Role of the Abelson Tyrosine Kinases in Regulating Macrophage Functions in Immunity and Cancer

<p>The Abl family of protein tyrosine kinases regulates diverse cellular processes by coordinating cytoskeletal rearrangements. Recent data indicate that pharmacological inhibition of Abl kinases reduces inflammation in preclinical models and in the clinic. While a previous role for Abl kinases in lymphocytes had been described, it remained unclear if Abl kinases regulate innate immune function. To explore this possibility, we generated a myeloid-specific conditional Abl knockout mouse. Using a combination of molecular, genetic, and pharmacological approaches, we demonstrate a role for Abl kinases in regulating the efficiency of macrophage phagocytosis and inflammatory responses. Bone marrow-derived macrophages from mice lacking Abl and Arg kinases exhibit inefficient phagocytosis of sheep erythrocytes and zymosan particles. Treatment with the Abl kinase inhibitors imatinib and GNF-2 or overexpression of kinase-inactive forms of the Abl family kinases also impairs particle internalization in murine macrophages, indicating Abl kinase activity is required for efficient phagocytosis. Further, Abl kinases are present at the phagocytic cup and are activated by Fcgamma receptor engagement. The regulation of phagocytosis by Abl family kinases is mediated in part by the Syk kinase. Loss of Abl and Arg expression or treatment with Abl inhibitors reduced Syk phosphorylation in response to Fcgamma receptor ligation. The link between Abl family kinases and Syk may be direct as purified Arg kinase phosphorylates Syk in vitro. Further, overexpression of membrane-targeted Syk in cells treated with Abl kinase inhibitors partially rescues the impairment in phagocytosis.</p><p>Our studies also revealed a role for Abl kinases in macrophage and cancer cell invasion. Inhibition of Abl kinases suppressed cell invasion in vitro, whereas overexpression of Abl kinases enhanced extracellular matrix degradation. We found that partial loss of Abl kinase expression in myeloid cells reduced macrophage infiltration into tumors in a mouse model of breast cancer. Furthermore, pharmacological inhibition of Abl kinases reduced myeloid cell infiltration and slowed tumor growth in subcutaneous tumor models. We also found that Abl expression and activity are elevated in subsets of human tumor samples. Taken together, our results suggest Abl kinases have an important role in cancer and inflammation, and represent important therapeutic targets for their treatment.</p>Dissertatio

Biorelevant In Vitro Skin Permeation Testing and In Vivo Pharmacokinetic Characterization of Lidocaine from a Nonaqueous Drug-in-Matrix Topical System.

Recently, lidocaine topical systems utilizing nonaqueous matrices have been developed and provide efficient lidocaine delivery through the skin, such that lower concentrations of drug provide equivalent or greater drug delivery than drug-in-matrix hydrogel lidocaine patches. This study characterizes drug delivery from a nonaqueous lidocaine topical system with increasing drug load both in vitro and in vivo. Topical systems formulated with either 1.8% or 5.4% lidocaine were applied to healthy volunteers' backs (n = 15) for 12 h in a single-center, open-label, four-treatment, four-period crossover pharmacokinetic study. Subjects were dosed with either three 1.8% systems or one, two, or three 5.4% systems in each period. Blood was collected for up to 48 h, and plasma lidocaine levels were measured with a validated HPLC method. In parallel, human and mouse skin models characterized the in vitro skin permeation profile. The pharmacokinetic profile was linear between one, two, and three lidocaine 5.4% applications. Application of three lidocaine 1.8% systems (108 mg lidocaine) was bioequivalent to one lidocaine 5.4% system (108 mg lidocaine). Both topical systems remained well adhered to the skin and irritation was mild. The 5.4% system had approximately threefold higher skin permeability than the 1.8% system in the mouse and human skin models. The results indicate increasing the drug load by three times results in triple the drug delivery both in vivo and in vitro. The relationship between the in vitro permeation and in vivo absorption correlates and is nonlinear