Laser-capture Microdissection of Human Prostatic Epithelium for RNA Analysis

Summary

The goal of this protocol is to use laser-capture micro-dissection as an effective method to isolate pure populations of cell types from heterogeneous prostate tissues for downstream RNA analysis.

Abstract

The prostate gland contains a heterogeneous milieu of stromal, epithelial, neuroendocrine and immune cell types. Healthy prostate is comprised of fibromuscular stroma surrounding discrete epithelial-lined secretory lumens and a very small population of immune and neuroendocrine cells. In contrast, areas of prostate cancer have increased dysplastic luminal epithelium with greatly reduced or absent stromal population. Given the profound difference between stromal and epithelial cell types, it is imperative to separate the cell types for any type of downstream molecular analysis. Despite this knowledge, the bulk of gene expression studies compare benign prostate to cancer without micro-dissection, leading to stromal bias in the benign samples. Laser-capture micro-dissection (LCM) is an effective method to physically separate different cell types from a specimen section. The goal of this protocol is to show that RNA can be successfully isolated from LCM-collected human prostatic epithelium and used for downstream gene expression studies such as RT-qPCR and RNAseq.

Introduction

The prostate gland is a heterogeneous tissue composed of secretory epithelium arranged in glandular acini surrounded by fibromuscular stroma composed primarily of smooth muscle¹. The epithelial compartment is comprised of five different but organized cell types: basal cells, secretory cells, neuroendocrine cells, transit amplifying cells and stem cells². In prostate cancer (PCa), which arises from the luminal epithelial cells, the growth of the adenocarcinoma causes an evident progressive decline of the stromal compartment³. For these reasons, tissue specimens will have distinct differences in the proportion of stromal and epithelial cell type based on the extent of PCa. These differences can lead to biased assumptions of the gene expression data acquired from whole tissues without regard to microdissection of the desired cell type. Therefore, to remove this bias it is essential to separate cell types prior to RNA extraction and gene expression analysis.

Macrodissection or microdissection can be used to physically separate well-characterized epithelial areas from the surrounding stroma^4-6. Macrodissection is typically done with a razor blade under a dissecting microscope and works well for separating large PCa nodules from stroma, but is not capable of removing benign epithelium from surrounding stroma (see example of benign prostate histology in Figure 1). Microdissection with a laser (LCM) is significantly more labor intensive than macrodissection, but can very accurately dissect benign epithelium⁴.

Recent publications from our lab have shown that RNA can be successfully extracted by LCM from either formalin-fixed paraffin-embedded (FFPE) biopsies or frozen tissue^4,7-9. The major challenges in LCM-RNA extraction are 1) to accurately dissect the desired areas of the tissue, and 2) to preserve RNA integrity during the LCM and isolation process^4,10. RNA isolated from pure cell populations can be used for gene expression analysis by several methods including reverse-transcription quantitative PCR (RT-qPCR)^7,8, microarray¹¹, and deep -sequencing^12-14.

The goal of this protocol is to isolate total RNA from LCM prostatic epithelium from frozen tissue for downstream gene expression analyses.

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Protocol

All human tissues used for these experiments were acquired via an Institutional Review Board approved protocol and/or exemption at University of Illinois at Chicago.

1. Section Fresh Frozen Prostate onto PEN-slide and onto Charged Glass Slide

1. The day before or a few hours before sectioning the sample, clean tools (i.e., brush, forceps, coplins, blades, PEN-framed slides (if not already RNase free), an ETOH safe marker and a pencil) and the inside of a RT cryostat with RNase-decontaminating solution using a spray bottle and lab-wipes.
   1. Allow RNase-decontaminating solution to sit for 5 min before wiping away, rinse with depcH₂0 to remove left over RNase-decontaminating solution and a final rinse with 70% EtOH (prepared with depcH₂0).
      Note: It is essential to maintain an RNase-free workspace. All coplins, tools, frozen mounting medium, blades and slides used should be used only for RNase free work and never used in a standard non-RNase free environment. All instruments must be treated with an RNase decontamination solution before each experiment.
2. Cool cryostat to -24 °C.
3. Place the following cleaned RNase free instruments inside cryostat to cool at least 30 min prior to sectioning: slide coplin-filled with 100% ethanol, tools, small frozen tissue cassettes and mounting chuck.
4. Retrieve frozen prostate tissue from cryostorage and place into a dry-ice-filled foam bucket for transport. Place tissue into cryostat to equilibrate to cryostat temperature for at least 30 min.
   Note: Human prostate tissues for laser-capture micro-dissection can be either fresh-frozen or formalin-fixed paraffin-embedded (FFPE). The time constraints and slide preparation are slightly different between tissue sources. Here we describe the steps for frozen sections.
5. Work with one tissue at a time, and squirt frozen mounting medium into the bottom of the cassette and quickly mount the frozen prostate tissue into the frozen mounting medium using the chilled forceps.
6. Place the cassette with tissue onto chiller in cryostat for 5 min to set frozen mounting medium.
7. Squirt a small amount of frozen mounting medium onto the chuck and carefully press mounted tissue bottom side up onto the frozen mounting medium. Let set in the cryostat for 5 min to allow the frozen mounting medium to completely solidify.
8. Place chuck into the holder and tighten.
9. Lock the handle in locked position and place a new blade onto the cryostat. For downstream molecular endpoints that include an amplification step (i.e., qPCR) it is advisable to use a new blade for each patient to prevent contamination (or move the blade over to use area of the blade for the next sample).
10. Unlock the handle and carefully advance the tissue by hand or with a foot pedal to even and expose the tissue with 50 µm sections until the desired tissue exposure is reached.
11. Adjust cryostat to 5 µm, cut one or two sections and place them onto charged glass slide for hematoxylin and eosin (H&E) staining (see Step 2).
12. Immediately place the slide into the cold 100% ethanol for 2 min.
13. Remove the charged glass slide from ethanol and let it dry at RT before proceeding to H&E staining (Step 2).
14. Place RT PEN-frame slide on a frame supporter.
15. Adjust cryostat to 10 µm and place sections onto the RT PEN frame slides. One to four sections can be place onto each slide depending on the tissue size.
16. Immediately plunge the slide into the cold 100% ethanol for 2 min.
17. Remove the PEN-frame slides from ethanol and store the slide in a slide box in a desiccator box in a -80 °C freezer until ready for LCM. Three days is the maximum storage time for optimal RNA recovery.
18. Proceed with Step 2 for ONLY the charged glass slide. Proceed with Step 3 for PEN-frame slide.

2. Hematoxylin and Eosin-Y (H&E) Stain for Histological Mark-up

Note: This if for the tissue on the charged glass slide and NOT the PEN-frame slide for LCM.

1. Hydrate the sections on the charged glass slide dipping the slide through graded ethanol as follows: dip the slide two times in 100% ethanol for 3 min, two times in 95% ethanol for 3 min, once in 70% ethanol for 3 min and two times in distilled H₂O for 3 min.
   1. Prepare acid alcohol solution: 99 ml 70% ethanol + 1 ml 1% HCl and 0.1% sodium bicarbonate solution: 0.1 g Sodium bicarbonate in 100 ml distilled H₂O
2. Dip the slide in Hematoxylin Gill II (0.4%) for 5 min.
3. Wash off excess stain in steady running tap H₂O for 3 min.
4. Dip the slide 10 times in acid alcohol
5. Wash the slide in running tap H₂O for 3 min.
6. Dip the slide in 0.1% sodium bicarbonate solution for 30-60 sec to turn the purplish color to blue.
7. Wash the slide in running tap H₂O for 3 min.
8. Rinse the slide in 95% ethanol with 10 dips.
9. Dip the slide in Eosin-Y 2-3 times for 15 sec total.
10. Dehydrate the slide through graded ethanol as follows: dip the slide two times in 95% ethanol, two times in 100% ethanol, and two times in Xylene (make sure the tissue appears clear which indicates thorough dehydration).
11. Mount the slide with non-aqueous permanent hard mounting medium and cover slip.
12. Let the slide dry for 30 min.
13. Scan slide with any whole slide scanner and print a large, high-resolution image onto 8” x 11” paper.
14. Outline areas of interest (typically done by a board certified pathologist) with a marker. This markup is the guide for the LCM procedure.

3. Toluidine Blue Staining of PEN-frame Slides

Note: This is done the SAME DAY as the LCM. Use depcH₂O water for all solutions. Complete all steps in RNase-free area. All coplins must be cleaned with RNase-decontaminating solution.

1. The day of LCM remove the PEN-frame slides from -80 °C freezer and hydrate by gently dipping slides into 90% EtOH for 2 min then 75% EtOH for 2 min.
   1. Prepare 0.5% toluidine blue by dissolving in molecular biology grade water then filter sterilize through a 0.2 µm filter and store at RT. This solution may be re-used for up to 6 months. Note: It is highly advised to prepare the solution prior to as the filtration can take a few hr.
2. Stain the prostate tissue by gently dipping slides into 0.5% toluidine blue for 5-30 sec. Destain the tissue by washing slides 2 times in depcH₂O for 15 sec followed by 75% EtOH for 30 sec to 3 min. Note: stain and destain times can be adjusted to ensure good staining. Prostate tends to over stain.
3. Transfer PEN-frame slides to RNAase-free dry container on ice.

4. Laser-capture Micro-dissection (LCM)  

1. Immediately prior to LCM, dry slide on a slide warmer at 42 °C for 15 min. Dry only the slide that will be processed and store the rest on ice until ready for them.
2. Turn on LCM and computer in this order, microscope power, the laser key, the laser switch and then the computer. Launch the Laser Microdissection software.
3. Use the software to control the microscope to load the slides and collection tubes. Click on “unload sample holder”, load the slide with the sections onto the microscope slide holder with the tissue facing down and insert the slide holder in the appropriate slot in the microscope, then click “continue”.
   1. Click on “unload collection tubes”, label and load 0.5 ml tubes onto tube holder and insert it in the appropriate slot in the instrument. Once caps are secured, add 35 μl of Lysis buffer to the collection caps and try to avoid bubbles. Then click “OK”.
      Note: If evaporation is an issue, dilute the buffer as follows: 25 µl lysis buffer with 10 µl depcH2O.
4. In the software, select the position where the slide has been placed in the slide holder. Select the collection cap to collect the LCM specimen.
5. Visualize and focus the slide through the computer at 10X. Use the software to calibrate the laser by selecting “Laser” then “calibrate”. Adjust the power, aperture and speed of the laser, selecting “laser” then “control” to allow the laser beam to cut the area selected completely and efficiently. Repeat adjustments until the laser cuts completely through the tissue.
6. Using the 8” x 11” pathologist mark-up as a guide, use the “draw shape” tool to circumscribe the desired areas of epithelium in the view and avoid collecting any stroma.
   Note: Multiple areas can be selected within one view, but do not move to another view without first cutting by clicking the “cut shape” tool.
   1. If an area does not get completely cut by the laser use the “move and cut” tool to go over it manually. Continue moving the objective to new views and repeat laser cutting until slide is completely dissected or the desired amount of tissue has been collected (typically 100 benign glands yield 150-500 ng of RNA). (see example in Figure 1A).
7. Carefully remove tubes from the collection holder and close the caps, being mindful of the lysis buffer and tissue in the caps. Briefly centrifuge for 30 sec to collect liquid and tissue in the bottom of the tube. Incubate the samples at 42 °C for 30 min and store at -80 °C until ready for RNA isolation.

5. Total RNA Isolation with a Filter-based Kit and Quality Analysis

1. Thaw out the tubes on ice and bring the volume of the solution to 100 µl.
2. Pre-wet the micro filter of an RNA isolation kit by applying 30 µl ofLysis Solution to the center of the filter and allow it to soak whileperforming the next two steps (at least 5 min).
3. Add 3 µl of LCM Additive solution (provided in the kit) to the lysate and mix by vortexing for 5 sec. Centrifuge for 30 sec to collect the fluid at the bottom of the tube.
4. Centrifuge the pre-wetted filter for ~30 sec at top speed to remove liquid.
5. Add 1.25 volumes (in this case 129 µl) of 100 % ethanol to the lysate mixture, gently vortex or pipette up and down. **This method will recover both large and small RNA species.
6. Load the sample onto the pre-wetted micro filter, and centrifuge at 10,000 x g for 1 min to bind the RNA to the filter. Then wash micro filter with 180 µl of “Wash solution 1,” centrifuge at 10,000 x g for 1 min.
   Note: From this point on all centrifugations should be done at 13,000 x g, or maximum speed.
7. Wash filter twice with 180 µl of ”Wash solutions 2 and 3”, respectively as directed by the kit protocol. Centrifuge for 30 sec, then discard the flow through, and spin the filter for 1 min to remove residual fluid and to dry the filter.
8. Transfer filter to a new collection tube.
9. Warm elution solution to -95 °C (provided with the kit).
10. Apply 10 µl of preheated elution solution to the center of the filter, close the cap and store for 5 min at RT. Then centrifuge for 1 min to elute the RNA, and repeat this step one time to yield ~20 µl of RNA.
11. Perform the DNase I treatment for 15 min at 37 °C.
12. Quantify the RNA by spectrophotometer with absorbance at 260 nm. The ratio of optical density at wavelengths of 260 nm and 280 nm is used to assess the purity of the RNA (see Table 1)¹⁵.

6. Gene Expression Analysis

Note: Gene expression of long RNA species (like mRNAs and lncRNAs) is shown in Step 6.1 and short RNA species (like microRNAs) is shown in step 6.2. Different kits are available for RT-qPCR and the amount of RNA required varies by kit (as little as 10 ng). RNA sequencing analysis is described in 6.3.

1. Reverse transcribe (RT) the RNA to cDNA mixing 5 µl of 20 ng/µl RNA sample with 5 µl of the RT master mix (RT buffer, dNTP’s, random primers, RT enzyme, RNase inhibitor). Incubate the reaction for 25 min at 25 °C, then 120 min at 37 °C and 5 min at 85 °C.
2. Dilute the RT reaction 1:10 with RNase free water and use 2.5 µl per 10 µl qPCR reaction with primers or primer/probe sets for the genes of interest.
   Note: To facilitate analysis of partially degraded RNA It is advisable to use primers for shorter amplicons (less than 100 bp)¹⁶. (Table 2B)
   1. For microRNA expression analysis run the RT reaction by mixing 5 µl of 2-10 ng/µl RNA sample with 5 µl of the RT master mix.
      Note: each commercially-available PCR-based microRNA detection technology requires the use of proprietary and specific RT primers.
3. Alternatively or in addition to RT-PCR, use next generation sequencing (RNA-seq or small-RNA-seq) to quantify different species of RNAs. Typically, use 500 ng of RNA for this procedure (Table 3) and carry out the method as indicated by the manufacturer and detection instrument.

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Results

In a previous study we demonstrated the use of LCM to collect epithelial and stromal tissues to compare expression profiling by RT-qPCR of mRNA and microRNAs from frozen and FFPE prostate tissues from the same patient⁴. LCM is time consuming, particularly if large amount of RNA is to be collected for next-generation sequencing analysis. Therefore, it is crucial to keep the working space and tools RNase free. It is recommended to examine quality and cell-specificity controls in the RNA collected (discussed in m...

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Discussion

Gene expression profiling from human specimens can be challenging, not only for the quality or quantity of tissue available, but also for the various histological entities present in a given tissue specimen. This is particularly challenging in the prostate in which benign tissues are largely stromal tissues and areas of cancer are devoid of stroma. LCM facilitates physical separation of prostatic stroma and epithelium RNA for a more accurate signature of the two different cell types (Figure 1A). In compa...

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Materials

Name	Company	Catalog Number	Comments
RNase-AWAY	MBP	7005-11
PEN-membrane 4.0 mm slides	Leica	11600289
Glass slides, Superfrost Plus	FisherBrand	12-550-15
Ethanol 200 proof	Decon labs.	2701
DEPC (diethyl pyrocarbonate)	Sigma	D-5758
Cryostat	Leica	CM3050
Coplins (Staining jar)	IHCWORLD	M900-12
Coplins (Staining rack)	IHCWORLD	M905-12
Aperio ScanScope	Aperio(Leica)	ScanScope® CS
Toluidine Blue	Fluka	89640-5G
Laser Microdissection System	Leica	LMD7000
0.5 ml Thin-walled Tubes for LCM	Thermo Scientific	AB-0350
RNAqueous®-Micro Total RNA Isolation Kit	Ambion	AM1931	Thermo Fisher Scientific Brand
NanoDrop	Thermo Scientific	ND-1000
Qubit 2.0 Fluorometer	Life Technologies	Q32866	Thermo Fisher Scientific Brand
High-Capacity cDNA Reverse Transcription Kit	Applied Biosystems	4368814	Thermo Fisher Scientific Brand
Universal cDNA Synthesis Kit II, 8-64 rxns	Exiqon	203301
TaqMan microRNA RT kit	Applied Biosystems	4366597	Thermo Fisher Scientific Brand
Hematoxylin stain	Ricca Chemical Company	3536-16
Eosin-Y	Richard Allan Scientific	7111