no mutagenesis was detected when the adducted vectors were introduced into mex+ cells, indicating the significant role of the O6-alkylguanine-DNA alkyltransferase in the repair of O6-methylguanine and O6-ethylguanine in these mammalian cells.

Construction of a shuttle vector containing a single O6-methylguanine: a probe for mutagenesis in mammalian cells.

A shuttle vector, pKE15, was constructed for investigating the mechanisms by which single carcinogen-DNA adducts induce mutations in mammalian cells. pKE15 contains the SV40 origin of replication, the neomycin resistance gene, SV40 polyadenylation sequences and the pML2 origin of replication. Transfection of pKE15 into CHO cells established the G418-resistant phenotype; the frequency of G418-resistant clones was approximately 10(-4), a value that is similar to those obtained with other SV40-based vectors expressing the neomycin resistance gene. A tetranucleotide containing O6-methylguanine, a DNA adduct formed by carcinogenic alkylating agents, was incorporated into a 4-base gap positioned in the center of a PstI site. The tetranucleotide containing the adduct was physically mapped to a 14-base-pair region of the shuttle vector that included the ligation target, the PstI site. It was incorporated approximately equally into either of the complementary strands of the shuttle vector. The ligation efficiency of the tetranucleotide into the gapped genome was approximately 100% and was independent of the concentration of tetranucleotide used at concentrations ranging over one order of magnitude. The potential applications of the site-specifically modified genome for establishing the mutagenic fate of O6-methylguanine in repair-proficient and -deficient CHO cells are discussed.