Li, Cheryl C Y and Eaton, Sally A and Young, Paul E and Lee, Maggie and Shuttleworth, Rupert and Humphreys, David T and Grau, Georges E and Combes, Valery and Bebawy, Mary and Gong, Joyce and Brammah, Susan and Buckland, Michael E and Suter, Catherine M (2013) Glioma microvesicles carry selectively packaged coding and non-coding RNAs which alter gene expression in recipient cells. RNA biology, 10 (8). pp. 1333-44. ISSN 1555-8584 (PMC OA)
Li, Cheryl C Y and Eaton, Sally A and Young, Paul E and Lee, Maggie and Shuttleworth, Rupert and Humphreys, David T and Grau, Georges E and Combes, Valery and Bebawy, Mary and Gong, Joyce and Brammah, Susan and Buckland, Michael E and Suter, Catherine M (2013) Glioma microvesicles carry selectively packaged coding and non-coding RNAs which alter gene expression in recipient cells. RNA biology, 10 (8). pp. 1333-44. ISSN 1555-8584 (PMC OA)
Li, Cheryl C Y and Eaton, Sally A and Young, Paul E and Lee, Maggie and Shuttleworth, Rupert and Humphreys, David T and Grau, Georges E and Combes, Valery and Bebawy, Mary and Gong, Joyce and Brammah, Susan and Buckland, Michael E and Suter, Catherine M (2013) Glioma microvesicles carry selectively packaged coding and non-coding RNAs which alter gene expression in recipient cells. RNA biology, 10 (8). pp. 1333-44. ISSN 1555-8584 (PMC OA)
Abstract
Interactions between glioma cells and their local environment are critical determinants of brain tumor growth, infiltration and neovascularisation. Communication with host cells and stroma via microvesicles represents one pathway by which tumors can modify their surroundings to achieve a tumor-permissive environment. Here we have taken an unbiased approach to identifying RNAs in glioma-derived microvesicles, and explored their potential to regulate gene expression in recipient cells. We find that glioma microvesicles are predominantly of exosomal origin and contain complex populations of coding and noncoding RNAs in proportions that are distinct from those in the cells from which they are derived. Microvesicles show a relative depletion in microRNA compared with their cells of origin, and are enriched in unusual or novel noncoding RNAs, most of which have no known function. Short-term exposure of brain microvascular endothelial cells to glioma microvesicles results in many gene expression changes in the endothelial cells, most of which cannot be explained by direct delivery of transcripts. Our data suggest that the scope of potential actions of tumor-derived microvesicles is much broader and more complex than previously supposed, and highlight a number of new classes of small RNA that remain to be characterized. (Cancer Council NSW Innovator Grant IG 11-15; Cancer Institute NSW, ARC Future Fellow grant FT120100097).
Metadata
Subjects: | R Medicine > R Medicine (General) |
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Depositing User: | Ms Britt Granath |
Date Deposited: | 22 Dec 2015 00:24 |
Last Modified: | 27 Jan 2016 05:01 |