Efficacy of a recombinant single-chain fragment variable region, VasSF, as a new drug for vasculitis.

BACKGROUND: Anti-neutrophil cytoplasmic autoantibodies (ANCA) associated vasculitis is a pauci-immune disease with the inflammation of the small blood vessels. The efficacies of antibody drugs for induction therapies of vasculitis vary among cases. Here, we developed a novel clone of a single chain Fv region (ScFv) with vasculitis-specific therapeutic potential. MATERIALS AND METHODS: The clone, termed VasSF, was selected from our Escherichia coli expression library of recombinant human ScFv based on the therapeutic efficacy in an SCG/Kj mouse model of MPO-ANCA-associated vasculitis (MAAV), such as improvement of the urinary score and decreased crescent formation in glomeruli, granulomatous in lung, MPO-ANCA biomarkers, the anti-moesin antibody, and some cytokine levels. RESULTS: We identified vasculitis-associated apolipoprotein A-II (VAP2) as a target molecule of the clone and confirmed the independently-established VAP2 antibodies were also therapeutic in SCG/Kj mice. In MAAV, MPO-ANCA and cytokines stimulate neutrophils by facilitating heterodimer formation of VAP2 with apolipoprotein A-I in HDL. CONCLUSION: VasSF would constitute a novel antibody drug for vasculitis by suppressing the heterodimer formation of the apolipoproteins.

Hypothiocyanous Acid Suppresses PolyI:C-Induced Antiviral Responses by Modulating IRF3 Phosphorylation in Human Airway Epithelial Cells.

Pattern recognition receptors recognize RNA viruses and trigger type I and III interferon (IFN) production and apoptosis to limit viral replication and spread. Some innate immune cells produce oxidants in response to viral infection to protect against invasion. Recent studies have demonstrated the virucidal activity of hypothiocyanous acid (HOSCN), an oxidant generated by the peroxidase-catalyzed reaction of thiocyanate with hydrogen peroxide. However, the effects of HOSCN on host antiviral responses are still unknown. In this study, we aimed to clarify the role of HOSCN in host antiviral responses against RNA viruses in airway epithelial cells using polyinosinic-polycytidylic acid (polyI:C), a mimic of viral RNA. Our results show that HOSCN repressed antiviral responses in NCI-H292 human airway epithelial cells. HOSCN decreased polyI:C-induced apoptosis and the expression levels of IFNB1, IFNL1, IFNL2 and IFNL3 mRNAs. In addition, the induction of other interferon regulatory factor 3 (IRF3)-dependent genes was also suppressed by HOSCN. Further analyses focused on IRF3 revealed that HOSCN inhibited the phosphorylation of IRF3 at Ser386 and Ser396 as well as its dimerization and nuclear translocation by inhibiting the phosphorylation of TANK-binding kinase 1 (TBK1). Furthermore, HOSCN led to the phosphorylation of IRF3 at residues other than Ser386 and Ser396, implying that HOSCN may cause a conformational change in IRF3 to impair its function. Collectively, these results suggest that HOSCN plays a novel signaling role in the antiviral response, acting as a negative regulator of apoptotic and TBK1-IRF3 signaling pathways and limiting IRF3-dependent gene expression.

Nanoscale elongating control of the self-assembled protein filament with the cysteine-introduced building blocks.

Self-assembly of artificially designed proteins is extremely desirable for nanomaterials. Here we show a novel strategy for the creation of self-assembling proteins, named "Nanolego." Nanolego consists of "structural elements" of a structurally stable symmetrical homo-oligomeric protein and "binding elements," which are multiple heterointeraction proteins with relatively weak affinity. We have established two key technologies for Nanolego, a stabilization method and a method for terminating the self-assembly process. The stabilization method is mediated by disulfide bonds between Cysteine-residues incorporated into the binding elements, and the termination method uses "capping Nanolegos," in which some of the binding elements in the Nanolego are absent for the self-assembled ends. With these technologies, we successfully constructed timing-controlled and size-regulated filament-shape complexes via Nanolego self-assembly. The Nanolego concept and these technologies should pave the way for regulated nanoarchitecture using designed proteins.

Dynamic force spectroscopy of the specific interaction between the PDZ domain and its recognition peptides.

To characterize the molecular basis of specific interactions of PDZ proteins, dynamic force spectroscopy (DFS) for the PDZ protein Tax-interacting protein-1 (TIP-1) and its recognition peptide (PDZ-pep) derived from beta-catenin was performed using an atomic force microscope (AFM), together with measurement of thermodynamic and kinetic parameters using surface plasmon resonance (SPR). The unbinding force of this pair was measured under different conditions of AFM tip-retraction velocity. The relationship between the unbinding force and the logarithmic force-loading rate, that is, the dynamic force spectrum, exhibited two different rate regimes, for each of which the forces increased linearly with the force-loading rate. On the basis of the theoretical treatment of the Bell-Evans model, the positions of two different activation barriers in the reaction coordinate and dissociation rate constants in each barrier were evaluated from slopes and x-intercepts of the two linear regimes (first barrier: 0.04 nm and 1.10 x 10 s(-1); second barrier: 0.21 nm and 2.77 x 10(-2) s(-1), respectively). Although two-step unbinding kinetics between TIP-1 and PDZ-pep was suggested from the DFS analysis, SPR results showed single-step dissociation kinetics with a rate constant of 2.89 x 10(-1) s(-1). Different shapes of the free energy profile of the unbinding process were deduced from each result of DFS and SPR. The reason for such topographic differences in the energy landscape is discussed in relation to the differences in the pathways of forced unbinding and spontaneous dissociation.