Structural basis for the substrate specificity switching of lysoplasmalogen-specific phospholipase D from Thermocrispum sp. RD004668.

Lysoplasmalogen-specific phospholipase D (LyPls-PLD) hydrolyzes choline lysoplasmalogen to choline and 1-(1-alkenyl)-sn-glycero-3-phosphate. Mutation of F211 to leucine altered its substrate specificity from lysoplasmalogen to 1-O-hexadecyl-2-hydroxy-sn-glycero-3-phosphocholine (lysoPAF). Enzymes specific to lysoPAF have good potential for clinical application, and understanding the mechanism of their activity is important. The crystal structure of LyPls-PLD exhibited a TIM barrel fold assigned to glycerophosphocholine phosphodiesterase, a member of glycerophosphodiester phosphodiesterase. LyPls-PLD possesses a hydrophobic cleft for the binding of the aliphatic chain of the substrate. In the structure of the F211L mutant, Met232 and Tyr258 form a "small lid" structure that stabilizes the binding of the aliphatic chain of the substrate. In contrast, F211 may inhibit small lid formation in the wild-type structure. LysoPAF possesses a flexible aliphatic chain; therefore, a small lid is effective for stabilizing the substrate during catalytic reactions.

Structural basis for the high thermal stability and optimum pH of sphingomyelinase C from Streptomyces griseocarneus.

Sphingomyelinase C (SMC) hydrolyzes sphingomyelin to ceramide and phosphocholine. Prokaryotic SMCs share sequence homology with mammalian SMCs that have enzymatic pH optima at neutral pH. SMC from the nonpathogenic prokaryote Streptomyces griseocarneus shows notable enzymatic features such as higher optimum pH and thermostability than other prokaryotic SMCs. Determination of the three-dimensional structure of S. griseocarneus-SMC (Sg-SMC) and comparison with other SMC structures represents a promising strategy to elucidate the unique enzymatic features of Sg-SMC on a structural basis. Therefore, we determined the crystal structure of Sg-SMC at 2.0 Å resolution by X-ray crystallography. Comparison of the Sg-SMC structure with three other structurally known SMCs from Listeria ivanovii, Bacillus cereus, and Staphylococcus aureus indicated that Sg-SMC is more diverse in sequence and that structural differences in the main chain between these SMCs are primarily located on the molecular surface distant from the active site. Comparison of the surface area of the four SMCs revealed that Sg-SMC has the most compact structure, which may contribute to the enhanced thermostability of Sg-SMC. Regarding the hydrogen bond network in the active site of Sg-SMC, a basic amino acid, Arg278, is involved, whereas the corresponding residue in other SMCs (Ser or Asn) does not form hydrogen bonds with metal-coordinating water molecules. Hydrogen bond formation between Arg278 and a Mg2+ ion-coordinating water molecule may be responsible for the higher optimal pH of Sg-SMC compared to that of other SMCs.

Crystal structure analysis of the PHD domain of the transcription co-activator Pygopus.

The Wnt/beta-catenin signaling pathway plays important roles in animal development and cancer. Pygopus (Pygo) and Legless (Lgs) are recently discovered core components of the Wnt/beta-catenin transcription machinery complex, and are crucially involved in the regulation of the transcription of the Arm/beta-catenin and T cell factors (TCF). Lgs/Bcl9 functions as an adaptor between Pygo and Arm/beta-catenin. Here, we report the first crystal structure of the plant homeodomain (PHD) finger of Pygopus (Pygo1 PHD), a Pygo family member, which is essential for the association with Lgs/Bcl9. The Pygo1 PHD structure forms a canonical PHD finger motif, stabilized by two Zn ions coordinated in a cross-brace scheme. Surprisingly, the Pygo1 PHD domain forms a dimer in both the crystals and solution. This is the first structural evidence for dimerization among the known PHD domain structures. The dimer formation occurs by the interactions of antiparallel beta-sheets between the symmetry-related beta3 strands of the monomers. The Pygo1 PHD dimer interface mainly comprises hydrophobic residues. Interestingly, some of the interface residues, such as Met372, Thr373, Ala376 and Leu380, are reportedly important for the association with Lgs/Bcl9 and are also critical for transcriptional activation. The M372A and L380D mutants, and several surrounding mutants such as S385A and A386D, showed decreased ability to form dimers and to interact with the homology domain 1 (HD1) of Lgs/Bcl9. These results suggest that the Pygo1 PHD dimerization is functionally important for Lgs/Bcl9 recognition as well as for the regulation of the Wnt/beta-catenin signaling pathway.

Crystal structure of the human BRD2 bromodomain: insights into dimerization and recognition of acetylated histone H4.

The BET (bromodomains and extra terminal domain) family proteins recognize acetylated chromatin through their bromodomain and act as transcriptional activators. One of the BET proteins, BRD2, associates with the transcription factor E2F, the mediator components CDK8 and TRAP220, and RNA polymerase II, as well as with acetylated chromatin during mitosis. BRD2 contains two bromodomains (BD1 and BD2), which are considered to be responsible for binding to acetylated chromatin. The BRD2 protein specifically recognizes the histone H4 tail acetylated at Lys12. Here, we report the crystal structure of the N-terminal bromodomain (BD1, residues 74-194) of human BRD2. Strikingly, the BRD2 BD1 protein forms an intact dimer in the crystal. This is the first observation of a homodimer among the known bromodomain structures, through the buried hydrophobic core region at the interface. Biochemical studies also demonstrated BRD2 BD1 dimer formation in solution. The two acetyllysine-binding pockets and a negatively charged secondary binding pocket, produced at the dimer interface in BRD2 BD1, may be the unique features that allow BRD2 BD1 to selectively bind to the acetylated H4 tail.

Crystal structure of a predicted phosphoribosyltransferase (TT1426) from Thermus thermophilus HB8 at 2.01 A resolution.

TT1426, from Thermus thermophilus HB8, is a conserved hypothetical protein with a predicted phosphoribosyltransferase (PRTase) domain, as revealed by a Pfam database search. The 2.01 A crystal structure of TT1426 has been determined by the multiwavelength anomalous dispersion (MAD) method. TT1426 comprises a core domain consisting of a central five-stranded beta sheet surrounded by four alpha-helices, and a subdomain in the C terminus. The core domain structure resembles those of the type I PRTase family proteins, although a significant structural difference exists in an inserted 43-residue region. The C-terminal subdomain corresponds to the "hood," which contains a substrate-binding site in the type I PRTases. The hood structure of TT1426 differs from those of the other type I PRTases, suggesting the possibility that TT1426 binds an unknown substrate. The structure-based sequence alignment provides clues about the amino acid residues involved in catalysis and substrate binding.

Solution structure of a BolA-like protein from Mus musculus.

The BolA-like proteins are widely conserved from prokaryotes to eukaryotes. The BolA-like proteins seem to be involved in cell proliferation or cell-cycle regulation, but the molecular function is still unknown. Here we determined the structure of a mouse BolA-like protein. The overall topology is alphabetabetaalphaalphabetaalpha, in which beta(1) and beta(2) are antiparallel, and beta(3) is parallel to beta(2). This fold is similar to the class II KH fold, except for the absence of the GXXG loop, which is well conserved in the KH fold. The conserved residues in the BolA-like proteins are assembled on the one side of the protein.

Crystal structure of the conserved protein TT1542 from Thermus thermophilus HB8.

The TT1542 protein from Thermus thermophilus HB8 is annotated as a conserved hypothetical protein, and belongs to the DUF158 family in the Pfam database. A BLAST search revealed that homologs of TT1542 are present in a wide range of organisms. The TT1542 homologs in eukaryotes, PIG-L in mammals, and GPI12 in yeast and protozoa, have N-acetylglucosaminylphosphatidylinositol (GlcNAc-PI) de-N-acetylase activity. Although most of the homologs in prokaryotes are hypothetical and have no known function, Rv1082 and Rv1170 from Mycobacterium tuberculosis are enzymes involved in the mycothiol detoxification pathway. Here we report the crystal structure of the TT1542 protein at 2.0 A resolution, which represents the first structure for this superfamily of proteins. The structure of the TT1542 monomer consists of a twisted beta-sheet composed of six parallel beta-strands and one antiparallel beta-strand (with the strand order 3-2-1-4-5-7-6) sandwiched between six alpha-helices. The N-terminal five beta-strands and four alpha-helices form an incomplete Rossmann fold-like structure. The structure shares some similarity to the sugar-processing enzymes with Rossmann fold-like domains, especially those of the GPGTF (glycogen phosphorylase/glycosyl transferase) superfamily, and also to the NAD(P)-binding Rossmann fold domains. TT1542 is a homohexamer in the crystal and in solution, the six monomers forming a cylindrical structure. Putative active sites are suggested by the structure and conserved amino acid residues.