Characterization of the trans-activation properties of equine herpesvirus 1 EICP0 protein

The EICP0 protein of equine herpesvirus 1 (EHV-1) is an early, viral regulatory protein that independently trans-activates EHV-1 immediate-early (IE), early, gamma1 late, and gamma2 late promoters. To assess whether this powerful trans-activator functions in conjunction with three other EHV-1 regulatory proteins to activate expression of the various classes of viral promoters, transient cotransfection assays were performed in which effector plasmids expressing the EICP22, EICP27, and IE proteins were used either singly or in combination with an EICP0 effector construct. These analyses revealed that (i) independently, the EICP0 and IE proteins are powerful trans-activators but do not function synergistically, (ii) the IE protein inhibits the ability of the EICP0 protein to trans-activate the IE, gamma1 late, and gamma2 late promoters, (iii) the EICP22 and EICP0 proteins do not function together to significantly trans-activate any EHV-1 promoter, and (iv) the EICP27 and EICP0 proteins function synergistically to trans-activate the early and gamma1 late promoters. A panel of EICP0 truncation and deletion mutant plasmids was generated and used in experiments to define the domains of the 419-amino-acid (aa) EICP0 protein that are important for the trans-activation of each class of EHV-1 promoters. These studies revealed that (i) carboxy-terminal truncation mutants of the EICP0 protein exhibited a progressive loss of trans-activating ability as increasing portions of the carboxy terminus were removed, (ii) the amino terminus of the EICP0 protein containing the RING finger (aa 8 to 46) and the acidic region (aa 71 to 84) was necessary but not sufficient for activation of all classes of EHV-1 promoters, (iii) the RING finger was absolutely essential for activation of EHV-1 promoters, since deletion of the entire RING finger motif (aa 8 to 46) or a portion of it (aa 19 to 30) completely abrogated the ability of these mutants to activate any promoter tested, (iv) the acidic region contributed to the ability of the EICP0 protein to activate the early and gamma1 late promoters, and deletion of the acidic region enhanced the ability of this mutant to activate the IE promoter, (v) the carboxy terminus (aa 325 to 419), which is rich in glutamine residues, was dispensable for the EICP0 trans-activation function, (vi) a motif resembling a nuclear localization signal (aa 289 to 293) was unnecessary for the EICP0 protein to trans-activate promoters of any temporal class, and (vii) the EICP0 protein was phosphorylated during infection, and deletion of the serine-rich region (aa 210 to 217), a potential site for phosphorylation, reduced by more than 70% the ability of the EICP0 protein to activate the gamma2 late class of promoters.     

The EICP22 protein of equine herpesvirus 1 physically interacts with the immediate-early protein and with itself to form dimers and higher-order complexes

The EICP22 protein (EICP22P) of Equine herpesvirus 1 (EHV-1) is an early protein that functions synergistically with other EHV-1 regulatory proteins to transactivate the expression of early and late viral genes. We have previously identified EICP22P as an accessory regulatory protein that has the ability to enhance the transactivating properties and the sequence-specific DNA-binding activity of the EHV-1 immediate-early protein (IEP). In the present study, we identify EICP22P as a self-associating protein able to form dimers and higher-order complexes during infection. Studies with the yeast two-hybrid system also indicate that physical interactions occur between EICP22P and IEP and that EICP22P self-aggregates. Results from in vitro and in vivo coimmunoprecipitation experiments and glutathione S-transferase (GST) pull-down studies confirmed a direct protein-protein interaction between EICP22P and IEP as well as self-interactions of EICP22P. Analyses of infected cells by laser-scanning confocal microscopy with antibodies specific for IEP and EICP22P revealed that these viral regulatory proteins colocalize in the nucleus at early times postinfection and form aggregates of dense nuclear structures within the nucleoplasm. Mutational analyses with a battery of EICP22P deletion mutants in both yeast two-hybrid and GST pull-down experiments implicated amino acids between positions 124 and 143 as the critical domain mediating the EICP22P self-interactions. Additional in vitro protein-binding assays with a library of GST-EICP22P deletion mutants identified amino acids mapping within region 2 (amino acids [aa] 65 to 196) and region 3 (aa 197 to 268) of EICP22P as residues that mediate its interaction with IEP.     

Functional characterization of a Chrysanthemum dichrum stress-related promoter

A 1,474-bp stress-inducible CdDREBa promoter was identified from Chrysanthemum dichrum, revealing several candidate stress-related cis-acting elements (MYC-box, MYB site, GT-1, and W-box) within it. In Arabidopsis leaf tissues transformed with a CdDREBa promoter-β-glucuronidase (GUS) gene fusion, serially 5'-deleted CdDREBa promoters were differentially activated by cold and salinity. Histochemical and quantitative assays of GUS expression allowed us to localize a critical part of the promoter located between upstream 430 and 351 nt. This 80-bp fragment enhanced GUS expression under salinity stress when fused to -90/+8 CaMV 35S minimal promoter. Further promoter internal-deletion assays indicated that a low temperature-responsive element was located between positions -430 and -390, and a salinity inducible one between -385 and -351. Our results showed that there was a novel stress-related critical region except for the known cis-acting element (MYC-box, GT-1) in CdDREBa promoter.     

Mouse integrin alphav promoter is regulated by transcriptional factors Ets and Sp1 in melanoma cells

A 17-bp region between the -31 and -15 bp region of the mouse integrin alphav gene is known to be one of the cis-acting elements for promoter activity. Experimental binding of nuclear proteins to the -31/-15 region reveals that the -27/-16 region mediates the binding. The -27/-16 region, GGCTCCTCCTCC, has a TCCTCC motif, one of the Sp1 binding motifs. An anti-Sp1 IgG and an Sp1-binding oligonucleotide interfered with the binding of nuclear proteins to the -27/-16 oligonucleotide, demonstrating that Sp1 binds to the -27/-16 region. In addition to the -27/-16 region, two other regions, -108/-89 and -64/-44, were found to bind to nuclear proteins within the -108/+1 alphav promoter region. An oligonucleotide containing the Ets-binding consensus sequence of CAGGAAGT interfered with their binding, indicating that both regions have a functional Ets-binding site; which is ACGGAAGT from -106 to -99 bp and ACTTCCTC from -61 to -54 bp, as deduced from the sequence. Mutations in or deletions from any one of three cis-acting elements, the two Ets-binding sites or one Sp1-binding site, remarkably decreased the promoter activity detected in the -108/+1 region. Cotransfection of both Sp1 and Ets-1 cDNAs with the -108/+1 region into B16F10 cells increased the promoter activity 2.9-fold. These results demonstrate that Sp1 and Ets cooperate to activate the -108/+1-alphav promoter region.     

Regulatory function of the equine herpesvirus 1 ICP27 gene product.

The UL3 protein of equine herpesvirus 1 (EHV-1) KyA strain is a homolog of the ICP27 alpha regulatory protein of herpes simplex virus type 1 (HSV-1) and the ORF 4 protein of varicella-zoster virus. To characterize the regulatory function of the UL3 gene product, a UL3 gene expression vector (pSVUL3) and a vector expressing a truncated version of the UL3 gene (pSVUL3P) were generated. These effector plasmids, in combination with an EHV-1 immediate-early (IE) gene expression vector (pSVIE) and chimeric EHV-1 promoter-chloramphenicol acetyltransferase (CAT) reporter constructs, were used in transient transfection assays. These assays demonstrated that the EHV-1 UL3 gene product is a regulatory protein that can independently trans activate the EHV-1 IE promoter; however, this effect can be inhibited by the repressive function of the IE gene product on the IE promoter (R. H. Smith, G. B. Caughman, and D. J. O'Callaghan, J. Virol. 66:936-945, 1992). In the presence of the IE gene product, the UL3 gene product significantly augments gene expression directed by the promoters of three EHV-1 early genes (thymidine kinase; IR4, which is the homolog of HSV-1 ICP22; and UL3 [ICP27]) and the promoter of the EHV-1 late gene IR5, which is the homolog of HSV-1 US10. Sequences located at nucleotides -123 to +20 of the UL3 promoter harbor a TATA box, SP1 binding site, CAAT box, and octamer binding site and, when linked to the CAT reporter gene, are trans activated to maximal levels by the pSVIE construct in transient expression assays. Results from CAT assays also suggest that the first 11 amino acids of the UL3 protein are not essential for the regulatory function of the UL3 gene product.