Patti Hayes scite author profile

Background & Aims Defects in intestinal innate defense systems predispose patients to inflammatory bowel disease (IBD). Reactive oxygen species (ROS) generated by nicotinamide-adenine dinucleotide phosphate (NADPH) oxidases in the mucosal barrier maintain gut homeostasis and defend against pathogenic attack. We hypothesized that molecular genetic defects in intestinal NADPH oxidases might be present in children with IBD. Methods After targeted exome sequencing of epithelial NADPH oxidases NOX1 and DUOX2 on 209 children with very early onset inflammatory bowel disease (VEOIBD), the identified mutations were validated using Sanger Sequencing. A structural analysis of NOX1 and DUOX2 variants was performed by homology in silico modeling. The functional characterization included ROS generation in model cell lines and in in vivo transduced murine crypts, protein expression, intracellular localization, and cell-based infection studies with the enteric pathogens Campylobacter jejuni and enteropathogenic Escherichia coli. Results We identified missense mutations in NOX1 (c.988G>A, p.Pro330Ser; c.967G>A, p.Asp360Asn) and DUOX2 (c.4474G>A, p.Arg1211Cys; c.3631C>T, p.Arg1492Cys) in 5 of 209 VEOIBD patients. The NOX1 p.Asp360Asn variant was replicated in a male Ashkenazi Jewish ulcerative colitis cohort. All NOX1 and DUOX2 variants showed reduced ROS production compared with wild-type enzymes. Despite appropriate cellular localization and comparable pathogen-stimulated translocation of altered oxidases, cells harboring NOX1 or DUOX2 variants had defective host resistance to infection with C. jejuni. Conclusions This study identifies the first inactivating missense variants in NOX1 and DUOX2 associated with VEOIBD. Defective ROS production from intestinal epithelial cells constitutes a risk factor for developing VEOIBD.

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Mucosal Reactive Oxygen Species Are Required for Antiviral Response: Role of Duox in Influenza A Virus Infection

Strengert

Jennings²,

Davanture³

et al. 2014

Antioxidants & Redox Signaling

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Queuosine Formation in Eukaryotic tRNA Occurs via a Mitochondria-localized Heteromeric Transglycosylase

Boland

Hayes

Santa-María

et al. 2009

Journal of Biological Chemistry

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tRNA guanine transglycosylase (TGT) enzymes are responsible for the formation of queuosine in the anticodon loop (position 34) of tRNA Asp , tRNA Asn , tRNA His , and tRNA Tyr ; an almost universal event in eubacterial and eukaryotic species. Despite extensive characterization of the eubacterial TGT the eukaryotic activity has remained undefined. Our search of mouse EST and cDNA data bases identified a homologue of the Escherichia coli TGT and three spliced variants of the queuine tRNA guanine transglycosylase domain containing 1 (QTRTD1) gene. QTRTD1 variant_1 (Qv1) was found to be the predominant adult form. Functional cooperativity of TGT and Qv1 was suggested by their coordinate mRNA expression in Northern blots and from their association in vivo by immunoprecipitation. Neither TGT nor Qv1 alone could complement a tgt mutation in E. coli. However, transglycosylase activity could be obtained when the proteins were combined in vitro. Confocal and immunoblot analysis suggest that TGT weakly interacts with the outer mitochondrial membrane possibly through association with Qv1, which was found to be stably associated with the organelle. Queuosine (Q 3 ; (7-{[(4,5-cis-dihydroxy-2-cyclo-penten-1-yl)-amino]methyl}-7-deazaguanosine) is a modified 7-deazaguanosine molecule found at the wobble position of transfer RNA that contains a GUN anticodon sequence: tRNA Tyr , tRNA Asn , tRNA His , and tRNA Asp (1). The Q-modification is widely distributed in nature in the tRNA of eubacteria, plants, and animals; a notable exception being yeast and plant leaf cells (2, 3). Interestingly, Q-modification has also been detected in aspartyl tRNA from mitochondria of rat (4) and opossum (5). In most eukaryotes, the Q molecule can be further modified by the addition of a mannosyl group to Q-tRNA Asp and a galactosyl group to Q-tRNA Tyr (1). Eubacteria are unique in their ability to synthesize Q. As part of this biosynthetic process, the eubacterial tRNA guanine transglycosylase (TGT) enzyme inserts the Q precursor molecule, 7-aminomethyl-7-deazaguanine (preQ 1 ) into tRNA, which is then converted to Q by two further enzymatic steps at the tRNA level (6). Eukaryotes by contrast salvage queuosine from food and enteric bacteria either as the free base (referred to as queuine) or as queuosine 5Ј-phosphate subsequent to normal tRNA turnover (7). A Q-related molecule, archaeosine, is found at position 15 of the D loop of most archaeal tRNA, where it functions to stabilize the tRNA structure (8). The enzyme involved in archaeosine biosynthesis is structurally and mechanistically related to the eubacterial TGT but with adaptations necessitated by the differences imposed by its unique substrate and tRNA specificity (9, 10).The crystal structure of the Zymononas mobilis (Z. mobilis) TGT has been determined and revealed the enzyme to be an irregular (␤/␣) 8 TIM barrel with a C-terminal zinc-binding subdomain (11). Insight into the residues involved in catalysis came from mutational and kinetic analysis of the recombinant Escherichia coli enzyme...

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Constitutive NADPH Oxidase 4 Activity Resides in the Composition of the B-loop and the Penultimate C Terminus

Löhneysen

Noack

Hayes

et al. 2012

Journal of Biological Chemistry

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Background: Reactive oxygen species generated by NADPH oxidases are critical second messengers. Results: Unique motifs in the B-loop and C terminus are essential for Nox4 catalytic activity. Conclusion:The active conformation of the Nox4-p22 phox complex is dependent on discrete motifs and precise spacing. Significance: Improved understanding of the inactive versus the active conformation of Nox enzymes will aid inhibitor development.

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Balancing Reactive Oxygen Species in the Epigenome: NADPH Oxidases as Target and Perpetrator

Hayes

Knaus

2013

Antioxidants & Redox Signaling

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NADPH oxidases may serve as prognostic tumor biomarker, especially when their individual expression is confined to accessible tissues, such as mucosal epithelia or blood. Further validation of NADPH oxidase/dual oxidase enzymes as candidate markers will require well controlled, large-scale clinical data sets. This review is focused on NADPH oxidases as targets of epigenetic changes in cancer and on the emerging role of ROS as inducers of epigenetic changes.

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Patti Hayes

Defects in Nicotinamide-adenine Dinucleotide Phosphate Oxidase Genes NOX1 and DUOX2 in Very Early Onset Inflammatory Bowel Disease

Mucosal Reactive Oxygen Species Are Required for Antiviral Response: Role of Duox in Influenza A Virus Infection

Queuosine Formation in Eukaryotic tRNA Occurs via a Mitochondria-localized Heteromeric Transglycosylase

Constitutive NADPH Oxidase 4 Activity Resides in the Composition of the B-loop and the Penultimate C Terminus

Balancing Reactive Oxygen Species in the Epigenome: NADPH Oxidases as Target and Perpetrator

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