Carla Dib scite author profile

Facioscapulohumeral dystrophy (FSHD) is one of the three most common muscular dystrophies in the Western world, however, its etiology remains only partially understood. Here, we provide evidence of constitutive DNA damage in in vitro cultured myoblasts isolated from FSHD patients and demonstrate oxidative DNA damage implication in the differentiation of these cells into phenotypically-aberrant myotubes. Double homeobox 4 (DUX4), the major actor in FSHD pathology induced DNA damage accumulation when overexpressed in normal human myoblasts, and RNAi-mediated DUX4 inhibition reduced the level of DNA damage in FSHD myoblasts. Addition of tempol, a powerful antioxidant, to the culture medium of proliferating DUX4-transfected myoblasts and FSHD myoblasts reduced the level of DNA damage, suggesting that DNA alterations are mainly due to oxidative stress. Antioxidant treatment during the myogenic differentiation of FSHD myoblasts significantly reduced morphological defects in myotube formation. We propose that the induction of DNA damage is a novel function of the DUX4 protein affecting myogenic differentiation of FSHD myoblasts.

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Facioscapulohumeral dystrophy myoblasts efficiently repair moderate levels of oxidative DNA damage

Saada

Dib

Dmitriev

et al. 2016

Histochem Cell Biol

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Facioscapulohumeral dystrophy (FSHD) is a progressive muscular dystrophy linked to a deletion of a subset of D4Z4 macrosatellite repeats accompanied by a chromatin relaxation of the D4Z4 array on chromosome 4q. In vitro, FSHD primary myoblasts show altered expression of oxidative-related genes and are more susceptible to oxidative stress. Double homeobox 4 (DUX4) gene, encoded within each D4Z4 unit, is normally transcriptionally silenced but is found aberrantly expressed in skeletal muscles of FSHD patients. Its expression leads to a deregulation of DUX4 target genes including those implicated in redox balance. Here, we assessed DNA repair efficiency of oxidative DNA damage in FSHD myoblasts and DUX4-transfected myoblasts. We have shown that the DNA repair activity is altered neither in FSHD myoblasts nor in immortalized human myoblasts transiently expressing DUX4. DNA damage caused by moderate doses of an oxidant is efficiently repaired while FSHD myoblasts exposed for 24 h to high levels of oxidative stress accumulated more DNA damage than normal myoblasts, suggesting that FSHD myoblasts remain more vulnerable to oxidative stress at high doses of oxidants.

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Analysis of genes regulated by DUX4 via oxidative stress reveals potential therapeutic targets for treatment of facioscapulohumeral dystrophy

Karpukhina

Galkin²,

et al. 2021

Redox Biology

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Functional roles of HIV-1 Tat protein in the nucleus

Musinova

Sheval

Dib³

et al. 2015

Cell. Mol. Life Sci.

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Human immunodeficiency virus-1 (HIV-1) Tat protein is one of the most important regulatory proteins for viral gene expression in the host cell and can modulate different cellular processes. In addition, Tat is secreted by the infected cell and can be internalized by neighboring cells; therefore, it affects both infected and uninfected cells. Tat can modulate cellular processes by interacting with different cellular structures and signaling pathways. In the nucleus, Tat might be localized either in the nucleoplasm or the nucleolus depending on its concentration. Here we review the distinct functions of Tat in the nucleoplasm and the nucleolus in connection with viral infection and HIV-induced oncogenesis.

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DUX4 Pathological Expression: Causes and Consequences in Cancer

et al. 2019

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DUX4, a double homeobox transcription factor, has been mostly studied in facioscapulohumeral dystrophy (FSHD), a pathology linked to a deletion of subtelomeric repeats on chromosome 4q.More recently, however, the gene has been associated with various sarcomas and hematological malignancies. Drugs developed for FSHD could be tested on cancer cells to develop efficient treatment strategies for both pathologies.

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Control of DNA integrity in skeletal muscle under physiological and pathological conditions

Saada

Zakharova

Chernyak

et al. 2017

Cell. Mol. Life Sci.

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Skeletal muscle is a highly oxygen-consuming tissue that ensures body support and movement, as well as nutrient and temperature regulation. DNA damage induced by reactive oxygen species is present in muscles and tends to accumulate with age. Here, we present a summary of data obtained on DNA damage and its implication in muscle homeostasis, myogenic differentiation and neuromuscular disorders. Controlled and transient DNA damage appears to be essential for muscular homeostasis and differentiation while uncontrolled and chronic DNA damage negatively affects muscle health.

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Control of DUX4 Expression in Facioscapulohumeral Muscular Dystrophy and Cancer

Karpukhina

Tiukacheva

Dib

et al. 2021

Trends in Molecular Medicine

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DUX4, a gene encoding a transcription factor involved in early embryogenesis, is heavily repressed in most somatic tissues while its aberrant expression is linked to facioscapulohumeral muscular dystrophy (FSHD). Recently, the deregulation of DUX4 expression was found in many cancers. While DUX4 role in FSHD is well studied, its relevance in cancer is less explored. Here we discuss multiple levels of control of DUX4 expression, including enhancer-promoter interactions, epigenetic modifications, non-coding RNAs and telomere positioning effect. We also connect disparate data on intrachromosomal contacts involving DUX4 and emphasize feedback loops in DUX4 regulation. Finally, we bridge data on DUX4 in FSHD and cancer and discuss prospective approaches for future FSHD therapies and the potential outcomes of DUX4 inhibition in cancer.

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Correction of the FSHD myoblast differentiation defect by fusion with healthy myoblasts

Dib

Saada

Dmitriev

et al. 2015

Journal Cellular Physiology

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Facioscapulohumeral dystrophy (FSHD) is a neuromuscular disease with a prevalence that could reach 1 in 8,000 characterized by progressive asymmetric muscle weakness. Myoblasts isolated from FSHD muscles exhibit morphological differentiation defects and show a distinct transcription profile. These abnormalities may be linked to the muscle weakness in FSHD patients. We have tested whether fusion of FSHD myoblasts with primary myoblasts isolated from healthy individuals could correct the differentiation defects. Our results show that the number of hybrid myotubes with normal phenotype increased with the percentage of normal myoblasts initially cultured. We demonstrated that a minimum of 50% of normal nuclei is required for a phenotypic correction of the FSHD phenotype. Moreover, transcriptomic profiles of phenotypically corrected hybrid myotubes showed that the expression of deregulated genes in FSHD myotubes became almost normal. The number of deregulated pathways also decreased from 39 in FSHD myotubes to one in hybrid myotubes formed with 40% FSHD and 60% normal myoblasts. We thus propose that while phenotypical and functional correction of FSHD is feasible, it requires more than 50% of normal myoblasts, it creates limitations for cell therapy in the FSHD context.

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Carla Dib

DUX4-induced constitutive DNA damage and oxidative stress contribute to aberrant differentiation of myoblasts from FSHD patients

Facioscapulohumeral dystrophy myoblasts efficiently repair moderate levels of oxidative DNA damage

Analysis of genes regulated by DUX4 via oxidative stress reveals potential therapeutic targets for treatment of facioscapulohumeral dystrophy

Functional roles of HIV-1 Tat protein in the nucleus

DUX4 Pathological Expression: Causes and Consequences in Cancer

Control of DNA integrity in skeletal muscle under physiological and pathological conditions

Control of DUX4 Expression in Facioscapulohumeral Muscular Dystrophy and Cancer

Correction of the FSHD myoblast differentiation defect by fusion with healthy myoblasts

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