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Potential mRNA degradation targets of hsa-miR-200c, identified using informatics and qRT-PCR.

Authors :
Hurteau GJ
Spivack SD
Brock GJ
Source :
Cell cycle (Georgetown, Tex.) [Cell Cycle] 2006 Sep; Vol. 5 (17), pp. 1951-6. Date of Electronic Publication: 2006 Sep 01.
Publication Year :
2006

Abstract

Using an anchored oligo(dT) based RT-PCR approach we quantified endogenous expression of ten microRNAs in six cell lines. This identified a miRNA, miR-200c, with variable expression, ranging from undetectable in MDA-MB-231 and HT1080 to highly expressed in MCF7. The variable expression provided a model system to investigate endogenous interactions between miRNAs and their computationally predicted targets. As the expression level of the predicted mRNA targets and miR-200c in these lines should have an inverse relationship if cleavage or degradation results from the interaction. To select targets for analysis we used Affymetrix expression data and computational prediction programs. Affymetrix data indicated approximately 3500 candidate mRNAs, absent in MCF7 and present in MDA-MB-231 or HT1080. These targets were cross-referenced against approximately 600 computationally predicted miR-200c targets, identifying twenty potential mRNAs. Expression analysis by qRT-PCR of these targets and an additional ten mRNAs (selected using the prediction program ranking alone) revealed four mRNAs, BIN1, TCF8, RND3 and LHFP with an inverse relationship to miR-200c. Of the remainder, the majority did not appear to be degraded (and may be translational targets) or were undetectable in the cell lines examined. Finally, inhibition of miR-200c using an anti-miRNA 2'-0-Methyl oligonucleotide (AMO) resulted in an increase in expression of one of the targets, the transcription factor TCF8. These results indicate that a single miRNA could directly affect the mRNA levels of an important transcription factor, albeit in a manner specific to cell lines. Further investigation is required to confirm this in vivo and determine any translational effects.

Details

Language :
English
ISSN :
1551-4005
Volume :
5
Issue :
17
Database :
MEDLINE
Journal :
Cell cycle (Georgetown, Tex.)
Publication Type :
Academic Journal
Accession number :
16929162
Full Text :
https://doi.org/10.4161/cc.5.17.3133