Nonredundant, isoform-specific roles of HDAC1 in glioma stem cells
Costanza Lo Cascio, James B. McNamara, Ernesto L. Melendez, Erika M. Lewis, Matthew E. Dufault, Nader Sanai, Christopher L. Plaisier, Shwetal Mehta
Costanza Lo Cascio, James B. McNamara, Ernesto L. Melendez, Erika M. Lewis, Matthew E. Dufault, Nader Sanai, Christopher L. Plaisier, Shwetal Mehta
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Research Article Oncology Stem cells

Nonredundant, isoform-specific roles of HDAC1 in glioma stem cells

Abstract

Glioblastoma (GBM) is characterized by an aberrant yet druggable epigenetic landscape. One major family of epigenetic regulators, the histone deacetylases (HDACs), are considered promising therapeutic targets for GBM due to their repressive influences on transcription. Although HDACs share redundant functions and common substrates, the unique isoform-specific roles of different HDACs in GBM remain unclear. In neural stem cells, HDAC2 is the indispensable deacetylase to ensure normal brain development and survival in the absence of HDAC1. Surprisingly, we find that HDAC1 is the essential class I deacetylase in glioma stem cells, and its loss is not compensated for by HDAC2. Using cell-based and biochemical assays, transcriptomic analyses, and patient-derived xenograft models, we find that knockdown of HDAC1 alone has profound effects on the glioma stem cell phenotype in a p53-dependent manner. We demonstrate marked suppression in tumor growth upon targeting of HDAC1 and identify compensatory pathways that provide insights into combination therapies for GBM. Our study highlights the importance of HDAC1 in GBM and the need to develop isoform-specific drugs.

Authors

Costanza Lo Cascio, James B. McNamara, Ernesto L. Melendez, Erika M. Lewis, Matthew E. Dufault, Nader Sanai, Christopher L. Plaisier, Shwetal Mehta

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Figure 5

Knockdown of HDAC1 significantly extends survival in PDX and mouse models of GBM.

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Knockdown of HDAC1 significantly extends survival in PDX and mouse model...
(A) Average photon flux (p/s) measured 7 weeks postinjection through bioluminescence imaging of mice implanted with cells expressing control (shNT) and HDAC1-knockdown (shHDAC1_A and shHDAC1_B) cells and representative heatmap of bioluminescence intensity between the 2 groups. (B) Immunostaining for acetylated histone H3 at lysines 9 and 14 (H3K9/14ac; red) in tumor tissue. Arrowheads indicate GFP-positive cells with H3K9/14a-positive nuclei. (C) Immunostaining for Ki67 (red) and human mitochondria (hMitochondria, green) in shNT and shHDAC1 BT145 tumor tissue. Arrowheads indicate double-positive (Ki67+hMitochondria+) nuclei. (D) Quantification of human Ki67-positive cells in shNT and shHDAC1 BT145 tumors (n = 3 per cohort). (E) Kaplan-Meier survival analysis of mice implanted intracranially with p53-WT hGSCs (BT145) transduced with HDAC1 shRNA (shHDAC1_A, n = 4; shHDAC1_B, n = 3) or nontarget shRNA (shNT; n = 4 in both studies). (F) Kaplan-Meier survival analysis of mice implanted intracranially with murine GSCs (Cdkn2a–/– hEGFRvIII) transduced with HDAC1 shRNA (shHDAC1_A, n = 5) or shNT (n = 4). Inset below shows immunoblots confirming HDAC1-knockdown in the implanted GSCs. Error bars indicate SEM. *P < 0.05, **P < 0.01, ***P < 0.001. Original magnification, 20× and 63×; scale bars, 100 μm. P values were calculated using unpaired 2-tailed t test and Kaplan-Meier method with the Mantel-Cox log-rank test. See also Supplemental Figure 5.