The DAL7 promoter consists of multiple elements that cooperatively mediate regulation of the gene''s expression.

Expression of the allantoin system genes in Saccharomyces cerevisiae is induced by allophanate or its analog, oxalurate. This work provides evidence for the involvement of distinct types of cis-acting elements in the induction process. The first element was found to have the properties of an upstream activation sequence (UAS). This element was localized to a 16-base-pair (bp) DNA fragment containing a short 5-bp sequence that occurred repeatedly in the upstream region of DAL7. When present in two or more copies, the 16-bp fragment supported high-level beta-galactosidase production in a CYC1-lacZ expression vector; there was, however, no response to the allantoin pathway inducer. The second element had the properties of a negatively acting element or upstream repression sequence (URS). This element was localized to a 16-bp DNA fragment containing an 8-bp sequence that was repeated four times in the upstream region of DAL7. A fragment containing the 8-bp repeated sequence placed adjacent to the UAS-containing fragment mediated inhibition of the ability of the UAS to support lacZ expression regardless of whether inducer was present. A third element, designated an upstream induction sequence (UIS), was required for response to inducer. The UIS was localized to a small DNA fragment containing an approximately 10-bp sequence that was repeated twice in the upstream region of DAL7. When a fragment containing the 10-bp repeated sequence was placed adjacent to these UAS and URS elements, the construction (UIS-UAS-URS) supported normal oxalurate-mediated induction of beta-galactosidase synthesis. These data are consistent with the suggestion that multiple, cis-acting elements participate in the induction process.     

Construction of chimaeric promoter regions by exchange of the upstream regulatory sequences from fdhF and nif genes

Hybrid 5' regulatory regions were constructed in which the upstream activator sequence (UAS) and promoter of various nif genes were exchanged with the upstream regulatory sequence (URS) of the fdhF gene from Escherichia coli. They were analysed for their regulatory response under different growth conditions with the aid of fdhF'-'lacZ or nif'-'lacZ fusions. Placement of the UAS from the Bradyrhizobium japonicum nifH gene in front of the spacer (DNA region between URS and promoter) plus promoter from fdhF renders fdhF expression activatable by the Klebsiella pneumoniae NIFA protein, both under aerobic and anaerobic conditions. This excludes the possibility that the spacer of the fdhF5' flanking region contains a site recognized by a putative oxygen- or nitrate-responsive repressor. There was also considerable activation by NIFA of fdhF expression in a construct lacking the nifH UAS but containing the fdhF spacer plus promoter. Further experimental evidence suggests that this reflects a direct interaction between NIFA and RNA polymerase at the ntrA-dependent promoter. A second set of hybrid constructs in which the URS from fdhF (E. coli) was placed in front of the nifD spacer plus promoter from B. japonicum or in front of the K. pneumoniae nifH, nifU, nifB spacers and promoters, delivered inactive constructs in the case of the nifD, nifU and nifB genes. However, a nifH'-'lacZ fusion preceded by its own spacer and promoter plus the foreign fdhF URS displayed all the regulatory characteristics of fdhF expression, i.e. anaerobic induction with formate and repression by oxygen and nitrate. Although it is not known why only one out of the four nif promoters could be activated by the fdhF URS, this result nevertheless demonstrates that the various regulatory stimuli affecting expression of fdhF in E. coli have their target at the upstream regulatory sequence.     

The DAL82 protein of Saccharomyces cerevisiae binds to the DAL upstream induction sequence (UIS).

Expression of the DAL2, DAL4, DAL7, DUR1,2, and DUR3 genes in S. cerevisiae is induced by allophanate, the last intermediate in the allantoin catabolic pathway. Analysis of the DAL7 promoter identified a dodecanucleotide, the DAL7 UIS, which was required for inducer-responsiveness. Operation of the DAL7 UIS required functional DAL81 and DAL82 gene products. Since the DAL81 product was not an allantoin pathway-specific regulatory factor, the DAL82 product was considered as the more likely candidate to be the DAL UIS binding protein. Using an E. coli expression system, we showed that DAL82 protein specifically bound to wild type but not mutant DAL UIS sequences. DNA fragments containing DAL UIS elements derived from various DAL gene promoters bound DAL82 protein with different affinities which correlate with the degree of inducer-responsiveness the genes displayed.     

Bipartite structure of an early meiotic upstream activation sequence from Saccharomyces cerevisiae.

Diploid a/alpha Saccharomyces cerevisiae cells cease mitotic growth and enter meiosis in response to starvation. Expression of meiotic genes depends on the IME1 gene product, which accumulates only in meiotic cells. We report here an analysis of the regulatory region of IME2, an IME1-dependent meiotic gene. Deletion and substitution studies identified a 48-bp IME1-dependent upstream activation sequence (UAS). Activity of the UAS also requires the RIM11, RIM15, and RIM16 gene products, which are required for expression of the chromosomal IME2 promoter and for meiosis. Through a selection for suppressors that permit UAS activity in an ime1 deletion mutant, we identified recessive mutations in three genes, SIN3 (also called RPD1, UME4, and SDI1), RPD3, and UME6 (also called CAR80), that were previously known as negative regulators of other early meiotic genes. Mutational analysis of the IME2 UAS reveals two critical sequence elements: a G+C-rich sequence (called URS1), previously identified at many meiotic genes, and a newly described element, the T4C site, that we found at a subset of meiotic genes. In agreement with prior studies, URS1 mutations lead to elevated IME2 UAS activity in the absence of IME1. However, the URS1 mutations prevent any further stimulation of UAS activity by IME1. Repression through URS1 has been shown to require the UME6 gene product. We find that activation of the IME2 UAS by IME1 also requires the UME6 gene product. Thus, UME6 and the URS1 site both have dual negative and positive roles at the IME2 UAS. We propose that IME1 modifies UME6 to convert it from a negulator to a positive Regulor.