Human acidic mammalian chitinase (AMCase), a member of the family 18 glycosyl hydrolases, is one of the important proteins involved in Th2-mediated inflammation and has been implicated in asthma and allergic diseases. Inhibition of AMCase results in decreased airway inflammation and airway hyper-responsiveness in a mouse asthma model, suggesting that the AMCase activity is a part of the mechanism of Th2 cytokine-driven inflammatory response in asthma. In this paper, we report the first detailed kinetic characterization of recombinant human AMCase. In contrast with mouse AMCase that has been reported to have a major pH optimum at 2 and a secondary pH optimum around 3-6, human AMCase has only one pH optimum for k(cat)/K(m) between pH 4 and 5. Steady state kinetics shows that human AMCase has "low" intrinsic transglycosidase activity, which leads to the observation of apparent substrate inhibition. This slow transglycosylation may provide a mechanism in vivo for feedback regulation of the chitinase activity of human AMCase. HPLC characterization of cleavage of chitooligosaccharides (4-6-mers) suggests that human AMCase prefers the beta anomer of chitooligosaccharides as substrate. Human AMCase also appears to cleave chitooligosaccharides from the nonreducing end primarily by disaccharide units. Ionic strength modulates the enzymatic activity and substrate cleavage pattern of human AMCase against fluorogenic substrates, chitobiose-4-methylumbelliferyl and chitotriose-4-methylumbelliferyl, and enhances activity against chitooligosaccharides. The physiological implications of these results are discussed.
Post-translational modification catalyzed by phosphopantetheinyl transferases (PPTases) has previously been used to site-specifically label proteins with structurally diverse molecules. PPTase catalysis results in covalent modification of a serine residue in acyl/peptidyl carrier proteins and their surrogate substrates which are typically fused to the N- or C-terminus. To test the utility of PPTases for preparing antibody-drug conjugates (ADCs), we inserted 11 and 12-mer PPTase substrate sequences at 110 constant region loop positions of trastuzumab. Using Sfp-PPTase, 63 sites could be efficiently labeled with an auristatin toxin, resulting in 95 homogeneous ADCs. ADCs labeled in the CH1 domain displayed in general excellent pharmacokinetic profiles and negligible drug loss. A subset of CH2 domain conjugates underwent rapid clearance in mouse pharmacokinetic studies. Rapid clearance correlated with lower thermal stability of the particular antibodies. Independent of conjugation site, almost all ADCs exhibited subnanomolar in vitro cytotoxicity against HER2-positive cell lines. One selected ADC was shown to induce tumor regression in a xenograft model at a single dose of 3 mg/kg, demonstrating that PPTase-mediated conjugation is suitable for the production of highly efficacious and homogeneous ADCs.
Therapeutic use of type I IFN (IFN‐α/β) has become common. Many of the diverse diseases targeted are marked by pathogenetic abnormalities in cell‐mediated immunity (CMI), these cellular immune responses either causing injury to the host, lacking sufficient vigor for virus or tumor clearance, or both. In general, therapeutic efficacy is limited. It is thus notable that the pleiotropic effects of type I IFN on CMI remain poorly understood. We characterized the effects of type I IFN on the production of IL‐12, the central immunoregulatory cytokine of the CD4+ T cell arm of CMI. We show that type I IFN are potent inhibitors of IL‐12 production by human monocytes/macrophages. The underlying mechanism involves transcriptional inhibition of the IL‐12p40 gene, marked by down‐regulation of PU.1 binding activity at the upstream Ets site of the IL‐12p40 promoter. Type I IFN have previously been shown to be able to substitute for IL‐12 in driving IFN‐γ production from T and NK cells. The ability of IFN‐α/β to suppress IL‐12 production while up‐regulating IFN‐γ production suggests a possible mechanistic basis for the difficulties of employing these cytokines in diseases involving abnormalities of CMI.
Therapeutic use of type I IFN (IFN- § / g ) has become common. Many of the diverse diseases targeted are marked by pathogenetic abnormalities in cell-mediated immunity (CMI), these cellular immune responses either causing injury to the host, lacking sufficient vigor for virus or tumor clearance, or both. In general, therapeutic efficacy is limited. It is thus notable that the pleiotropic effects of type I IFN on CMI remain poorly understood. We characterized the effects of type I IFN on the production of IL-12, the central immunoregulatory cytokine of the CD4 + T cell arm of CMI. We show that type I IFN are potent inhibitors of IL-12 production by human monocytes/macrophages. The underlying mechanism involves transcriptional inhibition of the IL-12p40 gene, marked by down-regulation of PU.1 binding activity at the upstream Ets site of the IL-12p40 promoter. Type I IFN have previously been shown to be able to substitute for IL-12 in driving IFN-+ production from T and NK cells. The ability of IFN- § / g to suppress IL-12 production while up-regulating IFN-+ production suggests a possible mechanistic basis for the difficulties of employing these cytokines in diseases involving abnormalities of CMI.
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