A sensitive flow cytometric method for multi-parametric analysis of microRNA, messenger RNA and protein in single cells.

Analysis of RNA expression in mixed cell populations often requires laborious and costly cell sorting. Here we describe a flow cytometric assay that combines antibody staining and in situ hybridization for multi-parametric analysis of single cells. This method, referred to as the PrimeFlow™ RNA Assay, enables simultaneous detection of protein markers and RNA targets in mixed cell populations. Both coding and non-coding RNA sequences can be measured with a limit of detection of approximately 10 copies of mRNA and 20 copies of microRNA per cell. In this study, we used mouse bone marrow-derived macrophages to demonstrate that our method allows for analysis of the activation and polarization status of cells using expression patterns of protein and RNA. We then performed analysis of four cell subsets of mouse resident peritoneal cells and showed that the two macrophage populations present in this compartment are relatively heterogeneous in terms of expression of two M2 markers: Arg1, Retnla, and a B-cell attractant chemokine Cxcl13. In addition, we profiled the expression of a panel of microRNA in the four peritoneal cell subsets, showing that the assay can be readily adapted to parallel, high-throughput screening of multiple cell populations. This new method allows for single cell analysis of multiple RNA targets without the need for cell sorting, enables direct correlation between RNA and protein expression, and promises to accelerate biomarker and drug discovery.

Development of luciferase reporter-based cell assays.

Using luciferase reporter constructs driven by specific promoter response elements, we developed a series of stable reporter cell lines for monitoring the activity of specific transcription factors (TFs). These TFs, which play essential roles in regulating diverse biological functions, include nuclear factor kappaB (NFkappaB), cyclic AMP response element-binding protein, activator protein 1, signal transducer and activator of transcription 1 and 3, nuclear factor of activated T cells, serum response factor, and hypoxia-inducible factor. The response of the stable reporter cells was highly specific. For example, tumor necrosis factor-alpha (TNFalpha) strongly activated NFkappaB reporter cells, but not other cell lines. The NFkappaB reporter was active in multiple cell lines, including 293T, HeLa, A549, and NIH3T3 cells, in response to TNFalpha, indicating that this system is useful to monitor specific TFs in different model cell lines. To facilitate high throughput screening of these cell lines, they were adapted to a 96-well format. These stable reporter cells are also applicable for the analysis of steroid hormone receptors, which bind directly to the response element after ligand binding. With the HeLa/glucocorticoid response element-luciferase stable reporter cells, we were able to discriminate pharmacological activity of different compounds for the glucocorticoid receptor. Taken together, these results demonstrate that the stable reporter cells are useful tools for: (1) detection of signaling pathway-specific ligands; (2) identification of novel ligands for specific TFs, and (3) screening for agonists and antagonists of specific ligands/receptors.

Profiling activities of transcription factors in breast cancer cell lines.

Transcription factors (TFs) are critical regulators of cell growth and differentiation, whose dysfunction is associated with many human diseases, including cancer. To facilitate the discovery of functionally altered TFs among the approximately 2,000 human TFs, we (Panomics, Inc., Fremont, CA) developed a Protein/DNA array technology that can be used to profile the activities of multiple TFs simultaneously. In this study, we applied this technology to examine the TF activities in three different breast cancer cell lines: MCF7 (estrogen receptor [ER] +, tamoxifen-sensitive), T47D (ER+, tamoxifen-resistant), and HCC1806 (ER-, tamoxifen-resistant). We compared the differences in TF activity in these cells lines following treatment with estradiol or tamoxifen. We found a number of TF activities unique to each of these cell lines. In addition to verifying previous findings, the novel findings of this study provide a more comprehensive view of the differences in the response of these cancer lines to estrogen and tamoxifen.

Trafficking the NGF signal: implications for normal and degenerating neurons.

Nerve growth factor (NGF) activates TrkA to trigger signaling events that promote the survival, differentiation and maintenance of neurons. The mechanism(s) that controls the retrograde transport of the NGF signal from axon terminals to neuron cell bodies is not known. The 'signaling endosome' hypothesis stipulates that NGF, TrkA and signaling proteins are retrogradely transported on endocytic vesicles. Here, we provide evidence for the existence of signaling endosomes. Following NGF treatment, clathrin-coated vesicles (CCVs) contain NGF bound to TrkA together with activated signaling proteins of the Ras/pErk1/2 pathway. NGF signals from isolated CCVs through the Erk1/2 pathway. Early endosomes appear to represent a second type of signaling endosomes. We found that NGF induced a sustained activation of Rap1, a small monomeric GTP-binding protein of the Ras family, and that this activation occurred in early endosomes that contain key elements of Rap1/pErk1/2 pathway. We discuss the possibility that the failure of retrograde NGF signaling in a mouse model of Down syndrome (Ts65Dn) may be due to the failure to retrograde transport signaling endosomes. It is important to define further the significance of signaling endosomes in the biology of both normal and degenerating neurons.

High-throughput detection of miRNAs and gene-specific mRNA at the single-cell level by flow cytometry.

Fluorescent in situ hybridization (FISH) is a method that uses fluorescent probes to detect specific nucleic acid sequences at the single-cell level. Here we describe optimized protocols that exploit a highly sensitive FISH method based on branched DNA technology to detect mRNA and miRNA in human leukocytes. This technique can be multiplexed and combined with fluorescent antibody protein staining to address a variety of questions in heterogeneous cell populations. We demonstrate antigen-specific upregulation of IFNγ and IL-2 mRNAs in HIV- and CMV-specific T cells. We show simultaneous detection of cytokine mRNA and corresponding protein in single cells. We apply this method to detect mRNAs for which flow antibodies against the corresponding proteins are poor or are not available. We use this technique to show modulation of a microRNA critical for T-cell function, miR-155. We adapt this assay for simultaneous detection of mRNA and proteins by ImageStream technology.