Cellular and Mathematical Analyses of LUBAC Involvement in T Cell Receptor-Mediated NF-κB Activation Pathway.

The LUBAC ubiquitin ligase complex, composed of the HOIP, HOIL-1L, and SHARPIN subunits, stimulates the canonical nuclear factor-κB (NF-κB) activation pathways through its Met1-linked linear ubiquitination activity. Here we performed cellular and mathematical modeling analyses of the LUBAC involvement in the T cell receptor (TCR)-mediated NF-κB activation pathway, using the Jurkat human T cell line. LUBAC is indispensable for TCR-induced NF-κB and T cell activation, and transiently associates with and linearly ubiquitinates the CARMA1-BCL10-MALT1 (CBM) complex, through the catalytic HOIP subunit. In contrast, the linear ubiquitination of NEMO, a substrate of the TNF-α-induced canonical NF-κB activation pathway, was limited during the TCR pathway. Among deubiquitinases, OTULIN, but not CYLD, plays a major role in downregulating LUBAC-mediated TCR signaling. Mathematical modeling indicated that linear ubiquitination of the CBM complex accelerates the activation of IκB kinase (IKK), as compared with the activity induced by linear ubiquitination of NEMO alone. Moreover, simulations of the sequential linear ubiquitination of the CBM complex suggested that the allosteric regulation of linear (de)ubiquitination of CBM subunits is controlled by the ubiquitin-linkage lengths. These results indicated that, unlike the TNF-α-induced NF-κB activation pathway, the TCR-mediated NF-κB activation in T lymphocytes has a characteristic mechanism to induce LUBAC-mediated NF-κB activation.

Critical roles of IκBα and RelA phosphorylation in transitional oscillation in NF-κB signaling module.

The transcription factor NF-κB performs various cell functions, such as regulating proliferation and differentiation and blocking apoptosis, by inducing the expression of multiple genes. The shuttling of NF-κB between the cytoplasm and nucleus is involved in its transcriptional activity in the canonical NF-κB pathway. The transcription of the NF-κB target genes is regulated by the phosphorylation of both IκBα and the RelA subunit of NF-κB, suggesting that these phosphorylation events are crucial for the oscillation. In this study, we constructed a new mathematical model of NF-κB activation to explore the modulation of the oscillation by the phosphorylation of IκBα and RelA. Based on a stability analysis around the equilibrium point, we confirmed that IκBα phosphorylation added a structure with a stable periodic solution to the phosphorylation model. The stable periodic solution appeared to transiently respond to the attenuation of the concentration of active IKKß. Because the NF-κB oscillation is caused by the periodic solution, the amplitude and period of the NF-κB oscillation in the phosphorylation model was constant regardless of the initial conditions; we defined this property as the reproducibility of the oscillation. On the other hand, the amplitude and period of the NF-κB oscillation depended on a parameter related to the RelA phosphorylation, suggesting that the oscillation period is regulated by RelA phosphorylation. In addition, the region of the periodic solution that is dependent on active IKKß also depends on a parameter related to RelA phosphorylation. Therefore, we conclude that the phosphorylation of both IκBα and RelA regulates the robustness of the NF-κB signaling module oscillation. That is, by appropriately controlling the phosphorylation process, it becomes possible to control the NF-κB oscillation and appropriately induce the NFkB-dependent expression gene. We anticipate that this study will contribute to the future elucidation of the mechanism underlying the nuclear cytoplasmic (N-C) oscillation of NF-κB.

Safety and effectiveness of daclatasvir and asunaprevir dual therapy in patients with genotype 1 chronic hepatitis C: results from postmarketing surveillance in Japan.

BACKGROUND: Safety and effectiveness of daclatasvir (DCV)/asunaprevir (ASV) dual therapy were demonstrated in Japanese patients with chronic hepatitis C (CHC) genotype (GT) 1b in phase III studies. This postmarketing surveillance (PMS) was conducted to assess the safety and effectiveness of DCV/ASV in Japanese patients with GT-1 CHC treated in routine clinical practice. METHODS: This PMS was conducted between September 2014 and February 2017 at 261 centers in Japan. Patients with GT-1 CHC with or without compensated cirrhosis starting DCV and ASV dual therapy were observed from treatment initiation until 24 weeks after completing treatment. Safety and effectiveness assessments included incidence of adverse drug reactions (ADRs) and sustained viral response (SVR) rates at 24 weeks (SVR24). RESULTS: Of 2820 patients (median age, 71.0 years; ≥ 65 years, 73.1%; female, 56.1%; with compensated cirrhosis, 39.1%) in the safety population, 726 (25.7%) experienced 1063 ADRs and 47 (1.7%) experienced 55 serious ADRs. Overall, 532 hepatic ADRs were reported; most hepatic ADRs occurred between > 4 and ≤ 12 weeks after treatment initiation. Subgroup analysis showed a higher incidence of ADRs in female, elderly, underweight, and renal function-impaired patients. SVR24 and SVR at 12 weeks (SVR12) were 87.3% (2216/2538) and 88.4% (2284/2584), respectively. Patients without (SVR12, 89.1%; SVR24, 87.9%) and with (SVR12, 87.3%; SVR24, 86.3%) compensated cirrhosis had similar SVR rates. CONCLUSION: Results from this large PMS indicate that DCV and ASV dual therapy is generally well tolerated and effective in routine clinical practice in Japanese patients with GT-1 CHC with or without compensated cirrhosis.

Roles of NADPH-P450 reductase and apo- and holo-cytochrome b5 on xenobiotic oxidations catalyzed by 12 recombinant human cytochrome P450s expressed in membranes of Escherichia coli.

Drug oxidation activities of 12 recombinant human cytochrome P450s (P450) coexpressed with human NADPH-P450 reductase (NPR) in bacterial membranes (P450/NPR membranes) were determined and compared with those of other recombinant systems and those of human liver microsomes. Addition of exogenous membrane-bound NPR to the P450/NPR membranes enhanced the catalytic activities of CYP2C8, CYP2C9, CYP2C19, CYP3A4, and CYP3A5. Enhancement of activities of CYP1A1, CYP1A2, CYP1B1, CYP2A6, CYP2B6, CYP2D6, and CYP2E1 in membranes was not observed after the addition of NPR (4 molar excess to each P450). Exogenous purified human cytochrome b5 (b5) further enhanced catalytic activities of CYP2A6, CYP2B6, CYP2C8, CYP2E1, CYP3A4, and CYP3A5/NPR membranes. Catalytic activities of CYP2C9 and CYP2C19 were enhanced by addition of b5 in reconstituted systems but not in the P450/NPR membranes. Apo b5 (devoid of heme) enhanced catalytic activities when added to both membrane and reconstituted systems, except for CYP2E1/NPR membranes and the reconstituted system containing purified CYP2E1 and NPR. Catalytic activities in P450/NPR membranes fortified with b5 were roughly similar to those measured with microsomes of insect cells coexpressing P450 with NPR (and b5) and/or human liver microsomes, based on equivalent P450 contents. These results suggest that interactions of P450 and NPR coexpressed in membranes or mixed in reconstituted systems appear to be different in some human CYP2 family enzymes, possibly due to a conformational role of b5. P450/NPR membrane systems containing b5 are useful models for prediction of the rates for liver microsomal P450-dependent drug oxidations.