Search results for "Diepoxybutane"

showing 2 items of 2 documents

Re-definition and supporting evidence toward Fanconi Anemia as a mitochondrial disease: Prospects for new design in clinical management

2021

Fanconi anemia (FA) has been investigated since early studies based on two definitions, namely defective DNA repair and proinflammatory condition. The former definition has built up the grounds for FA diagnosis as excess sensitivity of patients' cells to xenobiotics as diepoxybutane and mitomycin C, resulting in typical chromosomal abnormalities. Another line of studies has related FA phenotype to a prooxidant state, as detected by both in vitro and ex vivo studies. The discovery that the FA group G (FANCG) protein is found in mitochondria (Mukhopadhyay et al., 2006) has been followed by an extensive line of studies providing evidence for multiple links between other FA gene products and mi…

0301 basic medicineMitochondrial DNAMitochondrial DiseasesMitomycinMitochondrial diseaseClinical BiochemistryDiepoxybutaneReview ArticleMitochondrionBiologyBiochemistry03 medical and health scienceschemistry.chemical_compound0302 clinical medicineFanconi anemiaFANCGmedicineHumansClastogenCarnitinelcsh:QH301-705.5Coenzyme Q10lcsh:R5-920ProteinOrganic ChemistryMitochondrial nutrientProteinsmedicine.diseaseMitochondrial diseaseFanconi AnemiaPhenotypeClastogens030104 developmental biologylcsh:Biology (General)chemistryProoxidant stateCancer researchMitochondrial nutrientsMitochondrial dysfunctionlcsh:Medicine (General)030217 neurology & neurosurgeryHumanmedicine.drugRedox Biology
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Fanconi anemia (FA) and crosslinker sensitivity: Re-appraising the origins of FA definition

2015

The commonly accepted definition of Fanconi anemia (FA) relying on DNA repair deficiency is submitted to a critical review starting from the early reports pointing to mitomycin C bioactivation and to the toxicity mechanisms of diepoxybutane and a group of nitrogen mustards causing DNA crosslinks in FA cells. A critical analysis of the literature prompts revisiting the FA phenotype and crosslinker sensitivity in terms of an oxidative stress (OS) background, redox-related anomalies of FA (FANC) proteins, and mitochondrial dysfunction. This re-appraisal of FA basic defect might lead to innovative approaches both in elucidating FA phenotypes and in clinical management.

Geneticsbusiness.industryDNA repairDNA damageMitomycin CDiepoxybutaneHematologymedicine.diseasemedicine.disease_causeFANC proteinschemistry.chemical_compoundOncologychemistryFanconi anemiaChromosome instabilityPediatrics Perinatology and Child HealthmedicineCancer researchbusinessOxidative stressPediatric Blood & Cancer
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