The mitogen activated kinases JNK1/2/3 are key enzymes in signaling modules that transduce and integrate extracellular stimuli into coordinated cellular response. Here we report the discovery of the first irreversible inhibitors of JNK1/2/3. We describe two JNK3 co-crystal structures at 2.60 and 2.97 Å resolutions that show the compounds form covalent bonds with a conserved cysteine residue. JNK-IN-8 is a selective JNK inhibitor that inhibits phosphorylation of c-Jun, a direct substrate of JNK kinase, in cells exposed to sub-micromolar drug in a manner that depends on covalent modification of the conserved cysteine residue. Extensive biochemical, cellular and pathway-based profiling establish the selectivity of JNK-IN-8 for JNK and suggest that the compound will be broadly useful as a pharmacological probe of JNK-dependent signal transduction. Potential lead compounds have also been identified for kinases including IRAK1, PIK3C3, PIP4K2C, and PIP5K3.
The X-ray crystal structure of the Escherichia coli (Ec) direct oxygen sensor heme domain (Ec DosH) has been solved to 1.8 A using Fe multiple-wavelength anomalous dispersion (MAD), and the positions of Met95 have been confirmed by selenomethionine ((Se)Met) MAD. Ec DosH is the sensing part of a larger two-domain sensing/signaling protein, in which the signaling domain has phosphodiesterase activity. The asymmetric unit of the crystal lattice contains a dimer comprised of two differently ligated heme domain monomers. Except for the heme ligands, the monomer heme domains are identical. In one monomer, the heme is ligated by molecular oxygen (O(2)), while in the other monomer, an endogenous Met95 with S --> Fe ligation replaces the exogenous O(2) ligand. In both heme domains, the proximal ligand is His77. Analysis of these structures reveals sizable ligand-dependent conformational changes in the protein chain localized in the FG turn, the G(beta)-strand, and the HI turn. These changes provide insight to the mechanism of signal propagation within the heme domain following initiation due to O(2) dissociation.
It is well known that exposure to UV induces DNA damage, which is the first step in mutagenesis and a major cause of skin cancer. Among a variety of photoproducts, cyclobutane-type pyrimidine photodimers (CPD) are the most abundant primary lesion. Despite its biological importance, the precise relationship between the structure and properties of DNA containing CPD has remained to be elucidated. Here, we report the free (unbound) crystal structure of duplex DNA containing a CPD lesion at a resolution of 2.0 Å. Our crystal structure shows that the overall helical axis bends Ϸ30°t oward the major groove and unwinds Ϸ9°, in remarkable agreement with some previous theoretical and experimental studies. There are also significant differences in local structure compared with standard B-DNA, including pinching of the minor groove at the 3 side of the CPD lesion, a severe change of the base pair parameter in the 5 side, and serious widening of both minor and major groves both 3 and 5 of the CPD. Overall, the structure of the damaged DNA differs from undamaged DNA to an extent that DNA repair proteins may recognize this conformation, and the various components of the replicational and transcriptional machinery may be interfered with due to the perturbed local and global structure. The cis-syn pyrimidine dimer (cyclobutane-type pyrimidine photodimer, CPD) is the major photoproduct induced by UV light present in sunlight (1) and is one of the principal causes of skin cancer (2). Evidence for the formation of the thymine dimer in DNA was first obtained Ͼ40 years ago (3, 4) and a few years later for cytosine-containing CPDs (5). Because of the mutagenic and protein-DNA-disrupting properties of CPDs, many organisms have evolved enzymes to specifically recognize and repair cis-syn dimers, such as Escherichia coli photolyase (6, 7), T4 endoV (8), as well as general repair enzymes such as E. coli uvrABC (9) and human excinuclease (10). Additionally, dimers are efficiently repaired in transcription-coupled repair by virtue of their ability to block synthesis by RNA polymerases (11,12). CPDs also block DNA replication (13) and are efficiently bypassed in a nonmutagenic manner by DNA damage bypass polymerases such as E. coli pol V (14) and the recently discovered yeast (15) and human polymerase (16,17). There is also evidence that the mismatch repair system can recognize mismatches opposite thymine dimers (18). Understanding the mechanism by which these proteins recognize and process CPDs will be greatly aided by a structure for CPD-containing DNA.The efficiency of damage repair is likely to depend on the extent to which those changes alter the structure of the DNA, hence making it recognizable for the repair enzymes involved. It has been suggested that the binding affinities of the repair enzymes for the CPD-containing DNA depend on the degree of DNA unwinding or kinking caused by those lesions (19,20). The first evidence that CPD formation causes large alterations in the structure of DNA is offered by circular dichroism studies and...
The nuclear receptor peroxisome proliferator-activated receptor gamma (PPARγ) is the master regulator of adipogenesis and the pharmacological target of the thiazolidinedione (TZD) class of insulin sensitizers. Activation of PPARγ by TZDs promotes adipogenesis at the expense of osteoblast formation, contributing to their associated adverse effects on bone. Recently we reported the development of PPARγ antagonist SR1664, designed to block the obesity induced phosphorylation of serine 273 (S273) in the absence of classical agonism, to derive insulin sensitizing efficacy with improved therapeutic index. Here we identify the structural mechanism by which SR1664 actively antagonizes PPARγ, and extend these findings to develop the inverse agonist SR2595. Treatment of isolated bone marrow derived mesenchymal stem cells (MSCs) with SR2595 promotes induction of osteogenic differentiation. Together these results identify the structural determinants of ligand mediated PPARγ repression, and suggest a therapeutic approach to promote bone formation.
Interaction of the pattern recognition receptor, RAGE with key ligands such as advanced glycation end products (AGE), S100 proteins, amyloid , and HMGB1 has been linked to diabetic complications, inflammatory and neurodegenerative disorders, and cancer. To help answer the question of how a single receptor can recognize and respond to a diverse set of ligands we have investigated the structure and binding properties of the first two extracellular domains of human RAGE, which are implicated in various ligand binding and subsequent signaling events. The 1.5-Å crystal structure reveals an elongated molecule with a large basic patch and a large hydrophobic patch, both highly conserved. Isothermal titration calorimetry (ITC) and deletion experiments indicate S100B recognition by RAGE is an entropically driven process involving hydrophobic interaction that is dependent on Ca 2؉ and on residues in the C D loop (residues 54 -67) of domain 1. In contrast, competition experiments using gel shift assays suggest that RAGE interaction with AGE is driven by the recognition of negative charges on AGE-proteins. We also demonstrate that RAGE can bind to dsDNA and dsRNA. These findings reveal versatile structural features of RAGE that help explain its ability to recognize of multiple ligands.The receptor for advanced glycation end products (RAGE) 3 is a multifunctional cell surface protein of the innate immune system thought to play pivotal roles in diabetes, chronic inflammatory conditions, neurodegenerative diseases, and cancer as well as T-lymphocyte proliferation and priming (1-3). In diabetic patients, abnormally high levels of glucose and accompanying reactive oxygen species (ROS) promote the formation of non-enzymatically glucose-derivatized protein (4, 5), also known as advanced glycation end products (AGE). Interaction of AGE with its primary receptor, RAGE, initiates pro-inflammatory responses from a variety of RAGE-expressing cell types such as vascular cells, monocytes/macrophage, B-and T-lymphocytes, retina Müller cells, kidney podocytes, mesangial cells, glial cells and neurons as well as certain cancer cells (2). Unlike macrophage scavenger receptors that can bind AGE and remove it from the cell environment, RAGE does not accelerate the clearance of AGE. Rather, it induces a sustained pro-inflammatory signal (6), which depending on cell type, results in various responses (7) including the generation of ROS and up-regulation of cytokines, vascular cell adhesion molecule 1 (VCAM1), monocyte chemoattractant protein-1 (MCP-1), matrix metalloproteinases, and RAGE itself, each of which potentially exacerbates diabetic pathology. A critical role of RAGE in diabetic complications has been implicated in a NOD/Scid mouse model where animals treated with sRAGE (soluble RAGE ectodomain) showed significant reduction in the development of diabetes after a transfer of splenocytes from a diabetic NOD donor (8). In addition to AGE, RAGE is also known to bind a number of other protein ligands including various S100/calgranulins, hig...
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