The phenotype in vitro and in infected cells of herpes simplex virus 1 alpha trans-inducing factor (VP16) carrying temperature-sensitive mutations introduced by substitution of cysteines.

alpha trans-inducing factor (alpha TIF, VP16, Vmw65) is an essential structural protein of herpes simplex virus, being required for virion assembly. The protein also forms complexes with host proteins and a response element and transactivates the alpha genes which carry this element. The protein contains an acidic carboxyl terminus required for transactivation and a much larger amino-terminal domain required for promoter recognition. We report the first set of temperature-sensitive (ts) mutations deliberately introduced into the protein by substitution of the cysteine codons with those specifying glycine at positions 78, 102, and 176, either singly or in combinations. We report the following results. (i) All mutated proteins synthesized in vitro formed complexes with the DNA response element at room temperature. However, the mutant with the triple substitution and two mutants with substitutions in two of the three cysteines exhibited a ts phenotype at 33 and 37 degrees C, and one exhibited a ts phenotype only at 37 degrees C. (ii) Replacement of wild-type alpha TIF with genes carrying substitutions in any two cysteines conferred a ts phenotype for replication at 39.5 degrees C. Shift-down experiments indicated that the 10(4)- to 10(5)-fold reduction in virus yield at the nonpermissive temperature was due to the disfunction of alpha TIF late in infection, presumably in virion maturation. (iii) The alpha TIF expressed in cells infected with mutant viruses exhibited the same ts phenotype in protein-DNA complex formation as those expressed in vitro from mutated plasmids. Although the virus carrying the alpha TIF substitutions at Cys-102 and Cys-176 failed to induce a reporter gene linked to the alpha 4 promoter at 39.5 degrees C, it replicated as well as the parent virus in cells maintained for the first 10 h of infection at 39.5 degrees C. We conclude the following. (i) Formation of DNA-protein complexes containing alpha TIF is a poor prognosticator of alpha TIF function. (ii) The data presented here and in the literature strongly support the hypothesis that the secondary structure of the alpha TIF is very sensitive to deletions or insertions which probably affect the interaction of alpha TIF with both viral proteins in the virion and cellular proteins during infection. As a consequence, deletion-insertion mutagenesis may not shed useful information on the role of transactivating function of alpha TIF in infection. (iii) Since cysteines may play a role in stabilizing the secondary structure of proteins, substitutions of cysteines may be a powerful technique for site-specific construction of ts mutants in essential viral proteins.     

Role of alpha-transinducing factor (VP16) in the induction of alpha genes within the context of viral genomes.

In herpes simplex virus 1, the five alpha genes are induced by alpha-transinducing factor (alpha TIF; VP16), a virion protein, acting in concert with Oct-1 and other cellular proteins on a cis-acting site in the promoter domain of alpha genes. Because alpha TIF is an essential virion protein, its function as an inducer can best be evaluated only by mutating the cis-acting site. Earlier we reported on a series of 17 mutations in and around the cis-acting site of a 275-bp alpha 27 promoter fused to a reporter gene and recombined into the viral genome. These recombinant viruses were tested in Vero cells in the presence of cycloheximide, and we demonstrated that mutations in the sequence required for Oct-1 binding abolished transactivation whereas mutations in the alpha TIF-dependent GARAT sequence decreased but did not abolish transactivation. We now report that (i) in limited-passage human embryonic lung cells, alpha gene expression from promoters mutated in the GARAT sequences is often higher and more variable than in Vero cells, (ii) in the absence of cycloheximide, the mutant viruses show less significant impairment of reporter gene expression, (iii) Oct-1 can bind either to the overlapping octamer element or to various TAATGARAT sequences with differing degrees of binding strength and these relative binding levels correlate well with levels of gene expression observed in infected cells, (iv) in the cis-acting site upstream of the alpha 4 gene, no degenerate overlapping Oct-1 sequence exists, and therefore in this instance Oct-1 must be binding directly to the TAATGARAT sequence, (v) extension of the alpha 27 promoter by an additional 1,334 bp results in much higher expression of the reporter gene as a result of additional upstream cis-acting sites, and (vi) obliteration of the most proximal Oct-1 binding element within the 275-bp promoter dramatically reduces gene expression even in the presence of the additional upstream cis-acting sites.     

Photoaffinity electrophoretic mobility shift assay using photoreactive DNA bearing 3-trifluoromethyl-3-phenyldiazirine in its phosphate backbone

Photoaffinity cross-linking enables the analysis of interactions between DNA and proteins even under denaturing conditions. We present a photoaffinity electrophoretic mobility shift assay (EMSA) in which two heterogeneous techniques―photoaffinity cross-linking using DNA bearing 3-trifluoromethyl-3-phenyldiazirine and sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS–PAGE) analysis—are combined. To prepare the photoreactive DNA, which is an essential tool for photoaffinity EMSA, we first determined the optimal conditions for the integration of 4-(3-trifluoromethyl-3H-diazirin-3-yl)benzyl bromide to the specific site of oligonucleotide where phosphodiester linkage was replaced with phosphorothioate linkage. The photoaffinity EMSA was developed using the POU (initial letters of three genes: Pit-l, Oct-1,2, and unc-86) domain region of Oct-1 protein, which specifically bound to octamer DNA motif (ATGCAAAT). The affinity-purified recombinant POU domain proteins conjugated with glutathione-S-transferase (GST) contained three distinct proteins with molecular weights of 34, 36, and 45 kDa. The photoaffinity EMSA could clearly distinguish the individual binding abilities of three proteins on a single lane and showed that the whole POU domain protein specifically bound to octamer DNA motif by competition experiments. Using the nuclear extract of HeLa cells, the photoaffinity EMSA revealed that at least five specific proteins could bind to the octamer DNA motif. These results show that photoaffinity EMSA using 3-trifluoromethyl-3-phenyldiazirine can provide high-performance analysis of DNA-binding proteins.     

A subfamily of RNA-binding DEAD-box proteins acts as an estrogen receptor alpha coactivator through the N-terminal activation domain (AF-1) with an RNA coactivator, SRA

One class of the nuclear receptor AF-2 coactivator complexes contains the SRC-1/TIF2 family, CBP/p300 and an RNA coactivator, SRA. We identified a subfamily of RNA-binding DEAD-box proteins (p72/p68) as a human estrogen receptor alpha (hER alpha) coactivator in the complex containing these factors. p72/p68 interacted with both the AD2 of any SRC-1/TIF2 family protein and the hER alpha A/B domain, but not with any other nuclear receptor tested. p72/p68, TIF2 (SRC-1) and SRA were co-immunoprecipitated with estrogen-bound hER alpha in MCF7 cells and in partially purified complexes associated with hER alpha from HeLa nuclear extracts. Estrogen induced co-localization of p72 with hER alpha and TIF2 in the nucleus. The presence of p72/p68 potentiated the estrogen-induced expression of the endogenous pS2 gene in MCF7 cells. In a transient expression assay, a combination of p72/p68 with SRA and one TIF2 brought an ultimate synergism to the estrogen-induced transactivation of hER alpha. These findings indicate that p72/p68 acts as an ER subtype-selective coactivator through ER alpha AF-1 by associating with the coactivator complex to bind its AF-2 through direct binding with SRA and the SRC-1/TIF2 family proteins.     

Segments of the POU domain influence one another''s DNA-binding specificity.

The ubiquitously expressed mammalian POU-domain protein Oct-1 specifically recognizes two classes of cis-acting regulatory elements that bear little sequence similarity, the octamer motif ATGCAAAT and the TAATGARAT motif. The related pituitary-specific POU protein Pit-1 also recognizes these two motifs but, unlike Oct-1, binds preferentially to the TAATGARAT motif. Yet in our assay, Pit-1 still binds octamer elements better than does the octamer motif-binding protein Oct-3. The POU domain is responsible for recognizing these diverse regulatory sequences through multiple DNA contacts that include the two POU subdomains, the POU-specific region, and the POU homeodomain. The DNA-binding properties of 10 chimeric POU domains, in which different POU-domain segments are derived from either Oct-1 or Pit-1, reveal a high degree of structural plasticity; these hybrid proteins all bind DNA well and frequently bind particular sites better than does either of the parental POU domains. In these chimeric POU domains, the POU-specific A and B boxes and the hypervariable POU linker can influence DNA-binding specificity. The surprising result is that the influence a particular segment has on DNA-binding specificity can be greatly affected by the origin of other segments of the POU domain and the sequence of the binding site. Thus, the broad but selective DNA-binding specificity of Oct-1 is conferred both by multiple DNA contacts and by dynamic interactions within the DNA-bound POU domain.