Eva Papp

Molecular Mechanism of the Syk Activation Switch

Many immune signaling pathways require activation of the Syk tyrosine kinase to link ligation of surface receptors to changes in gene expression. Despite the central role of Syk in these pathways, the Syk activation process remains poorly understood. In this work we quantitatively characterized the molecular mechanism of Syk activation in vitro using a real time fluorescence kinase assay, mutagenesis, and other biochemical techniques. We found that dephosphorylated full-length Syk demonstrates a low initial rate of substrate phosphorylation that increases during the kinase reaction due to autophosphorylation. The initial rate of Syk activity was strongly increased by either pre-autophosphorylation or binding of phosphorylated immune tyrosine activation motif peptides, and each of these factors independently fully activated Syk. Deletion mutagenesis was used to identify regions of Syk important for regulation, and residues 340–356 of the SH2 kinase linker region were identified to be important for suppression of activity before activation. Comparison of the activation processes of Syk and Zap-70 revealed that Syk is more readily activated by autophosphorylation than Zap-70, although both kinases are rapidly activated by Src family kinases. We also studied Syk activity in B cell lysates and found endogenous Syk is also activated by phosphorylation and immune tyrosine activation motif binding. Together these experiments show that Syk functions as an “OR-gate” type of molecular switch. This mechanism of switch-like activation helps explain how Syk is both rapidly activated after receptor binding but also sustains activity over time to facilitate longer term changes in gene expression.

Pamapimod, a Novel p38 Mitogen-Activated Protein Kinase Inhibitor: Preclinical Analysis of Efficacy and Selectivity

P38α is a protein kinase that regulates the expression of inflammatory cytokines, suggesting a role in the pathogenesis of diseases such as rheumatoid arthritis (RA) or systemic lupus erythematosus. Here, we describe the preclinical pharmacology of pamapimod, a novel p38 mitogen-activated protein kinase inhibitor. Pamapimod inhibited p38α and p38β enzymatic activity, with IC50 values of 0.014 ± 0.002 and 0.48 ± 0.04 μM, respectively. There was no activity against p38δ or p38γ isoforms. When profiled across 350 kinases, pamapimod bound only to four kinases in addition to p38. Cellular potency was assessed using phosphorylation of heat shock protein-27 and c-Jun as selective readouts for p38 and c-Jun NH2-terminal kinase (JNK), respectively. Pamapimod inhibited p38 (IC50, 0.06 μM), but inhibition of JNK was not detected. Pamapimod also inhibited lipopolysaccharide (LPS)-stimulated tumor necrosis factor (TNF) α production by monocytes, interleukin (IL)-1β production in human whole blood, and spontaneous TNFα production by synovial explants from RA patients. LPS- and TNFα-stimulated production of TNFα and IL-6 in rodents also was inhibited by pamapimod. In murine collagen-induced arthritis, pamapimod reduced clinical signs of inflammation and bone loss at 50 mg/kg or greater. In a rat model of hyperalgesia, pamapimod increased tolerance to pressure in a dose-dependent manner, suggesting an important role of p38 in pain associated with inflammation. Finally, an analog of pamapimod that has equivalent potency and selectivity inhibited renal disease in lupus-prone MRL/lpr mice. Our study demonstrates that pamapimod is a potent, selective inhibitor of p38α with the ability to inhibit the signs and symptoms of RA and other autoimmune diseases.

Structural insights for design of potent spleen tyrosine kinase inhibitors from crystallographic analysis of three inhibitor complexes.

Spleen tyrosine kinase is considered an attractive drug target for the treatment of allergic and antibody mediated autoimmune diseases. We have determined the co‐crystal structures of spleen tyrosine kinase complexed with three known inhibitors: YM193306, a 7‐azaindole derivative and R406. The cis‐cyclohexyldiamino moiety of YM193306 is forming four hydrophobically shielded polar interactions with the spleen tyrosine kinase protein and is therefore crucial for the high potency of this inhibitor. Its primary amino group is inducing a conformational change of the spleen tyrosine kinase DFG Asp side chain. The crystal structure of the 7‐azaindole derivative bound to spleen tyrosine kinase is the first demonstration of a 2‐substituted 7‐azaindole bound to a protein kinase. Its indole‐amide substituent is tightly packed between the N‐ and C‐terminal kinase lobes. The co‐crystal structure of the spleen tyrosine kinase–R406 complex shows two main differences to the previously reported structure of spleen tyrosine kinase soaked with R406: (i) the side chain of the highly conserved Lys is disordered and not forming a hydrogen bond to R406 and (ii) the DFG Asp side chain is pointing away from and not towards R406. The novel protein–ligand interactions and protein conformational changes revealed in these structures guide the rational design and structure‐based optimization of second‐generation spleen tyrosine kinase inhibitors.

Discovery of 6-(2,4-Difluorophenoxy)-2-[3-hydroxy-1-(2-hydroxyethyl)propylamino]-8-methyl-8H-pyrido[2,3-d]pyrimidin-7-one (Pamapimod) and 6-(2,4-Difluorophenoxy)-8-methyl-2-(tetrahydro-2H-pyran-4-ylamino)pyrido[2,3-d]pyrimidin-7(8H)-one (R1487) as Orally Bioavailable and Highly Selective Inhibitors of p38α Mitogen-Activated Protein Kinase

The development of a new series of p38α inhibitors resulted in the identification of two clinical candidates, one of which was advanced into a phase 2 clinical study for rheumatoid arthritis. The original lead, an lck inhibitor that also potently inhibited p38α, was a screening hit from our kinase inhibitor library. This manuscript describes the optimization of the lead to p38-selective examples with good pharmacokinetic properties.

3-Amino-pyrazolo[3,4-d]pyrimidines as p38α kinase inhibitors: Design and development to a highly selective lead

Learnings from previous Roche p38-selective inhibitors were applied to a new fragment hit, which was optimized to a potent, exquisitely selective preclinical lead with a good pharmacokinetic profile.

A fluorescence resonance energy transfer-based binding assay for characterizing kinase inhibitors: Important role for C-terminal biotin tagging of the kinase

Novel biochemical strategies are needed to identify the next generation of protein kinase inhibitors. One promising new assay format is a competition binding approach that employs time-resolved fluorescence resonance energy transfer (TR-FRET). In this assay, a FRET donor is bound to the kinase via a purification tag, whereas a FRET acceptor is bound via a tracer-labeled inhibitor. Displacement of the tracer by an unlabeled inhibitor eliminates FRET between the fluorophores and provides a readout on binding. Although promising, this technique has so far been limited in applicability in part by a lack of signal strength is some cases and also by an inability to predict whether a particular tagging strategy will show robust FRET. In this work, we sought to better understand the factors that give rise to a strong FRET signal in this assay. We determined the magnitude of FRET for several tyrosine kinases using different purification tags (biotin, glutathione S-transferase [GST], and His) placed at either the N terminus or C terminus of the kinase. It was observed that coupling the FRET acceptor to the kinase C terminus using a biotin/streptavidin interaction resulted in the greatest increase in FRET. Specifically, for multiple kinases, the signal/background ratio was at least 3-fold better using C-terminal biotinylation compared with tagging at the N terminus using a His/anti-His antibody or GST/anti-GST antibody interaction. In one case, the FRET signal using C-terminal biotin tagging was more than 150-fold over background. This strong FRET signal facilitated development of improved inhibitor binding assays that required only tens of picomolar enzyme or tracer-labeled inhibitor. Together, these results indicate that C-terminal biotinylation is a promising tagging strategy for developing an optimal FRET-based competition binding assay for tyrosine kinases.