ABIN-2 forms a ternary complex with TPL-2 and NF-kappa B1 p105 and is essential for TPL-2 protein stability

A20 and ABIN-3 possibly promote regression of trehalose 6,6'-dimycolate (TDM)-induced granuloma by interacting with an NF-kappa B signaling protein, TAK-1

OBJECTIVE

The objective of this paper is to examine the role of NF-kappa B inhibitors A20 and ABIN-family proteins in the trehalose 6,6'-dimycolate (TDM)-induced model of tuberculous granulomatous lesions.

MATERIALS AND METHODS

BALB/c mice were twice injected i.p. with w/o/w emulsions that contain TDM at a 1 week-interval. The mice were killed at days 0, 3, 7, 14, or 21 after the last injection. The mRNA and protein levels of A20 and ABIN-family proteins were measured by real-time PCR using mRNA or protein extract from the lesions. The activation status of NF-kappa B was analyzed by Western blotting and immunohistochemistry. Finally, the protein extracts were immunoprecipitated by anti-ABIN-3 antibody to identify the protein that potentially interacts with ABIN-3.

RESULTS

The activation of NF-kappa B pathway coincided with granuloma development, while A20 and ABIN-3 increased in accordance with granuloma regression. TAK-1 protein was co-precipitated with ABIN-3 by immunoprecipitation using anti-ABIN-3 antibody.

CONCLUSION

The results suggest that ABIN-3 contributed to granuloma regression by interacting with TAK-1 and, as a consequence, inhibiting activation of NF-kappa B pathway.

Crosstalk in NF-κB signaling pathways

NF-κB transcription factors are critical regulators of immunity, stress responses, apoptosis and differentiation. A variety of stimuli coalesce on NF-κB activation, which can in turn mediate varied transcriptional programs. Consequently, NF-κB-dependent transcription is not only tightly controlled by positive and negative regulatory mechanisms but also closely coordinated with other signaling pathways. This intricate crosstalk is crucial to shaping the diverse biological functions of NF-κB into cell type- and context-specific responses.

Cot/tpl2 activity is required for TLR-induced activation of the Akt p70 S6k pathway in macrophages: Implications for NO synthase 2 expression

LPS stimulation activates IKK and different MAP kinase pathways, as well as the PI3K-Akt-mTOR-p70 S6k pathway, a negative regulator of these MyD88-dependent intracellular signals. Here, we show that Cot/tpl2, a MAP3K responsible for the activation of the MKK1-Erk1/2, controls P-Ser473 Akt and P-Thr389 p70 S6k phosphorylation in LPS-stimulated macrophages. Analysis of the intracellular signalling in Cot/tpl2 KO macrophages versus WT macrophages reveals lower IκBα recovery and higher phosphorylation of JNK and p38α after 1 h of LPS stimulation. Moreover, Cot/tpl2 deficiency increases LPS-induced NO synthase 2 (NOS2) expression in macrophages. Inhibition of the PI3K pathway abolishes the differences in IκBα and NOS2 expression between Cot/tpl2 KO and WT macrophages following LPS administration. Furthermore, in zymosan- and polyI:C-stimulated macrophages, Cot/tpl2 mediates P-Ser473 Akt phosphorylation, increases IκBα levels and decreases NOS2 expression. In conclusion, these data reveal a novel role for the Cot/tpl2 pathway in mediating TLR activation of the Akt-mTOR-p70 S6k pathway, allowing Cot/tpl2 to fine-control the activation state of other signalling pathways.

Tpl2 kinase signal transduction in inflammation and cancer

The activation of mitogen-activated protein kinases (MAPKs) is critically involved in inflammatory and oncogenic events. Tumor progression locus 2 (Tpl2), also known as COT and MAP3 kinase 8 (MAP3K8), is a serine-threonine kinase with an important physiological role in tumor necrosis factor, interleukin-1, CD40, Toll-like receptor and G protein-coupled receptor-mediated ERK MAPK signaling. Whilst the full characterization of the biochemical events that lead to the activation of Tpl2 still represent a major challenge, genetic and molecular evidence has highlighted interesting interactions with the NF-κB network. Here, we provide an overview of the multifaceted functions of Tpl2 and the molecular mechanisms that govern its regulation.

Regulation and function of TPL-2, an IκB kinase-regulated MAP kinase kinase kinase

The IκB kinase (IKK) complex plays a well-documented role in innate and adaptive immunity. This function has been widely attributed to its role as the central activator of the NF-κB family of transcription factors. However, another important consequence of IKK activation is the regulation of TPL-2, a MEK kinase that is required for activation of ERK-1/2 MAP kinases in myeloid cells following Toll-like receptor and TNF receptor stimulation. In unstimulated cells, TPL-2 is stoichiometrically complexed with the NF-κB inhibitory protein NF-κB1 p105, which blocks TPL-2 access to its substrate MEK, and the ubiquitin-binding protein ABIN-2 (A20-binding inhibitor of NF-κB 2), both of which are required to maintain TPL-2 protein stability. Following agonist stimulation, the IKK complex phosphorylates p105, triggering its K48-linked ubiquitination and degradation by the proteasome. This releases TPL-2 from p105-mediated inhibition, facilitating activation of MEK, in addition to modulating NF-κB activation by liberating associated Rel subunits for translocation into the nucleus. IKK-induced proteolysis of p105, therefore, can directly regulate both NF-κB and ERK MAP kinase activation via NF-κB1 p105. TPL-2 is critical for production of the proinflammatory cytokine TNF during inflammatory responses. Consequently, there has been considerable interest in the pharmaceutical industry to develop selective TPL-2 inhibitors as drugs for the treatment of TNF-dependent inflammatory diseases, such as rheumatoid arthritis and inflammatory bowel disease. This review summarizes our current understanding of the regulation of TPL-2 signaling function, and also the complex positive and negative roles of TPL-2 in immune and inflammatory responses.

IRAK1-independent pathways required for the interleukin-1-stimulated activation of the Tpl2 catalytic subunit and its dissociation from ABIN2

The protein kinase Tpl2 (tumour progression locus 2) is activated by LPS (lipopolysaccharide), TNFalpha (tumour necrosis factor alpha) and IL (interleukin)-1. Activation of the native Tpl2 complex by these agonists requires the IKKbeta {IkappaB [inhibitor of NF-kappaB (nuclear factor kappaB)] kinase beta}-catalysed phosphorylation of the p105/NF-kappaB1 subunit and is accompanied by the release of the catalytic subunit from both p105/NF-kappaB1 and another subunit ABIN2 (A20-binding inhibitor of NF-kappaB 2). In the present study we report that IL-1 activates the transfected Tpl2 catalytic subunit in an HEK (human embryonic kidney)-293 cell line that stably expresses the IL-1R (IL-1 receptor), but does not express the protein kinase IRAK1 (IL-1R-associated kinase). In these cells IL-1 does not activate IKKbeta or induce the phosphorylation of p105/NF-kappaB1, and nor does the IKKbeta inhibitor PS1145 prevent the IL-1-induced activation of transfected Tpl2. However, the IL-1-stimulated activation of transfected Tpl2 in IRAK1-null cells or activation of the endogenous Tpl2 complex in IRAK1-expressing cells is suppressed by the protein kinase inhibitor PP2 by a mechanism that does not involve inhibition of Src family protein tyrosine kinases. The IL-1-stimulated activation of transfected Tpl2 is accompanied by its phosphorylation at Thr290 and Ser400 and by enhanced phosphorylation of Ser62, which we demonstrate are autophosphorylation events catalysed by Tpl2 itself. We further show that IL-1 triggers the dissociation of Tpl2 from co-transfected ABIN2 in IRAK1-null IL-1R cells, which is not suppressed by PP2 or by the inhibition of Tpl2 or IKKbeta. These studies identify two new signalling events involved in activation of the native Tpl2 complex by IL-1. First, the IRAK1-, IKKbeta- and PP2-independent dissociation of Tpl2 from ABIN2; secondly, the IRAK1- and IKKbeta-independent, but PP2-sensitive, activation of the Tpl2 catalytic subunit.

ABIN-1 negatively regulates NF-kappaB by inhibiting processing of the p105 precursor

p105 plays dual roles in NF-kappaB signaling: in its precursor form it inhibits NF-kappaB activation, but limited processing by the ubiquitin system generates the p50 active subunit of the transcription factor. Here we show that ABIN-1, an A20-binding protein that is also known to attenuate NF-kappaB activation, inhibits p105 processing. p105 and ABIN-1 physically interact with one another, but the binding is not necessary for inhibition of processing. Rather, it appears to stabilize ABIN-1 and to increase its level, which further augments its inhibitory effect. Deletion of the processing inhibitory domain (PID) of p105 abrogates the inhibition which also requires the ABIN homology domain (AHD)-2 of ABIN-1. Together, the effects of ABIN-1 on p105 processing and of p105 on stabilizing ABIN-1 act to potentiate the NF-kappaB inhibitory activity of ABIN-1.

ABINs: A20 binding inhibitors of NF-kappa B and apoptosis signaling

ABINs have been described as three different proteins (ABIN-1, ABIN-2, ABIN-3) that bind the ubiquitin-editing nuclear factor-kappaB (NF-kappaB) inhibitor protein A20 and which show limited sequence homology. Overexpression of ABINs inhibits NF-kappaB activation by tumor necrosis factor (TNF) and several other stimuli. Similar to A20, ABIN-1 and ABIN-3 expression is NF-kappaB dependent, implicating a potential role for the A20/ABIN complex in the negative feedback regulation of NF-kappaB activation. Adenoviral gene transfer of ABIN-1 has been shown to reduce NF-kappaB activation in mouse liver and lungs. However, ABIN-1 as well as ABIN-2 deficient mice exhibit only slightly increased or normal NF-kappaB activation, respectively, possibly reflecting redundant NF-kappaB inhibitory activities of multiple ABINs. Other functions of ABINs might be non-redundant. For example, ABIN-1 shares with A20 the ability to inhibit TNF-induced apoptosis and as a result ABIN-1 deficient mice die during embryogenesis due to TNF-dependent fetal liver apoptosis. On the other hand, ABIN-2 is required for optimal TPL-2 dependent extracellularly regulated kinase activation in macrophages treated with TNF or Toll-like receptor ligands. ABINs have recently been shown to contain an ubiquitin-binding domain that is essential for their NF-kappaB inhibitory and anti-apoptotic activities. In this context, ABINs were proposed to function as adaptors between ubiquitinated proteins and other regulatory proteins. Alternatively, ABINs might disrupt signaling complexes by competing with other ubiquitin-binding proteins for the binding to specific ubiquitinated targets. Altogether, these findings implicate an important role for ABINs in the regulation of immunity and tissue homeostasis.

Identification of a selective thieno[2,3-c]pyridine inhibitor of COT kinase and TNF-alpha production

COT (Tpl2 in mice) is a serine/threonine MAP3 kinase that regulates production of TNF-alpha and other pro-inflammatory cytokines such as IL-1beta via the ERK/MAP kinase pathway. As TNF-alpha and IL-1beta are clinically validated targets for therapeutic intervention in rheumatoid arthritis (RA), blocking COT provides a potential avenue for amelioration of disease. Herein we describe identification of a cellular active selective small molecule inhibitor of COT kinase.

Proteolysis of NF-kappaB1 p105 is essential for T cell antigen receptor-induced proliferation

To investigate the importance of proteolysis of NF-kappaB1 p105 induced by the kinase IKK in activation of the transcription factor NF-kappaB, we generated 'Nfkb1(SSAA/SSAA)' mice, in which the IKK-target serine residues of p105 were substituted with alanine. Nfkb1(SSAA/SSAA) mice had far fewer CD4+ regulatory and memory T cells because of cell-autonomous defects. These T cell subtypes require activation of NF-kappaB by the T cell antigen receptor for their generation, and the Nfkb1(SSAA) mutation resulted in less activation of NF-kappaB in CD4+ T cells and proliferation of CD4+ T cells after stimulation of the T cell antigen receptor. The Nfkb1(SSAA) mutation also blocked the ability of CD4+ T cells to provide help to wild-type B cells during a primary antibody response. IKK-induced p105 proteolysis is therefore essential for optimal T cell antigen receptor-induced activation of NF-kappaB and mature CD4+ T cell function.

Tpl-2/Cot and COX-2 in breast cancer

BACKGROUND

Breast cancer is the most common cancer in women worldwide and although mortality (129,000/year) stagnates, incidence (370,000/year) is increasing. In addition to histological type, grade, stage, hormonal and c-erbB2 status there is therefore a strong need for new and reliable prognostic and predictive factors.

METHODS AND RESULTS

This minireview focuses on two potential prognostic and predictive candidates Tpl2/Cot and COX-2 and summarise information about them.

CONCLUSION

Tumor progression locus 2 (Tpl2/Cot) is a serine/threonine protein kinase belonging to the family of MAP3 kinases. Activated Tpl2/Cot leads to induction of ERK1/2, JNK, NF-kappaB and p38MAPK pathways. The first study on Tpl2/Cot mRNA in breast cancer showed its increase in 40 % of cases of breast cancer but no available data exist on protein expression. Cyclo-oxygenase 2 (COX-2) is inducible by growth and inflammatory factors and contributes to the development of various tumours. Expression of COX-2 in breast cancer varied from 5-100 % in reviewed papers with significantly higher values in poorly differentiated tumours. Tpl2/Cot and COX-2 have their importance in different intracellular pathways and some of these are involved in cancer development. Briefly, the results from recent studies suggest that Tpl2/Cot and COX-2 could be prognostic factors in breast cancer.

Interleukin-1 (IL-1) induces the Lys63-linked polyubiquitination of IL-1 receptor-associated kinase 1 to facilitate NEMO binding and the activation of IkappaBalpha kinase

Interleukin 1 (IL-1) has been reported to stimulate the polyubiquitination and disappearance of IL-1 receptor-associated kinase 1 (IRAK1) within minutes. It has been thought that the polyubiquitin chains attached to IRAK1 are linked via Lys48 of ubiquitin, leading to its destruction by the proteasome and explaining the rapid IL-1-induced disappearance of IRAK1. In this paper, we demonstrate that IL-1 stimulates the formation of K63-pUb-IRAK1 and not K48-pUb-IRAK1 and that the IL-1-induced disappearance of IRAK1 is not blocked by inhibition of the proteasome. We also show that IL-1 triggers the interaction of K63-pUb-IRAK1 with NEMO, a regulatory subunit of the IkappaBalpha kinase (IKK) complex, but not with the NEMO[D311N] mutant that cannot bind K63-pUb chains. Moreover, unlike wild-type NEMO, the NEMO[D311N] mutant was unable to restore IL-1-stimulated NF-kappaB-dependent gene transcription to NEMO-deficient cells. Our data suggest a model in which the recruitment of the NEMO-IKK complex to K63-pUb-IRAK1 and the recruitment of the TAK1 complex to TRAF6 facilitate the TAK1-catalyzed activation of IKK by the TRAF6-IRAK1 complex.

A Saccharomyces cerevisiae autoselection system for optimised recombinant protein expression

Yeasts are attractive organisms for recombinant protein production. They combine highly developed genetic systems and ease of use with reductions in time and costs. We describe an autoselection system for recombinant protein expression in Saccharomyces cerevisiae which increases yields 5-10-fold compared to conditional selection for expression plasmids. Multicopy expression plasmids encoding essential MOB1 or CDC28 genes are absolutely necessary for the viability of host cells with mob1 or cdc28 deletions in their genomes. Such plasmids are stably maintained, even in rich medium, so optimising biomass production and yields of recombinant protein. Plasmid copy numbers are also increased by limiting selective MOB1 and CDC28 gene expression prior to induction. GST- or 6His-tagged proteins are produced for affinity purification and are expressed from a conditional GAL1-10 promoter to avoid potentially toxic effects of recombinant proteins on growth. Autoselection systems for expressing single or pairs of proteins are described. We demonstrate the versatility of this system by expressing proteins from a number of organisms and include several large and problematic products. The in vitro reconstruction of a step in mitotic regulation shows how this expression system can be successfully applied to the detailed analysis of complex metabolic pathways.

Phosphorylation of TPL-2 on serine 400 is essential for lipopolysaccharide activation of extracellular signal-regulated kinase in macrophages

Tumor progression locus 2 (TPL-2) kinase is essential for Toll-like receptor 4 activation of the mitogen-activated protein kinase extracellular signal-regulated kinase (ERK) and for upregulation of the inflammatory cytokine tumor necrosis factor (TNF) in lipopolysaccharide (LPS)-stimulated macrophages. LPS activation of ERK requires TPL-2 release from associated NF-kappaB1 p105, which blocks TPL-2 access to its substrate, the ERK kinase MEK. Here we demonstrate that TPL-2 activity is also regulated independently of p105, since LPS stimulation was still needed for TPL-2-dependent activation of ERK in Nfkb1(-/-) macrophages. In wild-type macrophages, LPS induced the rapid phosphorylation of serine (S) 400 in the TPL-2 C-terminal tail. Mutation of this conserved residue to alanine (A) blocked the ability of retrovirally expressed TPL-2 to induce the activation of ERK in LPS-stimulated Nfkb1(-/-) macrophages. TPL-2(S400A) expression also failed to reconstitute LPS activation of ERK and induction of TNF in Map3k8(-/-) macrophages, which lack endogenous TPL-2. Consistently, the S400A mutation was found to block LPS stimulation of TPL-2 MEK kinase activity. Thus, induction of TPL-2 MEK kinase activity by LPS stimulation of macrophages requires TPL-2 phosphorylation on S400, in addition to its release from NF-kappaB1 p105. Oncogenic C-terminal truncations of TPL-2 that remove S400 could promote its transforming potential by eliminating this critical control step.

Coordinating TLR‐activated signaling pathways in cells of the immune system

Toll-like receptor (TLR) signaling leads to the activation of mitogen-activated protein kinase and nuclear factor-kappaB signaling pathways. While the upstream signaling events initiated at the level of adaptors and the activation of the downstream signaling pathways have received a lot of attention, our understanding of how these signaling pathways are coordinated to regulate gene expression is poorly understood. This review gives a selective overview on our current understanding of signaling downstream of TLRs, with an emphasis on how the upstream kinases like the mitogen-activated protein kinase kinase kinases (TAK1 and Tpl2) and inhibitor of kappa-B kinase (IKK) coordinate the signaling events that steer the course of an immune response.

ABIN-3: a molecular basis for species divergence in interleukin-10-induced anti-inflammatory actions

Whereas interleukin-10 (IL-10) is an anti-inflammatory cytokine known to regulate macrophage activation, its full mechanism of action remains incompletely defined. In a screen to identify novel IL-10-induced genes, we cloned the mouse ortholog of human ABIN-3 (also termed LIND). ABIN-3 expression was induced selectively by IL-10 in both mouse and human mononuclear phagocytes coordinately undergoing proinflammatory responses. In contrast to the previously characterized ABINs, mouse ABIN-3 was incapable of inhibiting NF-kappaB activation by proinflammatory stimuli. Generation and analysis of ABIN-3-null mice demonstrated that ABIN-3 is unnecessary for the anti-inflammatory effects of IL-10 as well as for proper negative regulation of NF-kappaB. Conversely, human ABIN-3 was capable of inhibiting NF-kappaB activation in response to signaling from Toll-like receptor, IL-1, and tumor necrosis factor. Enforced expression of human ABIN-3 in human monocytic cells suppressed the cytoplasmic degradation of IkappaBalpha, the activation of NF-kappaB, and the induction of proinflammatory genes. Comparative sequence analyses revealed that mouse ABIN-3 lacks a complete ABIN homology domain, which was required for the functional activity of human ABIN-3. ABIN-3 is, thus, an IL-10-induced gene product capable of attenuating NF-kappaB in human macrophages yet is inoperative in mice and represents a basis for species-specific differences in IL-10 actions.

Interleukin-1 stimulated activation of the COT catalytic subunit through the phosphorylation of Thr290 and Ser62

The protein kinase COT/Tpl2 is activated by interleukin-1 (IL-1), TNFalpha and lipopolysaccharide, and its activation by these agonists involves the IkappaB kinase beta (IKKbeta) catalysed phosphorylation of the p105 regulatory subunit. Here, we show that COT activation also requires catalytic subunit phosphorylation, since IL-1beta induced a 5-10-fold activation of a COT mutant unable to bind p105. Activation was paralleled by the phosphorylation of Thr290 and Ser62 and unaffected by the IKKbeta inhibitor PS1145 at concentrations which prevented the degradation of IkappaBalpha. Mutagenesis experiments indicated that COT activation is initiated by Thr290 phosphorylation catalysed by an IL-1-stimulated protein kinase distinct from IKKbeta, while Ser62 phosphorylation is an autophosphorylation event required for maximal activation.

ABIN-2 is required for optimal activation of Erk MAP kinase in innate immune responses

The TPL-2 MEK kinase is essential for activation of the Erk MAP kinase pathway during innate immune responses. TPL-2 is found in complex with ABIN-2 (A20-binding inhibitor of NF-kappaB 2). Here, using antigen-presenting cells from ABIN-2-deficient mice, we show that ABIN-2 was required for optimal activation of Erk induced by receptors that signal via TPL-2, including Toll-like receptor 4 and tumor necrosis factor receptor 1 in macrophages, and CD40 in B cells. ABIN-2 was necessary for the maintenance of TPL-2 protein stability. In contrast, ABIN-2 deficiency did not affect agonist-induced regulation of transcription factor NF-kappaB. Stimulation of ABIN-2-deficient macrophages via Toll-like receptor 4 showed that different thresholds of Erk signaling were required for optimal induction of tumor necrosis factor and interleukin 1beta. Thus, ABIN-2 acts to positively regulate the Erk signaling potential by stabilizing TPL-2.

Charting protein complexes, signaling pathways, and networks in the immune system

Systematic deciphering of protein-protein interactions has the potential to generate comprehensive and instructive signaling networks and to fuel new therapeutic and diagnostic strategies. Here, we describe how recent advances in high-throughput proteomic technologies, involving biochemical purification methods and mass spectrometry analysis, can be applied systematically to the characterization of protein complexes and the computation of molecular networks. The networks obtained form the basis for further functional analyses, such as knockdown by RNA interference, ultimately leading to the identification of nodes that represent candidate targets for pharmacological exploitation. No individual experimental approach can accurately elucidate all critical modulatory components and biological aspects of a signaling network. Such functionally annotated protein-protein interaction networks, however, represent an ideal platform for the integration of additional datasets. By providing links between molecules, they also provide links to all previous observations associated with these molecules, be they of genetic, pharmacological, or other origin. As exemplified here by the analysis of the tumor necrosis factor (TNF)-alpha/nuclear factor-kappaB (NF-kappaB) signaling pathway, the approach is applicable to any mammalian cellular signaling pathway in the immune system.

Phosphorylation of NF-κB1/p105 by oncoprotein kinase Tpl2: Implications for a novel mechanism of Tpl2 regulation

The oncoprotein kinase Tpl2 plays an essential role in macrophage activation by the bacterial component lipopolysaccharide (LPS). In response to LPS stimulation, Tpl2 phosphorylates a downstream kinase, MEK1, leading to the activation of ERK signaling pathway. Recent studies demonstrate that the NF-kappaB1 precursor protein p105 functions as an inhibitor of Tpl2 and that the LPS-stimulated Tpl2 activation requires p105 degradation. However, how p105 inhibits the signaling function of Tpl2 is not completely understood. We show here that p105 does not inhibit the intrinsic kinase activity of Tpl2. When complexed with p105, Tpl2 remains catalytically active and uses p105 as a substrate. However, the p105-bound Tpl2 is unable to phosphorylate its physiological target, MEK1. These findings suggest that p105 functions as a competitive inhibitor of Tpl2 that blocks its access by MEK1.

MAP kinase kinase kinases and innate immunity

Toll-like receptors, which respond to invariant microbial molecules, and receptors for the proinflammatory cytokines tumour necrosis factor and interleukin-1 are crucial for initiation and regulation of innate immune responses. These receptors activate each of the major mitogen-activated protein (MAP) kinase subtypes, extracellular signal-regulated protein kinases, c-Jun amino-terminal kinases and p38 MAP kinases, which are crucial for cell survival and controlling the expression of immune mediators. Here we discuss recent studies characterizing the specific MAP kinase kinase kinases (MAP 3-kinases) that link MAP kinases to receptors involved in innate immunity and the mechanisms by which the activity of MAP 3-kinases is regulated by such receptors.

Comparative analysis of various in vitro COT kinase assay formats and their applications in inhibitor identification and characterization

Cancer osaka thyroid (COT) is a member of the mitogen-activated protein kinase kinase kinase family of enzymes and plays a pivotal role in tumor necrosis factor-alpha production in macrophages. Consequently, COT is considered to be a promising target for antiinflammatory drug discovery. We describe here the development of in vitro COT assays in several formats and the advantages and disadvantages of each. A cascade assay requires very small amounts of enzyme and can provide a useful tool for high-throughput screening, but it is not desirable for compound mechanistic studies due to complicated kinetics. Direct assays are superior to cascade assays and are suitable for both compound screening and mechanistic studies. Among the direct assays, the homogeneous time-resolved fluorescence (HTRF) format is preferred over the radiometric format due to the robustness, throughput, and ease of use of the HTRF format. When the physiological protein substrate MEK1 (MAP/Erk kinase 1) was used to determine inhibitor potencies, false positives were observed due to compound interference by binding to MEK1. Using a MEK1 peptide substrate, these false positives were eliminated. In addition, we describe a simple method to study the ATP competitiveness of compounds. The knowledge gained through our studies with COT, and the methods described for our assays and compound mechanistic studies, can be readily applied to other kinase targets.

Purification and kinetic characterization of recombinant human mitogen-activated protein kinase kinase kinase COT and the complexes with its cellular partner NF-kappa B1 p105

Cancer osaka thyroid (COT), a human MAP 3 K, is essential for lipopolysaccharide activation of the Erk MAPK cascade in macrophages. COT 30--467 is insoluble, whereas low levels of COT 30--397 can be expressed, but this protein is unstable. However, both COT 30--467 and COT 30--397 are expressed in a soluble and stable form when produced in complex with the C-terminal half of p105. The k(cat) of COT 30--397 is reduced approximately 47--fold in the COT 30--467/p105 Delta N complex. COT prefers Mn(2+) to Mg(2+) as the ATP metal cofactor, exhibiting an unusually high ATP K(m) in the presence of Mg(2+). When using Mn(2+) as the cofactor, the ATP K(m) is reduced to a level typical of most kinases. In contrast, the binding affinity of COT for its other substrate MEK is cofactor independent. Our results using purified proteins indicate that p105 binding improves COT solubility and stability while down-regulating kinase activity, consistent with cellular data showing that p105 functions as an inhibitor of COT.

The NF-κB signalling pathway: a therapeutic target in lymphoid malignancies?

Nuclear factor-kappaB/reticuloendotheliosis (NF-kappaB/Rel) designates a family of transcription factors that influence the activation of a multitude of genes critically involved in immune and inflammatory responses. Recently, genetic and biochemical evidence has accumulated, suggesting that constitutive activation of NF-kappaB/Rel proteins plays an important role in the development/progression of B and T cell lymphoid malignancies. In particular, genetic and molecular alterations of NF-kappaB family members and their transcriptional target genes have been implicated in the development of diffuse large B cell lymphoma and mucosa-associated lymphoid tissue lymphoma. Although NF-kappaB/Rel proteins represent an integrating point of several pathways, potentially contributing to several diseases, their unique activation depends on cell type and stimulus. Considering the NF-kappaB specificity in lymphoid cells, molecules that finely modulate the activity of these NF-kappaB components and dampen the inappropriate proliferation of lymphocytes may represent a novel pharmacological intervention to several lymphoid malignancies.

Lipopolysaccharide activation of the TPL-2/MEK/extracellular signal-regulated kinase mitogen-activated protein kinase cascade is regulated by IkappaB kinase-induced proteolysis of NF-kappaB1 p105

The MEK kinase TPL-2 (also known as Cot) is required for lipopolysaccharide (LPS) activation of the extracellular signal-regulated kinase (ERK) mitogen-activated protein (MAP) kinase cascade in macrophages and consequent upregulation of genes involved in innate immune responses. In resting cells, TPL-2 forms a stoichiometric complex with NF-kappaB1 p105, which negatively regulates its MEK kinase activity. Here, it is shown that lipopolysaccharide (LPS) stimulation of primary macrophages causes the release of both long and short forms of TPL-2 from p105 and that TPL-2 MEK kinase activity is restricted to this p105-free pool. Activation of TPL-2, MEK, and ERK by LPS is also demonstrated to require proteasome-mediated proteolysis. p105 is known to be proteolysed by the proteasome following stimulus-induced phosphorylation of two serines in its PEST region by the IkappaB kinase (IKK) complex. Expression of a p105 point mutant, which is not susceptible to signal-induced proteolysis, in RAW264.7 macrophages impairs LPS-induced release of TPL-2 from p105 and its subsequent activation of MEK. Furthermore, expression of wild-type but not mutant p105 reconstitutes LPS stimulation of MEK and ERK phosphorylation in primary NF-kappaB1-deficient macrophages. Consistently, pharmacological blockade of IKK inhibits LPS-induced release of TPL-2 from p105 and TPL-2 activation. These data show that IKK-induced p105 proteolysis is essential for LPS activation of TPL-2, thus revealing a novel function of IKK in the regulation of the ERK MAP kinase cascade.

Phosphorylation of threonine 290 in the activation loop of Tpl2/Cot is necessary but not sufficient for kinase activity

Cot/Tpl2/MAP3K8 is a serine/threonine kinase known to activate the ERK, p38, and JNK kinase pathways. Studies of Tpl2 knock-out mice reveal a clear defect in tumor necrosis factor-alpha production, although very little detail is known about its regulation and the signaling events involved. In the present study we demonstrated that phosphorylation of Cot was required for its maximal activity as phosphatase treatment of Cot decreased its kinase activity. The Cot sequence contains a conserved threonine at position 290 in the activation loop of the kinase domain. We found that mutation of this residue to alanine eliminated its ability to activate MEK/ERK and NF-kappaB pathways, whereas a phosphomimetic mutation to aspartic acid could rescue the ability to activate MEK. Thr-290 was also required for robust autophosphorylation of Cot. Antibody generated to phospho-Thr-290-Cot recognized both wild-type and kinase-dead Cot, suggesting that phosphorylation of Thr-290 did not occur through autophosphorylation but via another kinase. We showed that Cot was constitutively phosphorylated at Thr-290 in transfected human embryonic kidney 293T cells as well as human monocytes as this residue was phosphorylated in unstimulated and lipopolysaccharide-stimulated cells to the same degree. Treatment with herbimycin A inhibited Cot activity in the MEK/ERK pathway but did not inhibit phosphorylation at Thr-290. Together these results showed that phosphorylation of Cot at Thr-290 is necessary but not sufficient for full kinase activity in the MEK/ERK pathway.

Functions of NF-kappaB1 and NF-kappaB2 in immune cell biology

Two members of the NF-kappaB (nuclear factor kappaB)/Rel transcription factor family, NF-kappaB1 and NF-kappaB2, are produced as precursor proteins, NF-kappaB1 p105 and NF-kappaB2 p100 respectively. These are proteolytically processed by the proteasome to produce the mature transcription factors NF-kappaB1 p50 and NF-kappaB2 p52. p105 and p100 are known to function additionally as IkappaBs (inhibitors of NF-kappaB), which retain associated NF-kappaB subunits in the cytoplasm of unstimulated cells. The present review focuses on the latest advances in research on the function of NF-kappaB1 and NF-kappaB2 in immune cells. NF-kappaB2 p100 processing has recently been shown to be stimulated by a subset of NF-kappaB inducers, including lymphotoxin-beta, B-cell activating factor and CD40 ligand, via a novel signalling pathway. This promotes the nuclear translocation of p52-containing NF-kappaB dimers, which regulate peripheral lymphoid organogenesis and B-lymphocyte differentiation. Increased p100 processing also contributes to the malignant phenotype of certain T- and B-cell lymphomas. NF-kappaB1 has a distinct function from NF-kappaB2, and is important in controlling lymphocyte and macrophage function in immune and inflammatory responses. In contrast with p100, p105 is constitutively processed to p50. However, after stimulation with agonists, such as tumour necrosis factor-alpha and lipopolysaccharide, p105 is completely degraded by the proteasome. This releases associated p50, which translocates into the nucleus to modulate target gene expression. p105 degradation also liberates the p105-associated MAP kinase (mitogen-activated protein kinase) kinase kinase TPL-2 (tumour progression locus-2), which can then activate the ERK (extracellular-signal-regulated kinase)/MAP kinase cascade. Thus, in addition to its role in NF-kappaB activation, p105 functions as a regulator of MAP kinase signalling.