Structure transcription defined

Figure 9.12 Schematic diagram of the structure of the heterodimeric yeast transcription factor Mat a2-Mat al bound to DNA. Both Mat o2 and Mat al are homeodomains containing the helix-turn-helix motif. The first helix in this motif is colored blue and the second, the recognition helix, is red. (a) The assumed structure of the Mat al homeodomain in the absence of DNA, based on Its sequence similarity to other homeodomains of known structure, (b) The structure of the Mat o2 homeodomain. The C-terminal tail (dotted) is flexible in the monomer and has no defined structure, (c) The structure of the Mat a 1-Mat a2-DNA complex. The C-terminal domain of Mat a2 (yellow) folds into an a helix (4) in the complex and interacts with the first two helices of Mat a2, to form a heterodimer that binds to DNA. (Adapted from B.J. Andrews and M.S. Donoviel, Science 270 251-253, 1995.)...

The N-terminal A/B region whose structure has not yet been defined contains a transcriptional activation function, referred to as activation function 1 (AF-1), which can operate autonomously. The length and sequence of the A/B region in the different NRs are highly variable, revealing a very weak evolutionary... 

Because of the preceding properties, our profile procedure appears to produce highly sensitive and specific common pattern representations from limited numbers of defining sequences compared with other current methods (Figs. 5 and 7). This was shown by the construction of such profiles from more than 50 completely unrelated functional families. In more than 90% of the families, the sensitivity and specificity are more than 98%. This is also supported by the repeated sampling study of the complex bacterial transcription initiation factors. Finally, these methods allow for the localized recognition of entire domains within multidomain structures, as seen in Fig. 6. 

Transcription initiation in procaryotes is controlled via promoters and regulatory DNA sequences located near the promoter. The role of the promoter is to provide a defined association site for the RNA polymerase and to correctly orient it. The binding of the RNA polymerase to its promoter is controlled by the sigma factor, a component of the RNA polymerase holoenzyme. The sigma factor selects which genes are to be transcribed by specifically recognizing the promoter sequence and structure and by allowing the RNA polymerase to form a transcription-competent complex at the transcription start site. 

The TATA box and/or an initiation sequence are structural elements which define a minimal promoter from which in vitro transcription can be initiated. A classical TATA box is often, though not always, ca. 30bp from the transcription start site. The initiation sequence includes sequences in the immediate vicinity of the transcription start site. The TATA box and initiation sequence are sufficient for the formation of a basal transcription apparatus composed of general initiation factors for transcription and RNA polymerase II (see Fig. 1.31). 

General transcription initiation factors TFIIB, TFIIE, TFIIF and TFIIH have been identified as components of the RNA polymerase 11 holoenzyme of yeast. Various forms of the yeast holoenzyme contain further proteins, known as mediators or SRB proteins (SRB, suppressor of RNA polymerase B). The mediators fimction as coactivators (see 1.4.3.2). The holoenzyme is difficult to define structurally because the proteins accessory to the core enzyme (see table 1) may not be permanently associated with RNA polymerase II. 

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