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Guillemette, Chantal

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Guillemette

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Chantal

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Université Laval. Faculté de pharmacie

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Voici les éléments 1 - 10 sur 12
  • PublicationRestreint
    Posttranscriptional regulation of UGT2B10 hepatic expression and activity by alternative splicing
    (American Society for Pharmacology and Experimental Therapeutics, 2018-02-09) Rouleau, Michèle; Labriet, Adrien; Audet-Delage, Yannick; Guillemette, Chantal; Allain, Eric; Villeneuve, Lyne
    The detoxification enzyme UDP-glucuronosyltransferase UGT2B10 is specialized in the N-linked glucuronidation of many drugs and xenobiotics. Preferred substrates possess tertiary aliphatic amines and heterocyclic amines, such as tobacco carcinogens and several antidepressants and antipsychotics. We hypothesized that alternative splicing (AS) constitutes a means to regulate steady-state levels of UGT2B10 and enzyme activity. We established the transcriptome of UGT2B10 in normal and tumoral tissues of multiple individuals. The highest expression was in the liver, where 10 AS transcripts represented 50% of the UGT2B10 transcriptome in 50 normal livers and 44 hepatocellular carcinomas. One abundant class of transcripts involves a novel exonic sequence and leads to two alternative (alt.) variants with novel in-frame C termini of 10 or 65 amino acids. Their hepatic expression was highly variable among individuals, correlated with canonical transcript levels, and was 3.5-fold higher in tumors. Evidence for their translation in liver tissues was acquired by mass spectrometry. In cell models, they colocalized with the enzyme and influenced the conjugation of amitriptyline and levomedetomidine by repressing or activating the enzyme (40%–70%; P < 0.01) in a cell context–specific manner. A high turnover rate for the alt. proteins, regulated by the proteasome, was observed in contrast to the more stable UGT2B10 enzyme. Moreover, a drug-induced remodeling of UGT2B10 splicing was demonstrated in the HepaRG hepatic cell model, which favored alt. variants expression over the canonical transcript. Our findings support a significant contribution of AS in the regulation of UGT2B10 expression in the liver with an impact on enzyme activity.
  • PublicationAccès libre
    Immunohistochemical expression of conjugating UGT1A-derived splice proteins in normal and tumoral drug-metabolising tissues in humans
    (Wiley, 2010-10-29) Bellemare, Judith.; Pelletier, Georges; Popa, Ion; Têtu, Bernard; Harvey, Mario.; Guillemette, Chantal; Rouleau, Mélanie
    Glucuronidation by UDP-glucuronyltransferase (UGT) enzymes is the prevailing conjugative pathway for the metabolism of both xenobiotics and endogenous compounds. Alterations in this pathway, such as those generated by common genetic polymorphisms, have been shown to significantly impact on the health of individuals, influencing cancer susceptibility, responsiveness to drugs and drug-induced toxicity. Alternative usage of terminal exons leads to UGT1A-derived splice variants, namely the classical and enzymatically active isoforms 1 (i1) and the novel enzymatically inactive isoforms 2 (i2). In vitro functional data from heterologous expression and RNA interference experiments indicate that these i2 isoforms act as negative modulators of glucuronidation, likely by forming inactive complexes with active isoform 1. We used specific antibodies against either active i1 or inactive i2 proteins to examine their distribution in major drug-metabolizing tissues. Data revealed that UGT1A_i1 and inactive UGT1A_i2 are co-produced in the same tissue structures, including liver, kidney, stomach, intestine and colon. Examination of the cellular distribution and semi-quantitative level of expression of UGT1As revealed heterogeneous expression of i1 and i2 proteins, with increased expression of i2 in liver tumours and decreased levels of i1 and i2 in colon cancer specimens, compared to normal tissues. These differences in expression may be relevant to human colon and liver cancer tumorigenesis. Our data clearly demonstrate the similar immunolocalization of active and inactive UGT1A isoforms in most UGT1A-expressing cell types of major tissues involved in drug metabolism. These expression patterns are consistent with a dominant-negative function for the i2 encoded by the UGT1A gene.
  • PublicationAccès libre
    A rare UGT2B7 variant creates a novel N-glycosylation site at codon 121 with impaired enzyme activity
    (American Society for Pharmacology and Experimental Therapeutics, 2016-09-12) Benoît-Biancamano, Marie-Odile; Desjardins, Sylvie; Guillemette, Chantal; Girard-Bock, Camille; Villeneuve, Lyne
    UDP-glucuronosyltransferase (UGT) superfamily are glycoproteins resident of the endoplasmic reticulum membranes that undergo post-translational modifications (PTM). UGT2B7 is of particular interest because of its action on a wide variety of drugs. Most studies currently survey common variants and are only examining a small fraction of the genetic diversity. However, rare variants (frequency <1%) might have significant effect as they are predicted to greatly outnumber common variants in the human genome. Here, we discovered a rare single nucleotide UGT2B7 variant of potential pharmacogenetic relevance that encodes a nonconservative amino acid substitution at codon 121. This low-frequency variation, found in two individuals of a population of 305 healthy volunteers, leads to the translation of an asparagine (Asn) instead of an aspartic acid (Asp) (UGT2B7 p.D121N). This amino acid change was predicted to create a putative N-glycosylation motif NX(S/T) subsequently validated upon endoglycosidase H treatment of microsomal fractions and inhibition of N-glycosylation of endogenously produced UGT2B7 with tunicamycin from HEK293 cells. The presence of an additional N-linked glycan on the UGT2B7 enzyme, likely affecting proper protein folding, resulted in a significant decrease, respectively by 49 and 40%, in the formation of zidovudine and mycophenolic acid glucuronides. A systematic survey of the dbSNP database uncovered 32 rare and naturally occurring missense variations predicted to create or disrupt N-glycosylation sequence motifs in the other UGT2B enzymes. Collectively, these variants have the potential to increase the proportion of variance explained in the UGT pathway due to changes in PTM such as N-linked glycosylation with consequences on drug metabolism.
  • PublicationAccès libre
    Overexpression of uridine diphospho glucuronosyltransferase 2B17 in high risk chronic lymphocytic leukemia
    (American Society of Hematology, 2012-11-20) Gruber, Michaela; Lévesque, Éric; Bellemare, Judith.; Hörmann, Gregor; Guillemette, Chantal; Gleiss, Andreas; Porpaczy, Edith; Bilban, Martin; Le, Trang; Zehetmayer, Sabine; Mannhalter, Christine; Gaiger, Alexander; Shehata, Medhat; Fleiss, Karin; Skrabs, Cathrin; Vanura, Katrina; Jäger, Ulrich
    Uridine diphospho glucuronosyltransferase 2B17 (UGT2B17) glucuronidates androgens and xenobiotics including certain drugs. The UGT2B17 gene shows a remarkable copy number variation (CNV), which predisposes for solid tumors and influences drug response. Here, we identify a yet undescribed UGT2B17 mRNA overexpression in poor-risk chronic lymphocytic leukemia (CLL). In total, 320 CLL patients and 449 healthy donors were analyzed. High (above median) UGT2B17 expression was associated with established CLL poor prognostic factors and resulted in shorter treatment-free and overall survival (hazard ratio ([death] 2.18; 95% CI 1.18-4.01; P = .013). The prognostic impact of mRNA expression was more significant than that of UGT2B17 CNV. UGT2B17 mRNA levels in primary CLL samples directly correlated with functional glucuronidation activity toward androgens and the anticancer drug vorinostat (R > 0.9, P < .001). After treatment with fludarabine containing regimens UGT2B17 was up-regulated particularly in poor responders (P = .030). We observed an exclusive involvement of the 2B17 isoform within the UGT protein family. Gene expression profiling of a stable UGT2B17 knockdown in the CLL cell line MEC-1 demonstrated a significant involvement in key cellular processes. These findings establish a relevant role of UGT2B17 in CLL with functional consequences and potential therapeutic implications.
  • PublicationAccès libre
    UGT genomic diversity : beyond gene duplication
    (Informa Healthcare, 2009-10-26) Lévesque, Éric; Bellemare, Judith.; Harvey, Mario.; Ménard, Vincent; Guillemette, Chantal
    The human uridine diphospho (UDP)-glucuronosyltransferase (UGT) superfamily comprises enzymes responsible for a major biotransformation phase II pathway: the glucuronidation process. The UGT enzymes are located in the endoplasmic reticulum of almost all tissues, where they catalyze the inactivation of several endogenous and exogenous molecules, including bilirubin, sex steroids, numerous prescribed drugs, and environmental toxins. This metabolic pathway is particularly variable. The influence of inheritable polymorphisms in human UGT-encoding genes has been extensively documented and was shown to be responsible for a fraction of the observed phenotypic variability. Other key genomic processes are likely underlying this diversity; these include copy-number variations, epigenetic factors, and newly discovered splicing mechanisms. This review will discuss novel molecular aspects that may be determinant to UGT phenotypes.
  • PublicationAccès libre
    A pharmacogenetics study of the human glucuronosyltransferase UGT1A4
    (Lippincott Williams & Wilkins, 2009-12-01) Benoît-Biancamano, Marie-Odile; Leblanc, Marie-Hélène; Bernard, Olivier; Court, Michael H.; Guillemette, Chantal; Caron, Patrick; Adam, Jean-Philippe
    UGT1A4 is primarily expressed in the liver and exhibits catalytic activities for various drugs. Amongst the few UGT1A4 polymorphisms evaluated, studies support the alteration of UGT1A4-mediated glucuronidation by a few variations including the Pro24Thr and Leu48Val variants (referred to as UGT1A4*2 and *3). We therefore investigated genetic mechanisms that might contribute to interindividual variation in UGT1A4 expression and activity. The UGT1A4 gene was sequenced from -4963 bp relative to the ATG to 2000 bp after the first exon in 184 unrelated Caucasians and African-Americans. We identified a large number of genetic variations, including 13 intronic, 39 promoter, as well as 14 exonic polymorphisms, with 10 that lead to aminoacid changes. Of the nucleotide variations found in the -5kb promoter region, 5 are located in the proximal region (first 500 bp), and positioned in putative HNF-1 and OCT-1 binding sites. Four of these variants, placed at -163, -219, -419 and -463, are in complete linkage disequilibrium with the Leu48Val coding region variant and with several variants in the upstream region of the promoter. Transient transfections of reference and variant promoter constructs (from position -500 to +1) in different cell lines with or without co-expression of HNF-1 and/or OCT-1, demonstrated limited effect of these variations. However, several coding variants significantly modified the enzyme kinetics for tamoxifen and Z-4-hydroxytamoxifen (Val48, Asp50, Gln56, Phe176, Asn250, Leu276). Our results reveal that, despite a large number of polymorphisms located in the promoter region, the exonic variants are those expected to have a potential in vivo effect.
  • PublicationAccès libre
    Unravelling the transcriptomic landscape of the major phase II UDP-glucuronosyltransferase drug metabolizing pathway using targeted RNA sequencing
    (Nature, 2015-04-14) Lévesque, Éric; Margaillan, Guillaume; Rouleau, Michèle; Gilbert, Isabelle; Droit, Arnaud; Tourancheau, Alan; Guillemette, Chantal; Villeneuve, Lyne
    A comprehensive view of the human UDP-glucuronosyltransferase (UGT) transcriptome is a prerequisite to the establishment of an individual's UGT metabolic glucuronidation signature. Here, we uncover the transcriptome landscape of the 10 human UGT gene loci in normal and tumoral metabolic tissues by targeted RNA next-generation sequencing. Alignment on the human hg19 reference genome identifies 234 novel exon-exon junctions. We recover all previously known UGT1 and UGT2 enzyme-coding transcripts and identify over 130 structurally and functionally diverse novel UGT variants. We further expose a revised genomic structure of UGT loci and provide a comprehensive repertoire of transcripts for each UGT gene. Data also uncover a remodelling of the UGT transcriptome occurring in a tissue- and tumor-specific manner. The complex alternative splicing program regulating UGT expression and protein functions is likely critical in determining detoxification capacity of an organ and stress-related responses, with significant impact on drug responses and diseases.
  • PublicationAccès libre
    Pharmacogenomics of human uridine diphospho-glucuronosyltransferases (UGTs) and clinical implications
    (Wiley, 2014-06-12) Lévesque, Éric; Rouleau, Michèle; Guillemette, Chantal
    Glucuronidation, mediated by UDP-glucuronosyltransferase enzymes (UGTs), is a major phase II biotransformation pathway and, complementary to phase I metabolism and membrane transport, one of the most important cellular defense mechanism responsible for the inactivation of therapeutic drugs, other xenobiotics and numerous endogenous molecules. Individual variability in UGT enzymatic pathways is significant and may have profound pharmacological and toxicological implications. Several genetic and genomic processes are underlying this variability and are discussed in the context of drug metabolism and diseases such as cancer.
  • PublicationAccès libre
    The relative protein abundance of UGT1A alternative splice variants as a key determinant of glucuronidation activity in vitro
    (American Society for Pharmacology and Experimental Therapeutics, etc., 2013-04-01) Roberge, Joannie; Guillemette, Chantal; Falardeau, Sarah-Ann; Rouleau, Mélanie; Villeneuve, Lyne
    Alternative splicing (AS) is one of the most significant components of the functional complexity of human UDP-glucuronosyltransferase enzymes (UGTs), particularly for the UGT1A gene, which represents one of the best examples of a drug-metabolizing gene regulated by AS. Shorter UGT1A isoforms [isoform 2 (i2)] are deficient in glucuronic acid transferase activity but function as negative regulators of enzyme activity through protein-protein interaction. Their abundance, relative to active UGT1A enzymes, is expected to be a determinant of the global transferase activity of cells and tissues. Here we tested whether i2-mediated inhibition increases with greater abundance of the i2 protein relative to the isoform 1 (i1) enzyme, using the extrahepatic UGT1A7 as a model and a series of 23 human embryonic kidney 293 clonal cell lines expressing variable contents of i1 and i2 proteins. Upon normalization for i1, a significant reduction of 7-ethyl-10-hydroxycamptothecin glucuronide formation was observed for i1+i2 clones (mean of 53%) compared with the reference i1 cell line. In these clones, the i2 protein content varied greatly (38–263% relative to i1) and revealed two groups: 17 clones with i2 < i1 (60% ± 3%) and 6 clones with i2 = i1 (153% ± 24%). The inhibition induced by i2 was more substantial for clones displaying i2 = i1 (74.5%; P = 0.001) compared with those with i2 < i1 (45.5%). Coimmunoprecipitation supports a more substantial i1-i2 complex formation when i2 exceeds i1. We conclude that the relative abundance of regulatory i2 proteins has the potential to drastically alter the local drug metabolism in the cells, particularly when i2 surpasses the protein content of i1.
  • PublicationAccès libre
    Endogenous protein interactome of human UDP-glucuronosyltransferases exposed by untargeted proteomics
    (Frontiers Research Foundation, 2017-02-03) Rouleau, Michèle; Desjardins, Sylvie; Audet-Delage, Yannick; Guillemette, Chantal; Rouleau, Mélanie; Girard-Bock, Camille
    The conjugative metabolism mediated by UDP-glucuronosyltransferase enzymes (UGTs) significantly influences the bioavailability and biological responses of endogenous molecule substrates and xenobiotics including drugs. UGTs participate in the regulation of cellular homeostasis by limiting stress induced by toxic molecules, and by controlling hormonal signaling networks. Glucuronidation is highly regulated at genomic, transcriptional, post-transcriptional and post-translational levels. However, the UGT protein interaction network, which is likely to influence glucuronidation, has received little attention. We investigated the endogenous protein interactome of human UGT1A enzymes in main drug metabolizing non-malignant tissues, where UGT expression is most prevalent, using an unbiased proteomics approach. Mass spectrometry analysis of affinity-purified UGT1A enzymes and associated protein complexes in liver, kidney and intestine tissues revealed an intricate interactome linking UGT1A enzymes to multiple metabolic pathways. Several proteins of pharmacological importance such as transferases (including UGT2 enzymes), transporters and dehydrogenases were identified, upholding a potential coordinated cellular response to small lipophilic molecules and drugs. Furthermore, a significant cluster of functionally related enzymes involved in fatty acid ß-oxidation, as well as in the glycolysis and glycogenolysis pathways were enriched in UGT1A enzymes complexes. Several partnerships were confirmed by co-immunoprecipitations and co-localization by confocal microscopy. An enhanced accumulation of lipid droplets in a kidney cell model overexpressing the UGT1A9 enzyme supported the presence of a functional interplay. Our work provides unprecedented evidence for a functional interaction between glucuronidation and bioenergetic metabolism.