Leslie W. Tari scite author profile

Modulation of the acetylation state of histones plays a pivotal role in the regulation of gene expression. Histone deacetylases (HDACs) catalyze the removal of acetyl groups from lysines near the N termini of histones. This reaction promotes the condensation of chromatin, leading to repression of transcription. HDAC deregulation has been linked to several types of cancer, suggesting a potential use for HDAC inhibitors in oncology. Here we describe the first crystal structures of a human HDAC: the structures of human HDAC8 complexed with four structurally diverse hydroxamate inhibitors. This work sheds light on the catalytic mechanism of the HDACs, and on differences in substrate specificity across the HDAC family. The structure also suggests how phosphorylation of Ser39 affects HDAC8 activity.

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Structural Basis for Bisphosphonate-mediated Inhibition of Isoprenoid Biosynthesis

Hosfield¹,

Zhang²,

Dougan³

et al. 2004

Journal of Biological Chemistry

252

351

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Farnesyl pyrophosphate synthetase (FPPS) synthesizes farnesyl pyrophosphate through successive condensations of isopentyl pyrophosphate with dimethylallyl pyrophosphate and geranyl pyrophosphate. Nitrogen-containing bisphosphonate drugs used to treat osteoclast-mediated bone resorption and tumor-induced hypercalcemia are potent inhibitors of the enzyme. Here we present crystal structures of substrate and bisphosphonate complexes of FPPS. The structures reveal how enzyme conformational changes organize conserved active site residues to exploit metal-induced ionization and substrate positioning for catalysis. The structures further demonstrate how nitrogen-containing bisphosphonates mimic a carbocation intermediate to inhibit the enzyme. Together, these FPPS complexes provide a structural template for the design of novel inhibitors that may prove useful for the treatment of osteoporosis and other clinical indications including cancer.Post-translational modification of C-terminal CAAX sequences by covalent attachment of isoprenyl chains is crucial for intracellular localization and proper function of small GTPases such as Ras, Rac, Rho, and CDC42 (1, 2). The substrates for these modifications are the 15-carbon isoprenoid farnesyl pyrophosphate (FPP) 1 or the 20-carbon isoprenoid geranyl-geranyl pyrophosphate synthesized by enzymes of the mevalonate pathway (3) (Fig. 1A). A key branch point enzyme of the mevalonate pathway is farnesyl pyrophosphate synthetase (FPPS), a ϳ30-kDa Mg 2ϩ -dependent homodimeric enzyme that synthesizes (E,E)-FPP from isopentyl pyrophosphate (IPP) and dimethylallyl pyrophosphate (DMAPP) (4, 5) (Fig. 1B). Interest in understanding FPPS activity stems from the recent discovery that FPPS is the molecular target of nitrogencontaining bisphosphonates (6,7,31,32). Bisphophonates are non-cleavable pyrophosphate (P-O-P) analogues in which the central oxygen is replaced by a carbon (P-C-P) with various side chains (Fig. 1C). Against parasitic organisms (8, 9) these agents have been shown in vitro to disrupt cell growth through FPPS inhibition. In people, bisphosphonates are targeted to bone tissue (10) where FPPS inhibition in bone-resorbing osteoclasts is a current therapeutic approach for treating postmenopausal osteoporosis (11,12). Because of their bone-targeting properties, bisphosphonates have also found use as agents to treat tumor-induced hypercalcemia (13), Paget's disease (14), and osteolytic metastases (15).Although structures of apo-and ligand-bound avian FPPS have been solved (16,17), the active sites are unassembled and do not provide substantial information concerning catalysis. Thus, to resolve the molecular basis of catalysis, and also to understand the structural features governing bisphosphonate recognition, we determined the structures of unliganded Staphylococcus aureus FPPS (FPPS-Sa), as well as two Escherichia coli FPPS (FPPS-Ec) ternary complexes. These ternary complexes include a 2.4-Å "substrate-bound" structure containing IPP and the noncleavable DMAPP analogue dimethyla...

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Plant aromatic L-amino acid decarboxylases: evolution, biochemistry, regulation, and metabolic engineering applications

2000

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How do kinases transfer phosphoryl groups?

1998

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Understanding how phosphoryl transfer is accomplished by kinases, a ubiquitous group of enzymes, is central to many biochemical processes. Qualitative analysis of the crystal structures of enzyme-substrate complexes of kinases reveals structural features of these enzymes important to phosphoryl transfer. Recently determined crystal structures which mimic the transition state complex have added new insight into the debate as to whether kinases use associative or dissociative mechanisms of catalysis.

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Structural Biology of Bacterial Iron Uptake Systems

Clarke¹,

Tari²,

Vogel

2001

CTMC

148

138

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Numerous bacterial proteins are involved in microbial iron uptake and transport and considerable variation has been found in the uptake schemes used by different bacterial species. However, whether extracting iron from host proteins such as transferrin, lactoferrin or hemoglobin or importing low molecular weight iron-chelating compounds such as heme, citrate or siderophores, Gram-negative pathogenic bacteria typically employ a specific outer membrane receptor, a periplasmic binding protein and two inner membrane associated proteins: a transporter coupled with an ATP-hydrolyzing protein. Often, studies have shown that proteins with similar function but little amino acid sequence homology are structurally related. Elucidation of the structures of the Escherichia coli outer membrane siderophore transport proteins FepA and FhuA have provided the first insights into the conformational changes required for ligand transport through the bacterial outer membrane. The variations between the structures of the prototypical periplasmic ferric binding protein FbpA from Neisseria and Haemophilus influenzae and the unusual E coli periplasmic siderophore binding protein FhuD reveal that the different periplasmic ligand binding proteins exercise distinct mechanisms for ligand binding and release. The structure of the hemophore HasA from Serratia marcescens shows how heme may be extracted and utilized by the bacteria. Other biochemical evidence also shows that the proteins that provide energy for iron transport at the outer membrane, such as the TonB-ExbB-ExbD system, are structurally very similar across bacterial species. Likewise, the iron-sensitive gene regulatory protein Fur is found in most bacteria. To date, no structural information is available for Fur, but the structure for the related protein DxtR has been determined. Together, these three-dimensional structures complement our knowledge of iron transport systems from other pathogenic bacteria, including Pseudomonas aeruginosa, which has a number of homologous iron uptake proteins. More importantly, the current structures for iron transport proteins provide rational starting points for design of novel antimicrobial agents.

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Leslie W. Tari

Structural Snapshots of Human HDAC8 Provide Insights into the Class I Histone Deacetylases

Structural Basis for Bisphosphonate-mediated Inhibition of Isoprenoid Biosynthesis

Plant aromatic L-amino acid decarboxylases: evolution, biochemistry, regulation, and metabolic engineering applications

How do kinases transfer phosphoryl groups?

Structural Biology of Bacterial Iron Uptake Systems

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