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NF- κ B transcription factors promote survival in numerous cell types via induction of antiapoptotic genes. Pharmacological blockade of the IKK2 kinase with AS602868, a specific inhibitor that competes with ATP binding, prevented TNF- α -induced NF- κ B activation in Jurkat leukemic T cells. While TNF- α by itself had no effect on Jurkat survival, the addition of AS602868 induced cell death, visualized by DNA fragmentation and sub-G1 analysis. A disruption of the mitochondrial potential followed by activation of caspases 9 and 3 was observed in cells treated by the combination TNF- α +AS602868. Quantitative real-time PCR demonstrated that AS602868 prevented TNF- α induction of the antiapoptotic genes coding for c-IAP-2, Bclx, Bfl-1/A1 and Traf-1. The use of a specific IKK2 inhibitor appears, therefore, as an interesting pharmaceutical strategy to increase the cell's sensitivity towards apoptotic effectors.

Inhibitor of κB (IκB) kinase (IKK) phosphorylates IκB proteins, leading to their degradation and the liberation of nuclear factor κB for gene transcription. Here we report the crystal structure of IKKβ in complex with an inhibitor, at a resolution of 3.6 Å. The structure reveals a trimodular architecture comprising the kinase domain, a ubiquitin-like domain (ULD) and an elongated, α-helical scaffold/dimerization domain (SDD). Unexpectedly, the predicted leucine zipper and helix–loop–helix motifs do not form these structures but are part of the SDD. The ULD and SDD mediate a critical interaction with IκBα that restricts substrate specificity, and the ULD is also required for catalytic activity. The SDD mediates IKKβ dimerization, but dimerization per se is not important for maintaining IKKβ activity and instead is required for IKKβ activation. Other IKK family members, IKKα, TBK1 and IKK-i, may have a similar trimodular architecture and function. Structure of inhibitor of κB kinase IKK (inhibitor of κB kinase) is an important element in the activation of nuclear factor κB (NF-κB) transcription factors — master regulators of inflammatory, immune and apoptotic responses. Here Wu and colleagues describe the long awaited X-ray structure of a member of the IKK family in combination with an inhibitor. They show that IKKβ has a tri-molecular architecture that contains the kinase domain, a ubiquitin-like domain and an extended scaffolding and dimerization domain, and discuss the functional implications.

Purpose This study was conducted to investigate the potential neuroprotective effect of IL-6 on chemotherapy induced neuropathy (CIN). IL-6 was compared to four-methylcatechol (4-MC)-a known inducer of NGF secretion previously shown to exhibit neuroprotective effects in CIN models. Methods Three CIN models were used; two in rats (cisplatin and vincristine) and one in mice (paclitaxel). IL-6 was delivered in four different doses in rats (0.3, 1, 3, 10 μg/kg, sc) every day from the first day of chemotherapeutic agent intoxication until the end of the study (day 37 for cisplatin protocol and day 30 for vincristine procedure). In mice, IL-6 was delivered at 10 μg/kg, sc either daily or three times a week from the first day of intoxication until the end of the study (day 19). Behavioral testings (hot plate and rotarod), nerve conduction studies (CMAP, SNCV, H-wave) and histo-morphometric analysis were done for all models. In addition, we tested whether IL-6 interfered with the tumor-reducing effects of the chemotherapeutic agents. Results IL-6 treatment prevented the behavioral and electrophysiological abnormalities produced by vincristine, cisplatin and Taxol intoxication, and similarly prevented the pathological changes in peripheral nerves. The neuroprotective action of chronic IL-6 treatment was at least equal to that of 4-MC. In addition, IL-6 neither inhibited the antitumour activity of cisplatin, nor stimulated tumour growth. Conclusion IL-6 at low doses (10 μg/kg) provided protection against the development of CIN without demonstrating interference with the anti tumoural activity of these anti-mitotic drugs.

The lymphocyte activation gene-3 (LAG-3), selectively transcribed in human activated T and NK cells, encodes a ligand for major histocompatibility complex (MHC) class II molecules. Like CD4, LAG-3 ectodomain is composed of four Ig-like domains (D1-D4). Nothing is known about the LAG-3 regions or residues required to form a stable MHC class II binding site. In contrast to CD4, soluble LAG-3 molecules stably interact with MHC class II molecules expressed on the cell surface. In addition, the first two N-terminal domains of soluble LAG-3 (D1 and D2) molecules, alone, are capable of binding MHC class II. From a LAG-3 model structure, we designed mutants and tested their ability to bind MHC class II molecules in an intercellular adhesion assay. We found residues on the membrane-distal, CDR1-2-containing top face of D1 that are essential for either binding or repulsing MHC class II proteins. Most of these residues are clustered at the base of a large extra-loop structure that is a hallmark of the LAG-3 D1 Ig-like domain. In addition, as for CD4, oligomerization of LAG-3 on the cell surface may be required to form a stable MHC binding site because mutation of three residues in the ABED β -strands containing side of D1 results in a dominant negative effect (i.e., binding inhibition of coexpressed wild-type LAG-3).

Inhibitor of [kappa]B (I[kappa]B) kinase (IKK) phosphorylates I[kappa]B proteins, leading to their degradation and the liberation of nuclear factor [kappa]B for gene transcription. Here we report the crystal structure of IKK[beta] in complex with an inhibitor, at a resolution of 3.6 Å. The structure reveals a trimodular architecture comprising the kinase domain, a ubiquitin-like domain (ULD) and an elongated, [alpha]-helical scaffold/dimerization domain (SDD). Unexpectedly, the predicted leucine zipper and helix-loop-helix motifs do not form these structures but are part of the SDD. The ULD and SDD mediate a critical interaction with I[kappa]B[alpha] that restricts substrate specificity, and the ULD is also required for catalytic activity. The SDD mediates IKK[beta] dimerization, but dimerization per se is not important for maintaining IKK[beta] activity and instead is required for IKK[beta] activation. Other IKK family members, IKK[alpha], TBK1 and IKK-i, may have a similar trimodular architecture and function.

Purpose The need for new treatment options for acute myeloid leukemia (AML) is increasing. AS602868 is a novel investigational drug with reported activity on AML cells. Methods We studied gene expression profiles in AML blasts exposed to AS602868 in order to better understand its mechanism of action. We analyzed the in vitro cytotoxicity of AS602868 alone or in combination with daunorubicin, etoposide or cytarabine. To document AS602868-induced IKK2 inhibition in fresh AML cells, a flow cytometry analysis of IκB was performed. Finally, the effect of AS602868 on gene expression in fresh AML cells was analyzed. Results The results show that AML cells are globally as sensitive to AS602868 as they are to cytarabine, with large interindividual variations. Combinations with conventional antileukemic agents showed enhanced cytotoxic activity in subsets of patients. IKK2 appeared to be effectively inhibited by 100 μM AS602868 in fresh leukemic cells. Gene expression profiling and gene ontology analyses identified several groups of genes induced/inhibited by exposure to AS602868 and/or exhibiting a correlation with sensitivity to this agent in vitro. Of note, the expression of several genes related to immune function was found to be significantly altered after exposure to AS602868. Conclusion These data suggest that AS602868 is cytotoxic against fresh human AML blasts and provide insights regarding the mechanisms of cytotoxicity.

PURPOSE: The need for new treatment options for acute myeloid leukemia (AML) is increasing. AS602868 is a novel investigational drug with reported activity on AML cells. METHODS: We studied gene expression profiles in AML blasts exposed to AS602868 in order to better understand its mechanism of action. We analyzed the in vitro cytotoxicity of AS602868 alone or in combination with daunorubicin, etoposide or cytarabine. To document AS602868-induced IKK2 inhibition in fresh AML cells, a flow cytometry analysis of IκB was performed. Finally, the effect of AS602868 on gene expression in fresh AML cells was analyzed. RESULTS: The results show that AML cells are globally as sensitive to AS602868 as they are to cytarabine, with large interindividual variations. Combinations with conventional antileukemic agents showed enhanced cytotoxic activity in subsets of patients. IKK2 appeared to be effectively inhibited by 100 μM AS602868 in fresh leukemic cells. Gene expression profiling and gene ontology analyses identified several groups of genes induced/inhibited by exposure to AS602868 and/or exhibiting a correlation with sensitivity to this agent in vitro. Of note, the expression of several genes related to immune function was found to be significantly altered after exposure to AS602868. CONCLUSION: These data suggest that AS602868 is cytotoxic against fresh human AML blasts and provide insights regarding the mechanisms of cytotoxicity.

NF-kappaB transcription factors promote survival in numerous cell types via induction of antiapoptotic genes. Pharmacological blockade of the IKK2 kinase with AS602868, a specific inhibitor that competes with ATP binding, prevented TNF-alpha-induced NF-kappaB activation in Jurkat leukemic T cells. While TNF-alpha by itself had no effect on Jurkat survival, the addition of AS602868 induced cell death, visualized by DNA fragmentation and sub-G1 analysis. A disruption of the mitochondrial potential followed by activation of caspases 9 and 3 was observed in cells treated by the combination TNF-alpha+AS602868. Quantitative real-time PCR demonstrated that AS602868 prevented TNF-alpha induction of the antiapoptotic genes coding for c-IAP-2, Bclx, Bfl-1/A1 and Traf-1. The use of a specific IKK2 inhibitor appears, therefore, as an interesting pharmaceutical strategy to increase the cell's sensitivity towards apoptotic effectors.

T-cell-based adoptive immunotherapy is a new pillar of cancer care. Tumor-redirected B cells could also contribute to therapy if their manipulation to rewire immunoglobulin (Ig) genes is mastered. We designed a single-chain Ig-encoding cassette (“scFull-Ig”) that redirects antigen specificity when inserted at a single position of the IgH locus. This design, which places combined IgH and IgL variable genes downstream of a pVH promoter, nevertheless preserves all Ig functional domains and the intrinsic mechanisms that regulate expression from the IgM B cell receptor (BCR) expression to Ig secretion, somatic hypermutation and class switching. This single-locus editing provides an efficient and safe strategy to both disrupt endogenous Ig expression and encode a new Ig paratope. As a proof of concept, the functionality of scFull BCR and/or secreted Ig was validated against two different classical human tumor antigens, HER2 and hCD20. Once validated in cell lines, the strategy was extended to primary B cells, confirming the successful engineering of BCR and Ig expression and the ability of scFull-Ig to undergo further class switching. These results further pave the way for future B cell-based adoptive immunotherapy and strategies to express a therapeutic mAb with a variety of switched H-chains that provide complementary functions.

Cystic fibrosis (CF) is caused by defective Cystic Fibrosis Transmembrane Conductance Regulator (CFTR) protein. Morbidity is mainly due to early airway infection. We hypothesized that S. aureus clearance during the first hours of infection was impaired in CF human Airway Surface Liquid (ASL) because of a lowered pH. The ASL pH of human bronchial epithelial cell lines and primary respiratory cells from healthy controls (WT) and patients with CF was measured with a pH microelectrode. The antimicrobial capacity of airway cells was studied after S. aureus apical infection by counting surviving bacteria. ASL was significantly more acidic in CF than in WT respiratory cells. This was consistent with a defect in bicarbonate secretion involving CFTR and SLC26A4 (pendrin) and a persistent proton secretion by ATP12A. ASL demonstrated a defect in S. aureus clearance which was improved by pH normalization. Pendrin inhibition in WT airways recapitulated the CF airway defect and increased S. aureus proliferation. ATP12A inhibition by ouabain decreased bacterial proliferation. Antimicrobial peptides LL-37 and hBD1 demonstrated a pH-dependent activity. Normalizing ASL pH might improve innate airway defense in newborns with CF during onset of S. aureus infection. Pendrin activation and ATP12A inhibition could represent novel therapeutic strategies to normalize pH in CF airways.