Your search keyword '"Beshiri, Michael L."' showing total 2 results

1. Coordinated repression of cell cycle genes by KDM5A and E2F4 during differentiation.

Author

Beshiri, Michael L., Holmes, Katherine B., Richter, William F., Hess, Samuel, lsIam, Abul B. M. M. K., Qin Van, Plante, Lydia, Larisa Litovchick, Nicolas Gévry, Lopez-Bigas, Nuria, Kaelin, Jr., William G., and Benevolenskaya, Elizaveta V.

Subjects

*CELL cycle, *BIOLOGICAL rhythms, *CELL proliferation, *TRANSCRIPTION factors, *CELL differentiation, *GENETIC regulation

Abstract

Epigenetic regulation underlies the robust changes in gene expression that occur during development. How precisely epigenetic enzymes contribute to development and differentiation processes is largely unclear. Here we show that one of the enzymes that removes the activating epigenetic mark of trimethylated lysine 4 on histone H3, lysine (K)-specific demethylase 5A (KDM5A), reinforces the effects of the retinoblastoma (RB) family of transcriptional repressors on differentiation. Global location analysis showed that KDM5A cooccupies a substantial portion of target genes with the E2F4 transcription factor. During ES cell differentiation, knockout of KDM5A resulted in derepression of multiple genomic loci that are targets of KDM5A, denoting a direct regulatory function. In terminally differentiated cells, common KDM5A and E2F4 gene targets were bound by the pRB-related protein p130, a DREAM complex component. KDM5A was recruited to the transcription start site regions independently of E2F4; however, it cooperated with E2F4 to promote a state of deepened repression at cell cycle genes during differentiation. These findings reveal a critical role of H3K4 demethylation by KDM5A in the transcriptional silencing of genes that are suppressed by RB family members in differentiated cells. [ABSTRACT FROM AUTHOR]

Published

2012

2. Increased mitochondrial function downstream from KDM5A histone demethylase rescues differentiation in pRB-deficient cells.

Author

Váraljai, Renáta, Islam, Abul B. M. M. K., Beshiri, Michael L., Rehman, Jalees, Lopez-Bigas, Nuria, and Benevolenskaya, Elizaveta V.

Subjects

*LYSINE specific demethylase 1, *HISTONE demethylases, *MITOCHONDRIA formation, *RETINOBLASTOMA protein, *CELL cycle, *PEROXISOME proliferator-activated receptors

Abstract

The retinoblastoma tumor suppressor protein pRb restricts cell growth through inhibition of cell cycle progression. Increasing evidence suggests that pRb also promotes differentiation, but the mechanisms are poorly understood, and the key question remains as to how differentiation in tumor cells can be enhanced in order to diminish their aggressive potential. Previously, we identified the histone demethylase KDM5A (lysine [K]-specific demethylase 5A), which demethylates histone H3 on Lys4 (H3K4), as a pRB-interacting protein counteracting pRB's role in promoting differentiation. Here we show that loss of Kdm5a restores differentiation through increasing mitochondrial respiration. This metabolic effect is both necessary and sufficient to induce the expression of a network of cell type-specific signaling and structural genes. Importantly, the regulatory functions of pRB in the cell cycle and differentiation are distinct because although restoring differentiation requires intact mitochondrial function, it does not necessitate cell cycle exit. Cells lacking Rb1 exhibit defective mitochondria and decreased oxygen consumption. Kdm5a is a direct repressor of metabolic regulatory genes, thus explaining the compensatory role of Kdm5a deletion in restoring mitochondrial function and differentiation. Significantly, activation of mitochondrial function by the mitochondrial biogenesis regulator Pgc-1α (peroxisome proliferator-activated receptor γ-coactivator 1α; also called PPARGC1A) a coactivator of the Kdm5a target genes, is sufficient to override the differentiation block. Overexpression of Pgc-1α, like KDM5A deletion, inhibits cell growth in RB-negative human cancer cell lines. The rescue of differentiation by loss of KDM5A or by activation of mitochondrial biogenesis reveals the switch to oxidative phosphorylation as an essential step in restoring differentiation and a less aggressive cancer phenotype. [ABSTRACT FROM AUTHOR]

Published

2015