Obtaining specific populations of cells from heterogeneous samples is a major challenge in studying gene expression profiles of specific cell types. Laser capture microdissection (LCM), developed in a collaborative effort between the NIH and Arcturus, Inc. specifically to isolate cancer cells from normal tissue, can be used to separate individual cell types from within complex tissues. RNA can then be extracted from these microdissected cells to analyze their gene expression.
How LCM works
LCM can capture cells or discrete morphological structures from thin tissue sections. Frozen, O.C.T.-embedded tissue sections are prepared for the LCM process by fixation, staining, and dehydration. Sections are visualized through a thermoplastic film attached to the bottom of a microcentrifuge tube cap. A laser pulse is directed through the film onto the target cells. The plastic film melts onto the targeted area, then cools and bonds with the underlying cells. The film, along with the adhered target cells, is collected (Figure 1). RNA can be isolated from these captured cells for real-time PCR and mRNA expression profiling. (See our tips article Getting Intact RNA from LCM Samples.)
Capture and analyses of dentate gyrus from mouse brain
LCM was used to separate dentate gyrus from mouse brain sections (Figure 1). RNA from the captured dentate gyrus was purified using the RNAqueous-Micro Kit (see sidebar) and the purified RNA was assessed on an Agilent bioanalyzer (Figure 2). This RNA was of sufficient quality and amount for real-time RT-PCR analysis, which showed consistency between replicates and very low DNA contamination in the RNA samples purified with RNAqueous-Micro Kit (Figure 3).