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Literature DB >> 26220867

Dynamics of ceramide generation and metabolism in response to fenretinide--Diversity within and among leukemia.

Samy A F Morad¹, Traci S Davis², Mark Kester³, Thomas P Loughran⁴, Myles C Cabot⁵.

Abstract

Fenretinide, N-(4-hydroxyphenyl)retinamide, (4-HPR), a synthetic retinoid, owes its cancer-toxic effects in part to the generation of ceramide, a potent tumor-suppressing sphingolipid. As such, 4-HPR has garnered considerable interest as a chemotherapeutic. Cancer cells, however, via various metabolic routes, inactivate ceramide, and this can limit 4-HPR efficacy. As relatively little is known regarding 4-HPR-induced ceramide management in acute myelogeneous leukemia (AML), we undertook the present study to evaluate the impact of 4-HPR on ceramide production, metabolism, and cytotoxicity. In KG-1, HL-60, and HL-60/VCR (multidrug resistant) human leukemia cells, 4-HPR induced 15-, 2-, and 20-fold increases in ceramide (measured using [3H]palmitic acid), respectively. By use of specific inhibitors we show that ceramide was produced by sphingomyelinase and de novo pathways in response to 4-HPR exposure. HL-60/VCR cells metabolized ceramide to glucosylceramide (GC). 4-HPR exposure (1.25-10 μM) reduced viability in all cell lines, with approximate IC50's ranging from 1 to 8.0 μM. Reactive oxygen species (ROS) were generated in response to 4-HPR treatment, and the concomitant cytotoxicity was reversed by addition of vitamin E. 4-HPR was not cytotoxic nor did it elicit ceramide formation in K562, a chronic myeloid leukemia cell line; however, K562 cells were sensitive to a cell-deliverable form of ceramide, C6-ceramide. Treatment of Molt-3, an acute lymphoblastic leukemia cell line, with 4-HPR revealed moderate ceramide production (5-fold over control), robust conversion of ceramide to GC and sphingomyelin, and resistance to 4-HPR and C6-ceramide. In conclusion, this work demonstrates diversity within and among leukemia in 4-HPR sensitivity and ceramide generation and subsequent metabolism. As such, knowledge of these metabolic pathways can provide guidance for enhancing ceramide-driven effects of 4-HPR in treatment of leukemia.

Entities: CellLine Chemical Disease Gene Species

Keywords: Acute myelogenous leukemia; Ceramide metabolism; Fenretinide/4-HPR; Leukemia; Sphingolipid metabolism

Mesh：

Substances：

Year: 2015 PMID： 26220867 PMCID： PMC4573880 DOI： 10.1016/j.leukres.2015.06.009

Source DB: PubMed Journal: Leuk Res ISSN： 0145-2126 Impact factor: 3.156

47 in total

1. Elevation of glucosylceramide in multidrug-resistant cancer cells and accumulation in cytoplasmic droplets.

Authors: H Morjani; N Aouali; R Belhoussine; R J Veldman; T Levade; M Manfait
Journal: Int J Cancer Date: 2001-10-15 Impact factor: 7.396

2. N-(4-hydroxyphenyl)retinamide elevates ceramide in neuroblastoma cell lines by coordinate activation of serine palmitoyltransferase and ceramide synthase.

Authors: H Wang; B J Maurer; C P Reynolds; M C Cabot
Journal: Cancer Res Date: 2001-07-01 Impact factor: 12.701

Review 3. Evolving concepts in cancer therapy through targeting sphingolipid metabolism.

Authors: Jean-Philip Truman; Mónica García-Barros; Lina M Obeid; Yusuf A Hannun
Journal: Biochim Biophys Acta Date: 2013-12-30

Review 4. Targeting ceramide metabolism--a strategy for overcoming drug resistance.

Authors: A Senchenkov; D A Litvak; M C Cabot
Journal: J Natl Cancer Inst Date: 2001-03-07 Impact factor: 13.506

5. Resistance to the antiproliferative effect induced by a short-chain ceramide is associated with an increase of glucosylceramide synthase, P-glycoprotein, and multidrug-resistance gene-1 in cervical cancer cells.

Authors: Gisela Gutiérrez-Iglesias; Yamilec Hurtado; Icela Palma-Lara; Rebeca López-Marure
Journal: Cancer Chemother Pharmacol Date: 2014-08-12 Impact factor: 3.333

6. Ceramide glycosylation potentiates cellular multidrug resistance.

Authors: Y Y Liu; T Y Han; A E Giuliano; M C Cabot
Journal: FASEB J Date: 2001-03 Impact factor: 5.191

Review 7. Mechanism of fenretinide (4-HPR)-induced cell death.

Authors: J M Wu; A M DiPietrantonio; T C Hsieh
Journal: Apoptosis Date: 2001-10 Impact factor: 4.677

Review 8. Targeting novel signaling pathways for resistant acute myeloid leukemia.

Authors: Kathleen M Sakamoto; Steven Grant; Diana Saleiro; John D Crispino; Nobuko Hijiya; Francis Giles; Leonidas Platanias; Elizabeth A Eklund
Journal: Mol Genet Metab Date: 2014-12-05 Impact factor: 4.797

Review 9. Tumor suppressive functions of ceramide: evidence and mechanisms.

Authors: Sehamuddin Galadari; Anees Rahman; Siraj Pallichankandy; Faisal Thayyullathil
Journal: Apoptosis Date: 2015-05 Impact factor: 4.677

10. Modification of sphingolipid metabolism by tamoxifen and N-desmethyltamoxifen in acute myelogenous leukemia--Impact on enzyme activity and response to cytotoxics.

Authors: Samy A F Morad; Su-Fern Tan; David J Feith; Mark Kester; David F Claxton; Thomas P Loughran; Brian M Barth; Todd E Fox; Myles C Cabot
Journal: Biochim Biophys Acta Date: 2015-03-10

5 in total

1. Fenretinide binding to the lysosomal protein saposin D alters ceramide solubilization and hydrolysis.

Authors: Brandon T Milliken; Lindy Melegari; Gideon L Smith; Kris Grohn; Aaron J Wolfe; Kelsey Moody; Fadi Bou-Abdallah; Robert P Doyle
Journal: RSC Med Chem Date: 2020-07-14

Review 2. Harnessing the power of sphingolipids: Prospects for acute myeloid leukemia.

Authors: Johnson Ung; Su-Fern Tan; Todd E Fox; Jeremy J P Shaw; Luke R Vass; Pedro Costa-Pinheiro; Francine E Garrett-Bakelman; Michael K Keng; Arati Sharma; David F Claxton; Ross L Levine; Martin S Tallman; Myles C Cabot; Mark Kester; David J Feith; Thomas P Loughran
Journal: Blood Rev Date: 2022-04-09 Impact factor: 10.626