The TATA-dependent and TATA-independent promoters of the Drosophila melanogaster actin 5C-encoding gene

Promoter specificity mediates the independent regulation of neighboring genes

Although enhancers can exert their influence over great distances, their effect is generally limited to a single gene. To discern the mechanism by which this constraint can he mediated, we have studied three neighboring Drosophila genes: decapentaplegic (dpp), SLY1 homologous (Slh) and out at first (oaf). Several dpp enhancers are positioned close to Slh and oaf, and yet these genes are unaffected by the dpp elements. However, when a transposon is located within the oaf gene, the dpp enhancers activate the more distant transposon promoters while still ignoring the closer Slh and oaf start sites. To test whether this promoter specificity accounts for the regulatory autonomy normally found for the three genes, we used in vivo gene targeting to replace the oaf promoter with a dpp-compatible one in an otherwise normal chromosome. Strikingly, this chimeric gene is now activated by the dpp enhancers. Thus, the properties of the promoters themselves are sufficient to mediate the autonomous regulation of genes in this region.

A unique role for enhancers is revealed during early mouse development

Transcription and replication of genes in mammalian cells always requires a promoter or replication origin, respectively, but the ability of enhancers to stimulate these regulatory elements and the interactions that mediate this stimulation are developmentally acquired. The primary function of enhancers is to prevent repression, which appears to result from particular components of chromatin structure. Factors responsible for this repression are present in the maternal nucleus of oocytes and its descendant, the maternal pronucleus of mouse 1-cell embryos and in mouse 2-cell embryos, but are absent in the paternal pronucleus. Thus, enhancers are not needed to achieve efficient transcription and replication in paternal pronuclei. However, enhancers, even in the presence of their specific activation protein, are inactive prior to formation of a 2-cell embryo, suggesting that a coactivator essential for enhancer function is not available until zygotic gene expression begins. Furthermore, enhancer stimulation of transcription appears to be mediated through a promoter transcription factor, but this interaction can change as cells undergo differentiation, switching from a TATA-box independent to a TATA-box dependent mode.

TATA-dependent enhancer stimulation of promoter activity in mice is developmentally acquired

Herpes simplex virus (HSV) thymidine kinase (tk) promoter activity depends on four transcription factor binding sites, one of which is a TATA box sequence, and the presence of either a cis-acting enhancer sequence or a transactivator protein. Studies presented here show that this TATA box was required for promoter activity only after cells began to differentiate and then only when promoter activity was stimulated by either an enhancer or a transactivator. When the HSV tk promoter was utilized by mouse embryos from the one-cell to eight-cell stage of development or by undifferentiated mouse embryonic stem cells, disruption of the HSV tk TATA box by site-specific mutations did not reduce promoter activity. This was true even when HSV tk promoter activity was stimulated strongly by either the embryo-responsive polyomavirus F101 enhancer or its natural transactivator, the HSV ICP4 gene product. However, stimulated expression was dependent on a distal Sp1 DNA binding site. Similarly, disruption of the TATA box did not reduce tk promoter activity in primary mouse embryonic fibroblasts or in immortalized 3T3 mouse fibroblasts; in fact, promoter activity was increased up to 2.6-fold. However, in these differentiated cells, stimulation of the HSV tk promoter by either the F101 enhancer or ICP4 protein required the TATA box. HSV tk promoter activity also was dependent on its TATA box in the mouse oocyte, a terminally differentiated cell with an endogenous transactivating activity. These results reveal that the need for a TATA box is developmentally acquired and depends on at least two parameters: the differentiated state of the cell and stimulation of the promoter by either an enhancer or a transactivator.

TATA-dependent enhancer stimulation of promoter activity in mice is developmentally acquired

Herpes simplex virus (HSV) thymidine kinase (tk) promoter activity depends on four transcription factor binding sites, one of which is a TATA box sequence, and the presence of either a cis-acting enhancer sequence or a transactivator protein. Studies presented here show that this TATA box was required for promoter activity only after cells began to differentiate and then only when promoter activity was stimulated by either an enhancer or a transactivator. When the HSV tk promoter was utilized by mouse embryos from the one-cell to eight-cell stage of development or by undifferentiated mouse embryonic stem cells, disruption of the HSV tk TATA box by site-specific mutations did not reduce promoter activity. This was true even when HSV tk promoter activity was stimulated strongly by either the embryo-responsive polyomavirus F101 enhancer or its natural transactivator, the HSV ICP4 gene product. However, stimulated expression was dependent on a distal Sp1 DNA binding site. Similarly, disruption of the TATA box did not reduce tk promoter activity in primary mouse embryonic fibroblasts or in immortalized 3T3 mouse fibroblasts; in fact, promoter activity was increased up to 2.6-fold. However, in these differentiated cells, stimulation of the HSV tk promoter by either the F101 enhancer or ICP4 protein required the TATA box. HSV tk promoter activity also was dependent on its TATA box in the mouse oocyte, a terminally differentiated cell with an endogenous transactivating activity. These results reveal that the need for a TATA box is developmentally acquired and depends on at least two parameters: the differentiated state of the cell and stimulation of the promoter by either an enhancer or a transactivator.