Voltage and Use Dependence of Sodium Channel Blockade by a New Analgesic,D57, in Rat Dorsal Root Ganglion Neurons

We studied the voltage- and use-dependent action of pyrrolo-imidazole derivative, D57, on sodium currents in different dorsal root ganglion neurons of rats. At the level of 50% of maximum tonic block, which corresponded to a concentration of 0.44 mM, the use-dependent block of tetrodotoxin resistant (TTXr) sodium currents reached 59 ± 12% of the remaining currents when neurons were stimulated by 6-msec-long impulses up to -10 mV with a 20 sec^-1 frequency, whereas for TTX sensitive (TTXs) currents this value was equal to 38 ± 9%. This block was dependent on the holding potential, and for cells with only TTXr currents the dependence was shifted to more positive potentials compared with that for neurons with only TTXs currents or with both of them.     

Structure-based design of substituted biphenyl ethylene ethers as ligands binding in the hydrophobic pocket of gp41 and blocking the helical bundle formation

A series of substituted biphenyl ethylene ether compounds has been designed to target the gp41 N-trimer in order to inhibit formation of the six-helical bundle that represents the end state of gp41-mediated viral fusion. A size exclusion HPLC based helical bundle formation (HBF) assay was developed to evaluate in vitro inhibitory affinity of the inhibitors. The most potent compound 1 had an IC₅₀ of 31 μM. The binding of compound 1 to the proposed hydrophobic pocket of gp41 was further validated by site-directed peptide mutagenesis experiments.     

A Biacore biosensor method for detailed kinetic binding analysis of small molecule inhibitors of p38alpha mitogen-activated protein kinase

Protein kinases are emerging as one of the most intensely studied classes of enzymes as their central roles in physiologically and clinically important cellular signaling events become more clearly understood. We report here the development of a real-time, label-free method to study protein kinase inhibitor binding kinetics using surface plasmon resonance-based biomolecular interaction analysis (Biacore). Utilizing p38alpha mitogen-activated protein kinase as a model system, we studied the binding properties of two known small molecule p38alpha inhibitors (SB-203580 and SKF-86002). Direct coupling of p38alpha to the biosensor surface in the presence of a reversible structure-stabilizing ligand (SB-203580) consistently produced greater than 90% active protein on the biosensor surface. The dissociation and kinetic constants derived using this Biacore method are in excellent agreement with values determined by other methods. Additionally, we extend the method to study the thermodynamics of small molecule binding to p38alpha and derive a detailed thermodynamic reaction pathway for SB-203580. The Biacore method reported here provides an efficient way to directly and reproducibly examine dissociation constants, kinetics, and thermodynamics for small molecules binding to p38alpha and possibly other protein kinases. Immobilization in the presence of a stabilizing ligand may further represent a broadly applicable paradigm for creation of highly active biosensor surfaces.     

Two classes of p38alpha MAP kinase inhibitors having a common diphenylether core but exhibiting divergent binding modes

Two new classes of diphenylether inhibitors of p38alpha MAP kinase are described. Both chemical classes are based on a common diphenylether core that is identified by simulated fragment annealing as one of the most favored chemotypes within a prominent hydrophobic pocket of the p38alpha ATP-binding site. In the fully elaborated molecules, the diphenylether moiety acts as an anchor occupying the deep pocket, while polar extensions make specific interactions with either the adenine binding site or the phosphate binding site of ATP. The synthesis, crystallographic analysis, and biological activity of these p38alpha inhibitors are discussed.     

Discovery of a novel class of non-ATP site DFG-out state p38 inhibitors utilizing computationally assisted virtual fragment-based drug design (vFBDD)

Discovery of a new class of DFG-out p38α kinase inhibitors with no hinge interaction is described. A computationally assisted, virtual fragment-based drug design (vFBDD) platform was utilized to identify novel non-aromatic fragments which make productive hydrogen bond interactions with Arg 70 on the αC-helix. Molecules incorporating these fragments were found to be potent inhibitors of p38 kinase. X-ray co-crystal structures confirmed the predicted binding modes. A lead compound was identified as a potent (p38α IC(50)=22 nM) and highly selective (≥ 150-fold against 150 kinase panel) DFG-out p38 kinase inhibitor.     

Improved expression, purification, and crystallization of p38alpha MAP kinase

p38alpha mitogen-activated protein (MAP) kinase is widely expressed in many mammalian tissues and is activated as a part of signal transduction cascades that respond to inflammatory stimuli. The activation of p38 is known to trigger various biological effects, including cell death, differentiation, and proliferation. The central role played by p38alpha in cellular signaling events, including those that control a wide range of inflammatory and autoimmune diseases, makes it an attractive drug target. To develop optimized small molecule therapeutics targeting p38alpha, different techniques must be employed for the detailed biochemical, biophysical, and structural characterization of the interactions of p38alpha with lead compounds. These methods typically require large quantities of highly purified p38alpha protein. We describe here an improved expression and purification method for recombinant p38alpha production that reproducibly yields over 70 mg of highly purified protein per liter of shake flask bacterial culture. This yield is significantly higher than that previously reported for p38alpha production in Escherichia coli. We achieved a significant increase in soluble p38alpha protein expression by using the genetically modified E. coli strain BL21 DE3 Rosetta, which is optimized for expression of eukaryotic proteins with codons rarely used in E. coli. The p38alpha protein was purified to near homogeneity using a simple two-step procedure including nickel-chelating Sepharose chromatography followed by anion-exchange chromatography using MonoQ resin. Purified p38alpha was characterized using the standard commercially available small molecule inhibitor SB-203580. The binding association and dissociation rate constants determined by Biacore are in excellent agreement with previously reported values. The purified p38alpha protein was efficiently activated by MKK6 kinase to yield phosphorylated p38alpha. Purified p38alpha protein was also successfully crystallized, producing crystals diffracting to 1.9 angstroms, exceeding the highest resolution for p38alpha reported in the Protein DataBank. The simplicity and efficiency of this approach should prove useful for many laboratories that are interested in production of p38alpha for biochemical and biophysical studies and structure-based drug design.     

The rational design of a novel potent analogue of the 5'-AMP-activated protein kinase inhibitor compound C with improved selectivity and cellular activity

We have designed and synthesized analogues of compound C, a non-specific inhibitor of 5'-AMP-activated protein kinase (AMPK), using a computational fragment-based drug design (FBDD) approach. Synthesizing only twenty-seven analogues yielded a compound that was equipotent to compound C in the inhibition of the human AMPK (hAMPK) α2 subunit in the heterotrimeric complex in vitro, exhibited significantly improved selectivity against a subset of relevant kinases, and demonstrated enhanced cellular inhibition of AMPK.     

Analysis of the pediocin AcH gene cluster from plasmid pSMB74 and its expression in a pediocin-negative Pediococcus acidilactici strain.

The 3,500-bp pap operon in the 8,877-bp plasmid pSMB74 contains a cluster of four genes, papABCD, of which papA encodes prepediocin (A. M. Motlagh, M. Bukhtiyarova, and B. Ray, Lett. Appl. Microbiol. 18:305-312, 1994). The cluster without the promoter was cloned in the shuttle vector pHPS9. An Escherichia coli strain and a pediocin-sensitive Pediococcus acidilactici strain transformed with the recombinant plasmid, pMBR1.0, produced pediocin AcH. Deletion analysis by introducing mutations in the four genes in pMBR1.0 revealed that only papA and papD were required for pediocin AcH production and that the gene product of papD has both translocation and processing functions. In the transformed minicells of E. coli chi 925 the proteins of the pap cluster were synthesized, indicating no polar effect due to deletion.     

Mutagenesis of p38alpha MAP kinase establishes key roles of Phe169 in function and structural dynamics and reveals a novel DFG-OUT state

In order to study the role of Phe169 in p38alpha MAP kinase structure and function, wild-type p38alpha and five p38alpha DFG motif mutants were examined in vitro for phosphorylation by MKK6, kinase activity toward ATF2 substrate, thermal stability, and X-ray crystal structure. All six p38alpha variants were efficiently phosphorylated by MKK6. However, only one activated p38alpha mutant (F169Y) possessed measurable kinase activity (1% compared to wild-type). The loss of kinase activity among the DFG mutants may result from an inability to correctly position Asp168 in the activated form of p38alpha. Two mutations significantly increased the thermal stability of p38alpha (F169A DeltaTm = 1.3 degrees C and D168G DeltaTm = 3.8 degrees C), and two mutations significantly decreased the stability of p38alpha (F169R DeltaTm = -3.2 degrees C and F169G DeltaTm = -4.7 degrees C). Interestingly, X-ray crystal structures of two thermally destabilized p38alpha-F169R and p38alpha-F169G mutants revealed a DFG-OUT conformation in the absence of an inhibitor molecule. This DFG-OUT conformation, termed alpha-DFG-OUT, is different from the ones previously identified in p38alpha crystal structures with bound inhibitors and postulated from high-temperature molecular dynamics simulations. Taken together, these results indicate that Phe169 is optimized for p38alpha functional activity and structural dynamics, rather than for structural stability. The alpha-DFG-OUT conformation observed for p38alpha-F169R and p38alpha-F169G may represent a naturally occurring intermediate state of p38alpha that provides access for binding of allosteric inhibitors. A model of the local forces driving the DFG IN-OUT transition in p38alpha is proposed.