The UGT1A isoforms 2 act as negative modulators of their isoform 1 homologs in microsome preparations, revealing a new regulatory mechanism of the glucuronidation pathway. Findings further provide the first direct evidence of a novel alternative splicing mechanism at the 3' end of the UGT1 locus that further increases the number of proteins derived from this single gene.
UGT1A3 is one of the most efficient at conjugating estrone, a precursor for biosynthesis of estradiol in peripheral tissues. We established the genetic mechanisms that might contribute to individual variation in UGT1A3 expression and activity. UGT1A3 first exon and 5'-flanking regions were sequenced in 249 Caucasians. We identified 17 polymorphisms, among them seven regulatory and 10 exonic polymorphisms with six leading to amino-acid changes. Luciferase reporter assays, site-directed mutagenesis and electrophoretic mobility shift assays using hepatoma HepG2 cells were carried out to show functionality of variant promoters. Reduced transcriptional activity was associated with all six variant promoters (two-fold; P<0.001). One of the potential mechanisms would involve the -148 T>C and -581 C>T variations that modulate gene function by affecting hepatocyte nuclear factor-1alpha and hepatocyte nuclear factor-4alpha binding, respectively. Then, estrone-conjugating activity was assessed with 11 heterologously expressed allozymes. Three phenotypes were observed; UGT1A3*1, *2 (WR, VA) and *3 (WR) with high intrinsic clearance values; UGT1A3*5 (QR, WR), *7 (FI), *9 (WR, ML), *10 (VA) and *11 (WR, VA and MI) had intermediate CLint (2X-10X lower vs. *1), whereas UGT1A3*4 (RW), *6 (WR, VA, MV) and *8 (AV) had low CLint (>10X lower vs. *1). Diplotype analyses indicate that 20.1% of individuals carry two alleles affecting UGT1A3 expression and/or activity. This study did not investigate genotype-phenotype association, but raise the possibility that genetically determined variation might contribute to variability in the inactivation of estrone by UGT1A3 and subsequent changes in lifetime exposure to estrogens potentially modifying risk of cancer.
QRS widening and QT prolongation are associated with bupropion. The objectives were to elucidate its cardiac electrophysiological properties. Patch-clamp technique was used to assess the I(Kr) -, I(Ks) -, and I(Na) -blocking effects of bupropion. Langendorff retroperfusion technique on isolated guinea-pig hearts was used to evaluate the MAPD(90) -, MAP amplitude-, phase 0 dV/dt-, and ECG-modulating effects of bupropion and of two gap junction intercellular communication inhibitors: glycyrrhetinic acid and heptanol. To evaluate their effects on cardiac intercellular communication, fluorescence recovery after photobleaching (FRAP) technique was used. Bupropion is an I(Kr) blocker. IC(50) was estimated at 34 μm. In contrast, bupropion had hardly any effect on I(Ks) and I(Na) . Bupropion had no significant MAPD(90) -modulating effect. However, as glycyrrhetinic acid and heptanol, bupropion caused important reductions in MAP amplitude and phase 0 dV/dt. A modest but significant QRS-widening effect of bupropion was also observed. FRAP experiments confirmed that bupropion inhibits gap junctional intercellular communication. QT prolongation during bupropion overdosage is due to its I(Kr) -blocking effect. QRS widening with bupropion is not related to cardiac sodium channel block. Bupropion rather mimics the QRS-widening, MAP amplitude- and phase 0 dV/dt -reducing effect of glycyrrhetinic acid and heptanol. Unlike class I anti-arrhythmics, bupropion causes cardiac conduction disturbances by reducing cardiac intercellular coupling.
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