The human cytomegalovirus 80-kilodalton but not the 72-kilodalton immediate-early protein transactivates heterologous promoters in a TATA box-dependent mechanism and interacts directly with TFIID.

We have asked how the human cytomegalovirus major immediate-early 1 (IE1) and 2 (IE2) proteins act to transactivate heterologous cellular and viral promoters. Here we show that transactivation of the human immunodeficiency virus long terminal repeat and the 70,000-molecular-weight heat shock protein (hsp70) promoter by IE1 is TATA box independent and that the IE1 protein does not interact directly with the TATA box-binding factor TFIID. Conversely, transactivation of these promoters by IE2 is TATA box dependent and a direct interaction between IE2 and TFIID occurs, suggesting that IE2 transactivation is mediated through interaction with TFIID.     

Involvement of ATP in the nuclear and nucleolar functions of the 70 kd heat shock protein.

The major heat shock protein, hsp70, is an ATP-binding protein which is synthesized in very large amounts in response to stress. In unstressed, or recovered, mammalian cells it is found in both nucleus and cytoplasm. Under these conditions, its interaction with nuclei is weak, and it is readily released from them upon lysis of cells in isotonic buffer. After heat shock, hsp70 binds tightly first to some nuclear component(s) and then to nucleoli. It can be released from these binding sites rapidly and specifically in vitro by as little as 1 microM ATP, but not by non-hydrolysable ATP analogues. Studies of hsp70 deletion mutations show that the ability of mutants to be released by ATP correlates with their ability to migrate to heat-shocked nucleoli and aid their repair in vivo. We propose a model in which ATP-driven cycles of binding and release of hsp70 help to solubilize aggregates of proteins or RNPs that form after heat shock. Cells also contain proteins related to hsp70 that are synthesized in the absence of stress. The most abundant of these shows the same behaviour as hsp70 after heat shock, and thus may perform a related function in both normal and stressed cells.     

Interference between Proteins Hap46 and Hop/p60, Which Bind to Different Domains of the Molecular Chaperone hsp70/hsc70

Several structurally divergent proteins associate with molecular chaperones of the 70-kDa heat shock protein (hsp70) family and modulate their activities. We investigated the cofactors Hap46 and Hop/p60 and the effects of their binding to mammalian hsp70 and the cognate form hsc70. Hap46 associates with the amino-terminal ATP binding domain and stimulates ATP binding two- to threefold but inhibits binding of misfolded protein substrate to hsc70 and reactivation of thermally denatured luciferase in an hsc70-dependent refolding system. By contrast, Hop/p60 interacts with a portion of the carboxy-terminal domain of hsp70s, which is distinct from that involved in the binding of misfolded proteins. Thus, Hop/p60 and substrate proteins can form ternary complexes with hsc70. Hop/p60 exerts no effect on ATP and substrate binding but nevertheless interferes with protein refolding. Even though there is no direct interaction between these accessory proteins, Hap46 inhibits the binding of Hop/p60 to hsc70 but Hop/p60 does not inhibit the binding of Hap46 to hsc70. As judged from respective deletions, the amino-terminal portions of Hap46 and Hop/p60 are involved in this interference. These data suggest steric hindrance between Hap46 and Hop/p60 during interaction with distantly located binding sites on hsp70s. Thus, not only do the major domains of hsp70 chaperones communicate with each other, but cofactors interacting with these domains affect each other as well.     

Naturally occurring transposable elements disrupt hsp70 promoter function in Drosophila melanogaster

Naturally occurring transposable element (TE) insertions that disrupt Drosophila promoters are correlated with modified promoter function and are posited to play a significant role in regulatory evolution, but their phenotypes have not been established directly. To establish the functional consequences of these TE insertions, we created constructs with either TE-bearing or TE-lacking hsp70 promoters fused to a luciferase reporter gene and assayed luciferase luminescence in transiently transfected Drosophila cells. Each of the four TEs reduces luciferase signal after heat shock and heat inducibility of the hsp70 promoter. To test if the differences in hsp70 promoter activity are TE-sequence dependent, we replaced each of the TEs with multiple intergenic sequences of equal length. These replacement insertions similarly reduced luciferase signal, suggesting that the TEs affect hsp70 promoter function by altering promoter architecture. These results are consistent with differences in Hsp70 expression levels, inducible thermotolerance, and fecundity previously associated with the TEs. That two different varieties of TEs in two different hsp70 genes have common effects suggests that TE insertion represents a general mechanism through which selection manipulates hsp70 gene expression.