Functional organization of the yeast SAGA complex: distinct components involved in structural integrity, nucleosome acetylation, and TATA-binding protein interaction.

SAGA, a recently described protein complex in Saccharomyces cerevisiae, is important for transcription in vivo and possesses histone acetylation function. Here we report both biochemical and genetic analyses of members of three classes of transcription regulatory factors contained within the SAGA complex. We demonstrate a correlation between the phenotypic severity of SAGA mutants and SAGA structural integrity. Specifically, null mutations in the Gcn5/Ada2/Ada3 or Spt3/Spt8 classes cause moderate phenotypes and subtle structural alterations, while mutations in a third subgroup, Spt7/Spt20, as well as Ada1, disrupt the complex and cause severe phenotypes. Interestingly, double mutants (gcn5Delta spt3Delta and gcn5Delta spt8Delta) causing loss of a member of each of the moderate classes have severe phenotypes, similar to spt7Delta, spt20Delta, or ada1Delta mutants. In addition, we have investigated biochemical functions suggested by the moderate phenotypic classes and find that first, normal nucleosomal acetylation by SAGA requires a specific domain of Gcn5, termed the bromodomain. Deletion of this domain also causes specific transcriptional defects at the HIS3 promoter in vivo. Second, SAGA interacts with TBP, the TATA-binding protein, and this interaction requires Spt8 in vitro. Overall, our data demonstrate that SAGA harbors multiple, distinct transcription-related functions, including direct TBP interaction and nucleosomal histone acetylation. Loss of either of these causes slight impairment in vivo, but loss of both is highly detrimental to growth and transcription.

The SAGA unfolds: convergence of transcription regulators in chromatin-modifying complexes.

Several previously characterized transcriptional adaptors and coactivators are now known to be histone acetyltransferases (HATs). Recent studies in Saccharomyces cerevisiae indicate that the Gcn5p HAT exists in large complexes containing several phenotypic classes of transcription factors. Genetic and biochemical studies of these transcription factors and their functions within HAT complexes suggest that acetylation of histones is one function of an integrated system of modular activities. These activities include interaction with activators, histone acetylation and interaction with basal factors. Coordination of these functions may well be an important component of gene activation in vivo.

Identification of a Tus protein segment that photo-cross-links with TerB DNA and elucidation of the role of certain thymine methyl groups in the Tus-TerB complex using halogenated uracil analogues.

Six potential hydrophobic sites of the Tus-TerB complex were analyzed using bromodeoxy-uridine and iododeoxyuridine as isosteric analogues of thymine. Analogues were incorporated at individual sites, and dissociation rates were measured in 150 mM potassium glutamate, pH 8.0, using a nitrocellulose filter assay. These halogenated analogues serve as a probe of the environment in which they reside. Our measurement revealed at least two types of responses. Three sites showed increases in stability with the introduction of the bromo and iodo derivatives. The enhanced stability is proposed to result from polar or charged molecules in the vicinity of the halogenated analogues through dipole-dipole, dipole-ion, or dipole-induced dipole interactions. The other three sites exhibited the opposite trend, being destabilized by the introduction of these analogues. The destabilizing effects are attributed to a hydrophobic environment which cannot accommodate polar molecules. The photoreactivity of these analogues was utilized to specifically cross-link the Tus protein and TerB DNA. Using the substitution of bromodeoxyuridine at position 8 in the TerB DNA, Tus protein was covalently attached to the DNA, and by trypsin digestion a fragment of Tus was isolated. Sequencing of the peptide fragment revealed a segment that matched the amino acid composition from 122-139 of the Tus protein.

Using modified nucleotides to map the DNA determinants of the Tus-TerB complex, the protein-DNA interaction associated with termination of replication in Escherichia coli.

A series of modified nucleotides was used to map the hydrogen-bonding and hydrophobic sites of the TerB DNA required for Tus interaction. Each of four consensus guanine residues in the TerB-binding site was replaced by 7-deazaguanine, 2-aminopurine, or inosine nucleobase analogues, and each thymine by a uracil analogue. The observable equilibrium dissociation constant for the Tus protein-TerB DNA complex was measured at pH 7.5, 25 degrees C, and 150 mM potassium glutamate using a competition binding method. Substitutions made at position 10 with a 7-deazaguanine, 2-aminopurine, or inosine analogue had a large effect on the stability of the complex, approximately +3 kcal/mol in each case. Substitutions made at positions 13 and 17 had a varied response. For uracil substitutions, potential hydrophobic sites were identified at six positions in the TerB DNA. The energetic penalty for the removal of a single methyl group ranged between +1 and +2 kcal/mol. Rate dissociation measurements agree with these results. Overall, major and minor groove determinants are required for binding. An unusual result was that the conserved nucleotide at position 6 did not significantly affect in vitro binding of the complex.