NO2 interfacial transfer is reduced by phospholipid monolayers.

Nitrogen dioxide (NO2) is a ubiquitous, pollutant gas that produces a broad range of pathological and physiological effects on the lung. Absorption of inhaled NO2 is coupled to near-interfacial reactions between the solute gas and constituents of the airway and alveolar epithelial lining fluid. Although alveolar surfactant imparts limited resistance to respiratory gas exchange compared with that contributed by either the pulmonary membrane or uptake in red blood cells, resistance to NO2 flux could have a significant effect on NO2 absorption kinetics. To investigate the effect of interfacial surfactant on NO2 absorption, we designed an apparatus permitting exposure of variably compressed monolayers. Our results suggest that compressed monolayers enriched in 1,2-dipalmitoyl-sn-3-glycero-phosphocholine present significant resistance to NO2 absorption even at surface tensions greater than those achieved in vivo. However, monolayers composed of pure unsaturated phospholipids failed to alter NO2 absorption significantly when compressed, in spite of similar reductions in surface tension. The results demonstrate that phospholipid monolayers appreciably limit NO2 absorption and further that monolayer-induced resistance to NO2 flux is related to physicochemical properties of the film itself rather than alterations within the aqueous and gas phases. On the basis of these findings, we propose that pulmonary surfactant may influence the intrapulmonary gas phase distribution of inhaled NO2.

Sequences flanking the cAMP responsive core of the HTLV-I tax response elements influence CREB protease sensitivity.

The human T cell leukemia virus type I (HTLV-I) Tax protein activates transcription from the viral long terminal repeat and select cellular promoters by interacting with cellular DNA-binding proteins. The HTLV-I promoter contains three copies of a Tax-responsive element (TRE-1), each of which possesses a core cAMP response element (CRE). The cAMP response element-binding protein, CREB, binds TRE-1 and mediates Tax association with, and transactivation of, the viral promoter. These activities depend on DNA sequences that flank the core CRE. Although CREs are found in a variety of cellular promoters, cellular CREs vary in sequence from TRE-1, especially in the flanking regions, and are generally not Tax responsive. The molecular basis for differential Tax responsiveness of viral and cellular CREs has not been determined. Here we demonstrate that the conformation of CREB is influenced by the nucleotide sequence of its DNA-binding element. CREB showed altered sensitivity to V8, chymotrypsin, and trypsin proteases when bound to the HTLV-I TRE-1 element as compared to the rat somatostatin CRE element. The phosphorylation state of CREB did not influence its protease sensitivity on either element. Sequences flanking the core CRE-binding site in each element were found to specify protease sensitivity. Since the TRE-1-flanking sequences also modulate Tax association with CREB, and Tax transactivation of CREB-dependent LTR transcription, these results suggest that CREB conformation may determine the ability of Tax to bind CREB.

Augmentation of human T cell leukaemia virus type I Tax transactivation by octamer binding sites.

The human T cell leukaemia virus type I (HTLV-1) Tax protein is an activator of viral and cellular gene expression. Tax does not bind DNA directly, but does interact with cellular DNA binding proteins. These interactions bring Tax to a specific group of promoters and may help to determine the specificity of Tax transactivation. Previous studies have demonstrated that the activity of Tax, when tethered to a given promoter, is enhanced by the presence of adjacent transcription factor binding sites. To examine the specificity of this augmentation, a series of transcription factor binding sites was tested for the ability to enhance the activity of a Gal-Tax fusion protein. The greatest increase in Gal-Tax activity was observed when an octamer binding site was placed adjacent to the Gal4 binding sites. However, the octamer binding site failed to independently function as a Tax responsive element in the absence of an adjacent Tax-tethering element. Oct-2 was not required for augmentation of Gal-Tax activity as this enhancement was observed in BHK-21 cells, which lack Oct-2. The ability of octamer binding sites to augment transcription was specific for Gal-Tax, as compared to other transactivators. Taken together, these results demonstrate that the degree of Tax transactivation can be influenced by the elemental composition of the target promoter.

Function of the human T-cell leukemia virus type 1 21-base-pair repeats in basal transcription.

The human T-cell leukemia virus type 1 (HTLV-1) promoter contains three copies of an imperfect 21-bp repeat called Tax-responsive element (TRE1). To examine the role of individual TRE1 sequences in basal transcription of the HTLV-1 promoter, site-directed mutations were generated in all possible combinations of one, two, or all three TRE1 elements in the viral long terminal repeat (LTR) and tested in vivo for transcriptional activity. Mutation of the middle TRE1 resulted in the greatest reduction in basal activity. Electrophoretic mobility shift analysis demonstrated that the protein complexes bound to each of the three TRE1 sequences were not identical. The complexes formed with the TATA-distal and middle TRE1s were dependent on the core cyclic AMP response element (CRE) found in all three TRE1s, while the cellular transcription factor Sp1 bound the TATA-proximal TRE1 in a CRE-independent manner. Sp1 binding produced a footprint on the viral LTR which covered the 5' region of the proximal TRE1. Mixing experiments demonstrated that the bindings of CREB and Sp1 to the proximal TRE1 were mutually exclusive. Sp1 was able to activate transcription both from the complete LTR and from the proximal TRE1 alone. These studies demonstrate that the TRE1 elements in the HTLV-1 LTR are functionally nonequivalent and suggest that Sp1 can influence HTLV-1 basal transcription.

Cellular transformation by human T-cell leukemia virus type I.

Human T-cell leukemia virus type I (HTLV-I) is an oncogenic retrovirus that was isolated in 1980 from a patient with adult T-cell leukemia. From the numerous experiments using infected patient T-cells, transgenic mice and tissue culture transformation assays, the Tax protein has been determined to be the transforming component of HTLV-I. Tax-mediated transformation is linked to its ability to transcriptionally regulate the expression of cellular genes involved in growth and proliferation. Ultimately, unregulated and continued activation of these important growth modulating genes by Tax leads to transformation.

Control of cAMP-regulated enhancers by the viral transactivator Tax through CREB and the co-activator CBP.

The Tax protein of human T-lymphotropic virus (HTLV)-1 activates expression of the HTLV-1 long terminal repeat through a DNA element that resembles the cellular cyclic AMP-regulated enhancer (CRE). Tax contains a transcriptional activation domain, but its ability to activate gene expression depends on interactions with cellular CRE-binding proteins such as CREB. Whether Tax can activate the expression of cellular CRE-containing genes has been controversial. Here we show that Tax can activate both the HTLV-1 and consensus cellular CREs, and propose that this activation may occur through mechanisms that are differentially dependent on CREB phosphorylation. Tax not only increases the binding of CREB to the viral CRE but also recruits the transcriptional co-activator CBP in a manner independent of CREB phosphorylation. In contrast, association of Tax with the cellular CRE occurs through CBP which, in turn, is recruited only in the presence of phosphorylated CREB.

Twenty-one base pair repeat elements influence the ability of a Gal4-Tax fusion protein to transactivate the HTLV-I long terminal repeat.

The Tax1 protein of the human T-cell leukemia virus (HTLV-I) is a 40-kDa positive transactivator of viral gene expression. Tax1 does not bind directly to DNA, but associates indirectly with DNA via cellular transcription factors. To further investigate the activation of HTLV-I transcription by Tax1, a chimeric protein containing Tax1 fused to the DNA binding domain of Gal4 was created (Gal4-Tax). HTLV-I long terminal repeat (LTR) reporter plasmids were constructed in which specific Tax1 responsive elements were replaced with Gal4 binding sites. Cotransfection of Gal4-Tax or Tax1 with HTLV-I LTR reporter constructs containing Gal4 binding sites demonstrated that Gal4 sequences were necessary but not sufficient for maximal activation of the promoter by Gal4-Tax. Sequences surrounding the Gal4 binding sites were important in determining the level of Gal4-Tax activation. Association of Gal4-Tax with promoters which contained six Gal4 binding sites, but which lacked flanking LTR sequences, were weakly transactivated by Gal4-Tax (sevenfold). In contrast, LTR-CAT reporter constructs containing three Gal4 binding sites flanked by two 21 base pair repeat elements demonstrated a ninefold greater response to Gal4-Tax. These results suggest that cellular transcription factors, which bind the 21 base pair repeat elements, influence the ability of Tax1 to function as a transactivator. Furthermore, this effect is not fully explained by the ability of these factors to physically direct Tax1 to the LTR.