Structural studies of Ets-1/Pax5 complex formation on DNA

Pax5 regulates the B cell-specific expression of the mb-1 gene together with members of the Ets family of transcriptional activators. The Ets proteins on their own bind poorly to the Pax5/Ets binding site, but can be recruited to the site by cooperative interactions with Pax5. The structure of the ETS domain of Ets-1 and the paired domain of Pax5 bound to DNA reveals the molecular details of the selective recruitment of different Ets proteins by Pax5. Comparison with structures of Ets-1 alone bound to both high- and low-affinity DNA sites reveals that Pax5 alters the Ets-1 contacts with DNA. The ability of one protein to alter the DNA sequence-specific contacts of another provides a general mechanism for combinatorial regulation of transcription.

Recognition of specific DNA sequences

Proteins that recognize specific DNA sequences play a central role in the regulation of transcription. The tremendous increase in structural information on protein-DNA complexes has uncovered a remarkable structural diversity in DNA binding folds, while at the same time revealing common themes in binding to target sites in the genome.

Molecular insights into polyubiquitin chain assembly: crystal structure of the Mms2/Ubc13 heterodimer

While the signaling properties of ubiquitin depend on the topology of polyubiquitin chains, little is known concerning the molecular basis of specificity in chain assembly and recognition. UEV/Ubc complexes have been implicated in the assembly of Lys63-linked polyubiquitin chains that act as a novel signal in postreplicative DNA repair and I kappa B alpha kinase activation. The crystal structure of the Mms2/Ubc13 heterodimer shows the active site of Ubc13 at the intersection of two channels that are potential binding sites for the two substrate ubiquitins. Mutations that destabilize the heterodimer interface confer a marked UV sensitivity, providing direct evidence that the intact heterodimer is necessary for DNA repair. Selective mutations in the channels suggest a molecular model for specificity in the assembly of Lys63-linked polyubiquitin signals.

Characterization of the oligomeric states of wild type and mutant AraC

AraC regulates transcription of the Escherichia coli arabinose operon, binding tandem DNA half-sites in the presence of arabinose and widely spaced half-sites in the absence of arabinose. In the structure of the AraC N-terminal dimerization domain with bound arabinose, the protein dimerizes via an antiparallel coiled-coil interface. The absence of bound ligand opens a second, beta-barrel interaction interface that also mediates interactions between unliganded AraC dimers in the crystal. The larger buried surface area of the beta-barrel interface, as compared with the coiled-coil interface, raised the possibility that protein-protein interactions mediated by the beta-barrel might play a role in ligand-mediated modulation of AraC DNA binding activity. For the crystallographically observed beta-barrel interaction to play a role in the cell, dimerization via this interface in the absence of arabinose would be predicted to be at least as energetically favorable as dimerization via the coiled-coil interface. In the study presented here, we use analytical ultracentrifugation to determine the oligomeric state of the AraC dimerization domain in the presence and absence of arabinose. Dimerization of the unliganded protein via the beta-barrel interface in the absence of interactions mediated by the coiled-coil interface is assayed using a mutant AraC protein with a disrupted coiled-coil interface. The results of these studies indicate that dimerization via the beta-barrel interface is substantially weaker than dimerization via the coiled-coil interface, indicating that the crystallographically observed beta-barrel interaction is not relevant to in vivo function.

Structure of the C-terminal domain of Tup1, a corepressor of transcription in yeast

The Tup1-Ssn6 corepressor complex regulates the expression of several sets of genes, including genes that specify mating type in the yeast Saccharomyces cerevisiae. Repression of mating-type genes occurs when Tup1-Ssn6 is brought to the DNA by the Matalpha2 DNA-binding protein and assembled upstream of a- and haploid-specific genes. We have determined the 2.3 A X-ray crystal structure of the C-terminal domain of Tup1 (accesion No. 1ERJ), a 43 kDa fragment that contains seven copies of the WD40 sequence motif and binds to the Matalpha2 protein. Moreover, this portion of the protein can partially substitute for full-length Tup1 in bringing about transcriptional repression. The structure reveals a seven-bladed beta propeller with an N-terminal subdomain that is anchored to the side of the propeller and extends the beta sheet of one of the blades. Point mutations in Tup1 that specifically affect the Tup1-Matalpha2 interaction cluster on one surface of the propeller. We identified regions of Tup1 that are conserved among the fungal Tup1 homologs and may be important in protein-protein interactions with additional components of the Tup1-mediated repression pathways.

A phylogenetically conserved NAD+-dependent protein deacetylase activity in the Sir2 protein family

The yeast Sir2 protein, required for transcriptional silencing, has an NAD(+)-dependent histone deacetylase (HDA) activity. Yeast extracts contain a NAD(+)-dependent HDA activity that is eliminated in a yeast strain from which SIR2 and its four homologs have been deleted. This HDA activity is also displayed by purified yeast Sir2p and homologous Archaeal, eubacterial, and human proteins, and depends completely on NAD(+) in all species tested. The yeast NPT1 gene, encoding an important NAD(+) synthesis enzyme, is required for rDNA and telomeric silencing and contributes to silencing of the HM loci. Null mutants in this gene have significantly reduced intracellular NAD(+) concentrations and have phenotypes similar to sir2 null mutants. Surprisingly, yeast from which all five SIR2 homologs have been deleted have relatively normal bulk histone acetylation levels. The evolutionary conservation of this regulated activity suggests that the Sir2 protein family represents a set of effector proteins in an evolutionarily conserved signal transduction pathway that monitors cellular energy and redox states.

Characterization of the N-terminal domain of the yeast transcriptional repressor Tup1. Proposal for an association model of the repressor complex Tup1 x Ssn6

The yeast Tup1 and Ssn6 proteins form a transcriptional repression complex that represses transcription of a broad array of genes. It has been shown that the N-terminal domain of the Tup1 protein interacts with a region of the Ssn6 protein that consists of 10 tandem copies of a tetratricopeptide motif. In this work, we use a surface plasmon resonance assay to measure the affinity of the N-terminal domain of Tup1 for a minimal 3-TPR domain of Saccharomyces cerevisiae Ssn6 that is sufficient for binding to Tup1. This domain of Ssn6 binds with comparable affinity to S. cerevisiae and Candida albicans Tup1, but with 100-fold lower affinity to Tup1 protein containing a point mutation that gives rise to a defect in repression in vivo. Results from studies using analytical ultracentrifugation, CD spectroscopy, limited proteolysis, and (1)H NMR show that this domain of Tup1 is primarily alpha-helical and forms a stable tetramer that is highly nonglobular in shape. X-ray diffraction recorded from poorly ordered crystals of the Tup1 tetramerization domain contains fiber diffraction typical of a coiled coil. Our results are used to propose a model for the structure of the N-terminal domain of Tup1 and its interaction with the Ssn6 protein.

NMR studies of the pbx1 TALE homeodomain protein free in solution and bound to DNA: proposal for a mechanism of HoxB1-Pbx1-DNA complex assembly

The Hox homeodomain proteins are transcription factors involved in developmental regulation. Many of the vertebrate Hox proteins bind DNA cooperatively with the Pbx1 homeodomain protein. The crystal structure of a human HoxB1-Pbx1-DNA ternary complex revealed that interactions between the two proteins are mediated by the HoxB1 hexapeptide, which inserts into a hydrophobic pocket in Pbx1. It was also found that the Pbx1 DNA-binding domain is larger than the canonical three-helix homeodomain, containing an additional alpha-helix that is joined to the C terminus of the homeodomain by a turn of 310helix. These extra C-terminal residues had previously been shown to augment the cooperative interaction of Pbx1 with Hox partners, as well as enhancing the DNA binding of monomeric Pbx1. In order to characterize the role of the fourth Pbx1 helix in greater detail, we have examined the backbone structure of the enlarged Pbx1 DNA-binding domain in solution by(1)H,(15)N and(13)C multidimensional NMR spectroscopy. Our results show that the additional alpha-helix of Pbx1 is unfolded when the protein is free in solution and that its folding is triggered by binding of Pbx1 to DNA. In contrast, no change in conformation is observed upon mixing the HoxB1 protein with Pbx1 in the absence of DNA. This study suggests a model for the assembly of a stable HoxB1-Pbx1-DNA ternary complex.

Multiprotein-DNA complexes in transcriptional regulation

Transcription in eukaryotes is frequently regulated by a mechanism termed combinatorial control, whereby several different proteins must bind DNA in concert to achieve appropriate regulation of the downstream gene. X-ray crystallographic studies of multiprotein complexes bound to DNA have been carried out to investigate the molecular determinants of complex assembly and DNA binding. This work has provided important insights into the specific protein-protein and protein-DNA interactions that govern the assembly of multiprotein regulatory complexes. The results of these studies are reviewed here, and the general insights into the mechanism of combinatorial gene regulation are discussed.

Structure of a HoxB1-Pbx1 heterodimer bound to DNA: role of the hexapeptide and a fourth homeodomain helix in complex formation

Hox homeodomain proteins are developmental regulators that determine body plan in a variety of organisms. A majority of the vertebrate Hox proteins bind DNA as heterodimers with the Pbx1 homeodomain protein. We report here the 2.35 A structure of a ternary complex containing a human HoxB1-Pbx1 heterodimer bound to DNA. Heterodimer contacts are mediated by the hexapeptide of HoxB1, which binds in a pocket in the Pbx1 protein formed in part by a three-amino acid insertion in the Pbx1 homeodomain. The Pbx1 DNA-binding domain is larger than the canonical homeodomain, containing an additional alpha helix that appears to contribute to binding of the HoxB1 hexapeptide and to stable binding of Pbx1 to DNA. The structure suggests a model for modulation of Hox DNA binding activity by Pbx1 and related proteins.

Crystal structure of the MATa1/MATalpha2 homeodomain heterodimer in complex with DNA containing an A-tract

The crystal structure of the heterodimer formed by the DNA binding domains of the yeast mating type transcription factors, MATa1 and MATalpha2, bound to a 21 bp DNA fragment has been determined at 2.5 A resolution. The DNA fragment in the present study differs at four central base pairs from the DNA sequence used in the previously studied ternary complex. These base pair changes give rise to a (dA5).(dT5) tract without changing the overall base composition of the DNA. The resulting A-tract occurs near the center of the overall 60 degrees bend in the DNA. Comparison of the two structures shows that the structural details of the DNA bend are maintained despite the DNA sequence changes. Analysis of the A5-tract DNA subfragment shows that it contains a bend toward the minor groove centered at one end of the A-tract. The observed bend is larger than that observed in the crystal structures of A-tracts embedded in uncomplexed DNA, which are straight and have been presumed to be quite rigid. Variation of the central DNA base sequence reverses the two AT base pairs contacted in the minor groove by Arg7 of the alpha2 N-terminal arm without significantly altering the DNA binding affinity of the a1/alpha2 heterodimer. The Arg7 side chain accommodates the sequence change by forming alternate H bond interactions, in agreement with the proposal that minor groove base pair recognition is insensitive to base pair reversal. Furthermore, the minor groove spine of hydration, which stabilizes the narrowed minor groove caused by DNA bending, is conserved in both structures. We also find that many of the water-mediated hydrogen bonds between the a1 and alpha2 homeodomains and the DNA are highly conserved, indicating an important role for water in stabilization of the a1/alpha2-DNA complex.

Combinatorial transcription factors

Combinatorial regulation of eukaryotic transcription is mediated by proteins that associate in a specific manner to form multiprotein DNA-bound complexes. Substantial progress has recently been made towards the understanding of the molecular determinants of the protein-protein and protein-DNA interactions that govern assembly of these complexes. Three-dimensional structures have been determined of the MATalpha2/MCM1-DNA complex, the p50/p65 Rel homology domain heterodimer bound to DNA, the NFAT/Fos-Jun/DNA quaternary complex, and of the GABPalpha/beta ETS domain-ankyrin repeat heterodimer bound to DNA.

The structure of GABPalpha/beta: an ETS domain- ankyrin repeat heterodimer bound to DNA

GA-binding protein (GABP) is a transcriptional regulator composed of two structurally dissimilar subunits. The alpha subunit contains a DNA-binding domain that is a member of the ETS family, whereas the beta subunit contains a series of ankyrin repeats. The crystal structure of a ternary complex containing a GABPalpha/beta ETS domain-ankyrin repeat heterodimer bound to DNA was determined at 2. 15 angstrom resolution. The structure shows how an ETS domain protein can recruit a partner protein using both the ETS domain and a carboxyl-terminal extension and provides a view of an extensive protein-protein interface formed by a set of ankyrin repeats. The structure also reveals how the GABPalpha ETS domain binds to its core GGA DNA-recognition motif.

The 1.6 A crystal structure of the AraC sugar-binding and dimerization domain complexed with D-fucose

The crystal structure of the sugar-binding and dimerization domain of the Escherichia coli gene regulatory protein, AraC, has been determined in complex with the competitive inhibitor D-fucose at pH 5.5 to a resolution of 1.6 A. An in-depth analysis shows that the structural basis for AraC carbohydrate specificity arises from the precise arrangement of hydrogen bond-forming protein side-chains around the bound sugar molecule. van der Waals interactions also contribute to the epimeric and anomeric selectivity of the protein. The methyl group of D-fucose is accommodated by small side-chain movements in the sugar-binding site that result in a slight distortion in the positioning of the amino-terminal arm. A comparison of this structure with the 1.5 A structure of AraC complexed with L-arabinose at neutral pH surprisingly revealed very small structural changes between the two complexes. Based on solution data, we suspect that the low pH used to crystallize the fucose complex affected the structure, and speculate about the nature of the changes between pH 5.5 and neutral pH and their implications for gene regulation by AraC. A comparison with the structurally unrelated E. coli periplasmic sugar-binding proteins reveals that conserved features of carbohydrate recognition are present, despite a complete lack of structural similarity between the two classes of proteins, suggesting convergent evolution of carbohydrate binding.

Structural basis for ligand-regulated oligomerization of AraC

The crystal structure of the arabinose-binding and dimerization domain of the Escherchia coli gene regulatory protein AraC was determined in the presence and absence of L-arabinose. The 1.5 angstrom structure of the arabinose-bound molecule shows that the protein adopts an unusual fold, binding sugar within a beta barrel and completely burying the arabinose with the amino-terminal arm of the protein. Dimer contacts in the presence of arabinose are mediated by an antiparallel coiled-coil. In the 2.8 angstrom structure of the uncomplexed protein, the amino-terminal arm is disordered, uncovering the sugar-binding pocket and allowing it to serve as an oligomerization interface. The ligand-gated oligomerization as seen in AraC provides the basis of a plausible mechanism for modulating the protein's DNA-looping properties.

Homeodomain interactions

Homeodomain proteins play key roles in development and gene regulation in eukaryotes. Past structural studies have focused on the binding of monomeric homeodomains to DNA, but two recent structures have revealed how homeodomains bind DNA as multimers. The structures of the Drosophila Paired homodimer and the yeast a1/alpha2 heterodimer bound to DNA, along with a high-resolution study of a Drosophila eve-DNA complex, have deepened our understanding of how homeodomains locate their DNA targets.

Altered DNA recognition and bending by insertions in the alpha 2 tail of the yeast a1/alpha 2 homeodomain heterodimer

The yeast MAT alpha 2 and MATa1 homeodomain proteins bind cooperatively as a heterodimer to sites upstream of haploid-specific genes, repressing their transcription. In the crystal structure of alpha 2 and a1 bound to DNA, each homeodomain makes independent base-specific contacts with the DNA and the two proteins contact each other through an extended tail region of alpha 2 that tethers the two homeodomains to one another. Because this extended region may be flexible, the ability of the heterodimer to discriminate among DNA sites with altered spacing between alpha 2 and a1 binding sites was examined. Spacing between the half sites was critical for specific DNA binding and transcriptional repression by the complex. However, amino acid insertions in the tail region of alpha 2 suppressed the effect of altering an a1/alpha 2 site by increasing the spacing between the half sites. Insertions in the tail also decreased DNA bending by a1/alpha 2. Thus tethering the two homeodomains contributes to DNA bending by a1/alpha 2, but the precise nature of the resulting bend is not essential for repression.

Crystal structure of the MATa1/MAT alpha 2 homeodomain heterodimer bound to DNA

The Saccharomyces cerevisiae MATa1 and MAT alpha 2 homeodomain proteins, which play a role in determining yeast cell type, form a heterodimer that binds DNA and represses transcription in a cell type-specific manner. Whereas the alpha 2 and a1 proteins on their own have only modest affinity for DNA, the a1/alpha 2 heterodimer binds DNA with high specificity and affinity. The three-dimensional crystal structure of the a1/alpha 2 homeodomain heterodimer bound to DNA was determined at a resolution of 2.5 A. The a1 and alpha 2 homeodomains bind in a head-to-tail orientation, with heterodimer contacts mediated by a 16-residue tail located carboxyl-terminal to the alpha 2 homeodomain. This tail becomes ordered in the presence of a1, part of it forming a short amphipathic helix that packs against the a1 homeodomain between helices 1 and 2. A pronounced 60 degree bend is induced in the DNA, which makes possible protein-protein and protein-DNA contacts that could not take place in a straight DNA fragment. Complex formation mediated by flexible protein-recognition peptides attached to stably folded DNA binding domains may prove to be a general feature of the architecture of other classes of eukaryotic transcriptional regulators.

Crystallization and preliminary X-ray diffraction studies of an a1/alpha 2/DNA ternary complex

Crystals have been obtained of a ternary complex containing the yeast a1/alpha 2 homeodomain heterodimer bound to a 21-base pair DNA site containing two 5' overhanging bases at each end. The crystals are grown from cobaltic hexamine and form in space group P6(1) or P6(5) with a = b = 133 A, c = 45.4 A. Crystals that are flash-frozen at -179 degrees C diffract to 2.7 A along the c-axis and to 2.4 A in perpendicular directions. The crystals contain one protein-DNA complex in the crystallographic asymmetric unit.

Crystal structure of a MAT alpha 2 homeodomain-operator complex suggests a general model for homeodomain-DNA interactions

The MAT alpha 2 homeodomain regulates the expression of cell type-specific genes in yeast. We have determined the 2.7 A resolution crystal structure of the alpha 2 homeodomain bound to a biologically relevant DNA sequence. The DNA in this complex is contacted primarily by the third of three alpha-helices, with additional contacts coming from an N-terminal arm. Comparison of the yeast alpha 2 and the Drosophila engrailed homeodomain-DNA complexes shows that the protein fold is highly conserved, despite a 3-residue insertion in alpha 2 and only 27% sequence identity between the two homeodomains. Moreover, the orientation of the recognition helix on the DNA is also conserved. This docking arrangement is maintained by side chain contacts with the DNA--primarily the sugar-phosphate backbone--that are identical in alpha 2 and engrailed. Since these residues are conserved among all homeodomains, we propose that the contacts with the DNA are also conserved and suggest a general model for homeodomain-DNA interactions.

Crystallization and preliminary X-ray diffraction studies of a MAT alpha 2-DNA complex

Crystals have been obtained of the DNA-binding domain of the yeast MAT alpha 2 repressor bound to a 21 base-pair DNA site. The crystals are grown from polyethylene glycol and CaCl2 and form in space group P2(1) with a = 60.1 A, b = 39.4 A, c = 68.7 A and beta = 98 degrees. They diffract to 2.9 A resolution and contain one protein-DNA complex in the crystallographic asymmetric unit.

Structure of phage 434 Cro protein at 2.35 A resolution

The crystal structure of phage 434 Cro protein has been determined and refined against 2.35 A data to an R-factor of 19.5%. The protein comprises five alpha-helices and shows the helix-turn-helix motif found in other repressor proteins.

Structure of a phage 434 Cro/DNA complex

Comparison of the crystal structure of a complex of the phage 434 Cro protein and a synthetic DNA operator with the complex of the same operator and the 434 repressor DNA-binding domain shows different DNA conformations in the two structures. Binding of the protein determines the precise conformation of the DNA in each case.

Recognition of DNA sequences by the repressor of bacteriophage 434

The structure of a complex between the DNA-binding domain of phage 434 repressor and a 14 base-pair synthetic DNA operator reveals the molecular interactions important for sequence-specific recognition. A set of contacts with DNA backbone, notably involving hydrogen bonds between peptide-NH groups and DNA phosphates, position the repressor and fix the DNA configuration. Direct interactions between amino acid side chains and DNA bases involve nonpolar van der Waals contacts as well as hydrogen bonds. The structures of the repressor domain and of the 434 cro protein are extremely similar. There appear to be no major conformational changes in the proteins when they bind to DNA.

Crystallization and X-ray diffraction studies of a 434 Cro-DNA complex

Crystals have been obtained of the bacteriophage 434 Cro protein bound to a synthetic DNA operator. An analysis of the packing shows that the complexes stack end-to-end along crystallographic axis, forming long rods with non-crystallographic 11(3) screw symmetry. The average number of DNA base-pairs per turn is 10.27, which is somewhat more overwound as compared with the 434 repressor-DNA crystals of Anderson et al. Diffraction extends to 3 A along the rod direction and to 5 A in perpendicular directions.