Evidence for phosphorylation requirement for human bilirubin UDP-glucuronosyltransferase (UGT1A1) activity

Our discovery of rapid down-regulation of human bilirubin UDP-glucuronosyltransferase (UGT) in colon cell lines that was transient and irreversible following curcumin- and calphostin-C-treatment, respectively, suggested phosphorylation event(s) were involved in activity. Likewise, bilirubin-UGT1A1 expressed in COS-1 cells was inhibited by curcumin and calphostin-C. Because calphostin-C is a highly specific protein kinase C (PKC) inhibitor, we examined and found 4 to 5 predicted PKC phosphorylation sites in 11 UGTs examined. UGT1A1 incorporated [33P]orthophosphate, which was inhibited by calphostin-C. Also triple mutant, T75A/T112A/S435G-UGT1A1, at predicted PKC sites failed to incorporate [33P]orthophosphate. Individual or double mutants exhibited dominant-negative, additive, or no effect, while the triple mutant retained 10-15% activity towards bilirubin and two xenobiotics. Compared to wild-type, S435G and T112A/S435G shifted pH-optimum for eugenol, but not for bilirubin or anthraflavic acid, toward alkaline and acid conditions, respectively. This represents the first evidence that a UGT isozyme requires phosphorylation for activity.     

Targeted inhibition of glucuronidation markedly improves drug efficacy in mice - a model

Finding UDP-glucuronosyltransferases (UGT) require protein kinase C-mediated phosphorylation is important information that allows manipulation of this critical system. UGTs glucuronidate numerous aromatic-like chemicals derived from metabolites, diet, environment and, inadvertently, therapeutics to reduce toxicities. As UGTs are inactivated by downregulating PKCs with reversibly-acting dietary curcumin, we determined the impact of gastro-intestinal glucuronidation on free-drug uptake and efficacy using immunosuppressant, mycophenolic acid (MPA), in mice. Expressed in COS-1 cells, mouse GI-distributed Ugt1a1 glucuronidates curcumin and MPA and undergoes irreversibly and reversibly dephosphorylation by PKC-specific inhibitor calphostin-C and general-kinase inhibitor curcumin, respectively, with parallel effects on activity. Moreover, oral curcumin-administration to mice reversibly inhibited glucuronidation in GI-tissues. Finally, successive oral administration of curcumin and MPA to antigen-treated mice increased serum free MPA and immunosuppression up to 9-fold. Results indicate targeted inhibition of GI glucuronidation in mice markedly improved free-chemical uptake and efficacy using MPA as a model.     

Opposite Regulation of Adenylyl Cyclase by Protein Kinase C in Astrocyte and Microglia Cultures

Abstract: We studied the regulation of cyclic AMP responses by protein kinase C (PKC) in purified astrocyte and microglia cultures obtained from the neonatal rat brain. In astrocytes, a 10-min treatment with the phorbol esters phorbol 12-myristate 13-acetate (PMA) and 4β-phorbol 12,13-didecanoate (4β-PDD) (but not with 4α-PDD) or with diacylglycerol, which activate PKC, dose-dependently enhanced cyclic AMP accumulation induced by the β-adrenergic agonist isoproterenol and the adenylyl cyclase activator forskolin. Such enhancement was prevented by the PKC inhibitors staurosporine and calphostin-C and by down-regulation of PKC and was not related to activation of membrane receptors or G_s proteins or to inhibition of G_i proteins or phosphodiesterases. Instead, the activity of adenylyl cyclase doubled in PMA-treated astrocytes. In microglia, a 10-min treatment with PMA or PKC inhibitors did not affect cyclic AMP accumulation, whereas longer treatments with PMA or 4β-PDD (but not 4α-PDD) inhibited the cyclic AMP response in a time- and dose-dependent manner. Such inhibition was mimicked by staurosporine and calphostin-C. Also, in the case of microglia, the modulation of cyclic AMP responses appeared to occur at the level of adenylyl cyclase, and not elsewhere in the cyclic AMP cascade. The inhibition of microglial adenylyl cyclase was apparently not due to aspecific cytotoxicity. A differential regulation of adenylyl cyclase by PKC in astrocytes and microglia may help to explain qualitative and quantitative differences in the response of these cells to various physiological and pathological stimuli.