Abstract
Human mesenchymal stem cells have become an important resource in developing strategies for regenerative therapies, owing to their ease of use and differentiation potential. Analytical tools, such as whole-genome expression array and validation with Solaris™ qPCR Assays, are essential to fully understand the key molecular events, such as microRNA-mediated gene modulation, that mark stem cell differentiation.
Main
Although microarrays are useful for rapid whole-genome profiling, a complementary method with improved sample throughput, sensitivity and dynamic range is needed for follow-up studies. Quantitative real-time PCR (qPCR) is often the method of choice to validate gene expression results from whole-genome microarrays. Solaris™ qPCR Gene Expression Assays are predesigned on a genome-wide scale using a novel, tier-based algorithm to detect all variants of a given gene and distinguish among closely related family members. Solaris assays incorporate minor groove binder (MGB™)1 and Superbase™ technologies (Epoch Biosciences, Inc) for increased sequence design space and enhanced specificity. Combining these two chemical strategies with a fluorescent (FAM) reporter dye and corresponding Dark Quencher™ fluorochrome (Epoch Biosciences, Inc) results in highly specific and sensitive assays that consistently function under universal thermocycling conditions. Here we describe an application of Solaris technology to validate the microarray expression data from early-stage osteogenic human mesenchymal stem cells (hMSCs).
microRNAs (miRNAs) are involved in many aspects of cellular processes; however, little is known about their role in the regulation of adult stem cell differentiation. In a recently published screen using a Thermo Scientific Dharmacon miRIDIAN microRNA Inhibitor and Mimic library, miR-148b was shown to increase alkaline phosphatase (ALPL) activity, an early marker of osteoblast differentiation2. Here we show how the novel Solaris platform was used to further characterize gene expression in hMSCs treated with differentiation medium or with miRNA mimics.
We assessed osteogenic differentiation in hMSCs treated with medium or with miRNA mimics (Fig. 1). For the medium treatments, hMSCs were grown in osteoblast differentiation medium or propagation medium. For the mimic treatment, we transfected miRIDIAN miR-148b mimic or miRNA mimic negative control 1 into hMSCs. Six days after induction of osteogenic differentiation, we collected the cells and assessed the culture for ALPL-positive cells2. Using the Thermo Scientific Cellomics VTi ArrayScan high-content imaging system, we observed an approximately eightfold increase in ALPL-positive cells treated with either differentiation medium or miRNA mimics relative to controls (data not shown).
Microarray expression analysis identified 891 genes as differentially regulated as a result of treatment with differentiation medium, and 686 as differentially regulated by the miR-148b mimic treatment (analyzed using Rosetta Resolver software). Among these, 190 genes were regulated by both treatments (Fig. 2). The majority of these genes (143) were regulated in the same direction (up or down) by both treatments.
We examined differential expression of three characterized early osteoblast marker genes3 in more detail: ALPL (alkaline phosphatase), SPP1 (secreted phosphoprotein 1) and RUNX2 (runt DNA-binding domain transcription factor). Based on the microarray analysis, ALPL and RUNX2 were modestly induced approximately two fold under medium treatment and only modestly under miRNA treatment (Fig. 3a). SPP1 expression was induced only by the medium treatment, by approximately 3.5-fold, and was slightly reduced by the miRNA treatment.
We then validated the expression levels of the same early osteogenic markers using Solaris qPCR Gene Expression Assays. We observed upregulation of all three osteogenic markers in differentiation medium–treated hMSCs: ALPL and SPP1 were induced ∼4.5-fold and >5-fold, respectively, whereas RUNX2 was only mildly induced (Fig. 3b). The relatively low induction of RUNX2 expression on day 6 is not surprising as this transcription factor is typically upregulated at the onset of osteogenic differentiation4. ALPL and RUNX2 were mildly induced in miR-148b mimic–treated hMSCs. SPP1 gene expression, however, was slightly decreased in miR-148b mimic–treated cells, in contrast to the marked induction observed with the differentiation medium treatment. This supports previously published data demonstrating a decrease in the SPP1 expression caused by the miR-148b mimic2.
The microarray and qPCR detection methods revealed relatively similar expression levels for both treatments, with the exception of ALPL (for which higher expression was indicated with qPCR detection). Although these two gene expression detection methods are commonly used for identification and validation, discrepancies between them are sometimes observed owing to the differences in sensitivity and dynamic range5. The similarities in gene expression for ALPL and RUNX2 osteogenic markers and the 143 genes identified in the expression profiling that are commonly regulated between differentiation medium– and miRNA mimic–treated cells further support a role for miR-148b in the stimulation of osteogenic differentiation of hMSCs.
Follow-up qPCR studies using Solaris qPCR Gene Expression Assays will provide a more robust and quantitative assessment of these gene expression changes and a foundation for further study of the osteoblast differentiation mechanism and miRNA involvement in this process.
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Strezoska, Z., Fedorov, Y. & Kelley, M. hMSC differentiation marker detection using Thermo Scientific Solaris™ qPCR Gene Expression Assays. Nat Methods 6, v–vi (2009). https://doi.org/10.1038/nmeth.f.274
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DOI: https://doi.org/10.1038/nmeth.f.274