Supplementary Figure 1 from Carbon Monoxide Expedites Metabolic Exhaustion to Inhibit Tumor Growth

Wegiel, Barbara; Gallo, David; Csizmadia, Eva; Harris, Clair; Belcher, John; Vercellotti, Gregory M.; Penacho, Nuno; Seth, Pankaj; Sukhatme, Vikas; Ahmed, Asif; Pandolfi, Pier Paolo; Helczynski, Leszek; Bjartell, Anders; Persson, Jenny Liao; Otterbein, Leo E.

doi:10.1158/0008-5472.22398071.v1

00085472can131075-sup-fig1.pdf (6.81 MB)

Supplementary Figure 1 from Carbon Monoxide Expedites Metabolic Exhaustion to Inhibit Tumor Growth

journal contribution

posted on 2023-03-30, 21:53 authored by Barbara Wegiel, David Gallo, Eva Csizmadia, Clair Harris, John Belcher, Gregory M. Vercellotti, Nuno Penacho, Pankaj Seth, Vikas Sukhatme, Asif Ahmed, Pier Paolo Pandolfi, Leszek Helczynski, Anders Bjartell, Jenny Liao Persson, Leo E. Otterbein

PDF file - 6972K, Carbon monoxide accelerates camptothecin-induced apoptosis via inhibition of Gadd45α and independent of p53.

History

ARTICLE ABSTRACT

One classical feature of cancer cells is their metabolic acquisition of a highly glycolytic phenotype. Carbon monoxide (CO), one of the products of the cytoprotective molecule heme oxygenase-1 (HO-1) in cancer cells, has been implicated in carcinogenesis and therapeutic resistance. However, the functional contributions of CO and HO-1 to these processes are poorly defined. In human prostate cancers, we found that HO-1 was nuclear localized in malignant cells, with low enzymatic activity in moderately differentiated tumors correlating with relatively worse clinical outcomes. Exposure to CO sensitized prostate cancer cells but not normal cells to chemotherapy, with growth arrest and apoptosis induced in vivo in part through mitotic catastrophe. CO targeted mitochondria activity in cancer cells as evidenced by higher oxygen consumption, free radical generation, and mitochondrial collapse. Collectively, our findings indicated that CO transiently induces an anti-Warburg effect by rapidly fueling cancer cell bioenergetics, ultimately resulting in metabolic exhaustion. Cancer Res; 73(23); 7009–21. ©2013 AACR.

Usage metrics

Keywords

Chemotherapy Adjuvant chemotherapy Novel drug delivery systems Genitourinary Cancers Prostate cancer Immunology Tumor immunology animal models Lung Cancer Preclinical Models Animal models of cancer Small Molecule Agents

Licence

CC BY

Supplementary Figure 1 from Carbon Monoxide Expedites Metabolic Exhaustion to Inhibit Tumor Growth

History

ARTICLE ABSTRACT

Usage metrics

Categories

Keywords

Licence

Exports