Direct role for the Rpd3 complex in transcriptional induction of the anaerobic DAN/TIR genes in yeast.

Saccharomyces cerevisiae adapts to hypoxia by expressing a large group of "anaerobic" genes. Among these, the eight DAN/TIR genes are regulated by the repressors Rox1 and Mot3 and the activator Upc2/Mox4. In attempting to identify factors recruited by the DNA binding repressor Mot3 to enhance repression of the DAN/TIR genes, we found that the histone deacetylase and global repressor complex, Rpd3-Sin3-Sap30, was not required for repression. Strikingly, the complex was instead required for activation. In addition, the histone H3 and H4 amino termini, which are targets of Rpd3, were also required for DAN1 expression. Epistasis tests demonstrated that the Rpd3 complex is not required in the absence of the repressor Mot3. Furthermore, the Rpd3 complex was required for normal function and stable binding of the activator Upc2 at the DAN1 promoter. Moreover, the Swi/Snf chromatin remodeling complex was strongly required for activation of DAN1, and chromatin immunoprecipitation analysis showed an Rpd3-dependent reduction in DAN1 promoter-associated nucleosomes upon induction. Taken together, these data provide evidence that during anaerobiosis, the Rpd3 complex acts at the DAN1 promoter to antagonize the chromatin-mediated repression caused by Mot3 and Rox1 and that chromatin remodeling by Swi/Snf is necessary for normal expression.

Restriction digestion monitors facilitate plasmid construction and PCR cloning.

Plasmid construction by "forced" or "directional" ligation of fragments digested with two different restriction enzymes is highly efficient, except when inhibited digestion of one site favors vector recircularization. Such failures often result because incomplete double digestion is undetected in vector polylinkers or at terminal cloning sites on a PCR fragment. To test cleavage efficiency indirectly, a "monitor" plasmid is added to the digest. In a suitable monitor, the two test sites are separated by enough DNA (approximately 20% of full length) to distinguish the double digest from the failed single digest. To make this applicable to combinations of 32 popular cloning enzymes, we constructed a set of 4 monitors (pDM1, pDM2, pDM3, and pDM4). Each contains three polylinkers separated by stuffer segments of approximately 1 kb. The 32 sites are distributed in the polylinkers such that at least one plasmid in the set is diagnostic for each enzyme pair. The set is designed to be extended to up to 81 sites. A linearized version of the monitor allows for the determination of which of the two enzymes has failed in an incomplete double digest and is also useful when the target DNA is close to the size of the pDM backbone. The plasmids also serve as versatile self-monitoring cloning vectors for any site combination.

Synergistic repression of anaerobic genes by Mot3 and Rox1 in Saccharomyces cerevisiae.

Two groups of anaerobic genes (genes induced in anaerobic cells and repressed in aerobic cells) are negatively regulated by heme, a metabolite present only in aerobic cells. Members of both groups, the hypoxic genes and the DAN/TIR/ERG genes, are jointly repressed under aerobic conditions by two factors. One is Rox1, an HMG protein, and the second, originally designated Rox7, is shown here to be Mot3, a global C2H2 zinc finger regulator. Repression of anaerobic genes results from co-induction of Mot3 and Rox1 in aerobic cells. Repressor synthesis is triggered by heme, which de-represses a mechanism controlling expression of both MOT3 and ROX1 in anaerobic cells; it includes Hap1, Tup1, Ssn6 and a fourth unidentified factor. The constitutive expression of various anaerobic genes in aerobic rox1Delta or mot3Delta cells directly implies that neither factor can repress by itself at endogenous levels and that stringent aerobic repression results from the concerted action of both. Mot3 and Rox1 are not essential components of a single complex, since each can repress independently in the absence of the other, when artificially induced at high levels. Moreover, the two repression mechanisms appear to be distinct: as shown here repression of ANB1 by Rox1 alone requires Tup1-Ssn6, whereas repression by Mot3 does not. Though artificially high levels of either factor can repress well, the absolute efficiency observed in normal cells when both are present-at much lower levels-demonstrates a novel inhibitory synergy. Evidently, expression levels for the two mutually dependent repressors are calibrated to permit a range of variation in basal aerobic expression at different promoters with differing operator site combinations.