A Multiplexed Luciferase-based Screening Platform for Interrogating Cancer-associated Signal Transduction in Cultured Cells

Podsumowanie

Achieving a systems level understanding of cellular processes is a goal of modern-day cell biology. We describe here strategies for multiplexing luciferase reporters of various cellular function end-points to interrogate gene function using genome-scale RNAi libraries.

Streszczenie

Genome-scale interrogation of gene function using RNA interference (RNAi) holds tremendous promise for the rapid identification of chemically tractable cancer cell vulnerabilities. Limiting the potential of this technology is the inability to rapidly delineate the mechanistic basis of phenotypic outcomes and thus inform the development of molecularly targeted therapeutic strategies. We outline here methods to deconstruct cellular phenotypes induced by RNAi-mediated gene targeting using multiplexed reporter systems that allow monitoring of key cancer cell-associated processes. This high-content screening methodology is versatile and can be readily adapted for the screening of other types of large molecular libraries.

Wprowadzenie

A variety of luciferase-based reporters for monitoring a diverse array of cell biological processes are commercially available. The majority of these DNA constructs encode luciferase proteins that are induced to express by specific cell stimuli or perturbations. The most robust transcriptionally based reporters place the expression of a luciferase enzyme under the control of synthetic enhancer elements or gene promoter regions well-established for their reliability in reporting a physiologically relevant transcriptional event^1,2. There are also trans-reporter luciferase systems that utilize GAL4-UAS to drive luciferase protein expression. Gal4 is a yeast transcriptional activator and the UAS is an enhancer to which Gal4 specifically binds to activate the transcription of gene sequences placed down-stream of it³. These types of luciferase systems are typically supported by two DNA plasmids - one encodes the GAL4 protein fused to the regulatory portion of a protein of interest, and the second encodes a luciferase protein placed under the control of one or more UAS sequences. Thus, the cellular luciferase signal reflects the activity level of the protein of interest. Another common use of luciferase-based reporters is for monitoring protein stability whereby a protein of interest is fused to a luciferase enzyme⁴. Regardless of the type of reporter, a caveat emptor is noted here as one cannot assume the specificity of any reporter to have been well interrogated. Thus, due diligence is required in the incorporation of new reporter constructs in any research strategy.

The selection of the luciferase enzyme read-out can be as important as the reliability of the DNA elements that control its expression. Whereas firefly luciferase (FL) is the most commonly used enzyme in commercially available constructs, the advent of new luciferase reporter systems that do not require ATP (as in the case of FL-based reactions) or that incorporate more stable enzymes that emit stronger signals promise to improve the efficiency and reliability of this research platform. An important note regarding the selection of luciferase reporters in chemical studies is the susceptibility of FL to chemical inhibition that could give rise to false reports. In our experience, other enzymes such as Renilla or Gaussia luciferase (RL and GL, respectively) that utilize coelenterazine as a substrate are less readily inhibited by small molecules⁵.

The most common format for multiplexing luciferase read-outs entails the use of FL and RL largely given the availability of easy-to-use kits with the ability to sequentially measure enzymatic activities from a single sample. In most kits, samples are first exposed to luciferin to reveal levels of FL activity followed by a quenching reagent that is simultaneously deposited with coelenterazine to yield a secondary RL signal. With the addition of other luciferases that can be secreted such as GL or that use yet another substrate such as Cypridina luciferase (CL), a greater number of possibilities for generating high content data using luciferases have emerged. An example of a genome-wide RNAi screen using this technique can be found here⁶. These technological advances have in turn spurred the development of specific mechanisms to quench each type of luciferase enzyme in order to limit cross-talk⁷. In our hands, we note a greater frequency of "edge effects" (inexplicable trends in cellular activity associated with the edge of high titer culture plates), with secreted luciferases such as GL or CL. On the other hand, such secreted luciferases are useful for kinetic assays as they enable signal sampling without adulterating cell viability.

For our study presented here, we will simultaneously monitor the activity of three cancer-relevant cellular processes: the p53, Kras, and Wnt signal transduction pathways. The reporters incorporated in our study are the pp53-TA-Luc FL reporter from Clontech (henceforth referred to as the p53-FL reporter)⁸, an Elk1-GAL4/UAS-CL reporter system (henceforth Elk-1 reporter; Agilent), and the 8X TCF RL reporter that incorporates multiple synthetic enhancer elements recognized by the Wnt pathway transcriptional regulators known as T-cell factors (or TCFs)^9-11.

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Protokół

Entire protocol takes approximately 4 days.

1. Preparation of Cells for siRNA and Reporter Transfection

We will introduce here a protocol for interrogating siRNA libraries using a small set of siRNAs (384 different siRNA pools array in 96 well format with each pool consisting of 4x siRNAs targeting a single gene) from a genome-wide siRNA library for illustrative purposes. For this particular study, we will exploit HCT116 cells that exhibit deviant Wnt and Kras signaling, and p53 activity. The appropriate cell line in studies aimed at interrogating other cellular processes of interest will have to be identified and evaluated in a similar fashion.

1. Wash 5 x 10 cm² plates of 80-90% confluent HCT116 cells with PBS then harvest cells by trypsinization using 1 ml of trypsinization solution/plate followed by neutralization with 10 ml of Dulbecco's modified eagle medium (DMEM) containing 2% fetal bovine serum (FBS) and 1% penicillin/streptomycin/plate.
2. Transfer suspended cells to a 50 ml conical tube and centrifugate at ~130 x g for 5 min, remove supernatant, and re-suspend cell pellet in 10 ml of DMEM/ 2%FBS/ 1% penicillin/streptomycin.
3. Count the cell number with a cell counter, and then make a cell solution with 10⁵ cells/ml, keep 150 ml cell suspension for the next step. Plate 10⁴ cells (100 μl) in each well of a 96 well cell culture plate using a Multidrop automated liquid dispenser (henceforth Multidrop). The cell suspension should be sufficient in this case for plating 12 x 96 well plates.
4. Incubate the plates with cells at 37 °C in an incubator with 5% CO₂ while preparing the transfection mixture.

2. Preparing the Reporter Construct Stock Solution

1. Isolate high-quality reporter construct DNA using standard midiprep kits (NucleoBond Xtra Midi produced by Clontech) and dilute the DNA to a final concentration of 1 mg/ml for each reporter.
2. Prepare 100 μl of reporter construct stock solution by combining 30 μl of p53-FL, 30 μl of 8X TCF-RL, 30 μl of Elk1-Gal4, 6 μl UAS-CL and 4 μl of H₂O to achieve a DNA mix with a final 1:1:1:0.2 ratio of the reporters. Final DNA concentration of this DNA mix stock solution is 0.3 mg/ml.

3. Preparing the siRNA/DNA Transfection Mix

In this part of the protocol, we will prepare siRNA/DNA transfection mixes that will be sufficient for transfecting 12 x 96 well plates. For this test library of 4 x 96 well plate of siRNAs, we will transfect each siRNA pool in triplicate. The transfection reagent we will use is called Effectene (Qiagen). In our hands this is the only reagent that works for the simultaneous delivery of siRNA and DNA into cultured cells.

1. Dilute 80 μl of reporter construct stock solution in 8 ml of EC buffer (Effectene Kit) to achieve a DNA solution with a final concentration of 3 μg/ml. In general, prepare enough DNA solution mix for immediate use.
2. Plate 20 μl of this DNA solution to each well of a 96 well/plate. The number of 96 well plates will depend on how many siRNA pools will be tested. For example, in this case we will need 4 x 96 well plates to evaluate 384 different siRNA pools.
3. The siRNAs to be tested should be at a stock concentration of 5 μM. If not, they can be replica plated and diluted to this concentration using the recommended dilution buffer associated with each library.
4. Transfer 2 μl of each 5 μM siRNA stock to the corresponding well of the PCR plate containing the diluted DNA stock with a Biomek Automated Liquid Handler. Depending on the scale of the study, a multi-channel pipettor may suffice.
5. Now, we will add 1 μl of Enhancer solution (Effectene kit) to each well of the DNA/siRNA plate. This again can be accomplished either with an automated liquid handler or multichannel pipettor.
6. Allow the Enhancer reaction to occur at RT for 5 min then add 3 μl of Effectene transfection reagent to each well and incubate at RT for an additional 10 min.
7. To stop transfection complex formation, add 10 μl of DMEM/ 2% FBS/ 1% penicillin/streptomycin to each well of the PCR plate.
8. Transfer 10 μl of the transfection mix to each well of the 96 well plate containing the cells (retrieved from the cell incubator). As each transfection will be performed in triplicate, the same mix will be applied to two additional 96 well plates containing cells.
9. Incubate the cells with transfection mixtures added at 37 °C in a humidified environment with 5% CO₂ for 36 hr.

4. Determine Luciferase Activities from Cell Samples

After 36 hr, luciferase activities are ready for measurement in transfected cells. The endpoint should be determined on a per-experiment basis. In our study, a 36 hr incubation time had previously yielded a sufficiently robust signal for meaning outcome determination. As this study incorporates multiple reporters (one secreted into the culture medium, and two others expressed in the cell cytoplasm), we will obtain measurements from both culture medium as well as a cellular lysate.

1. Detection of CL activity in the culture medium:
   1. 20 μl of culture medium is replica-plated in a white opaque 96 well plate (either using the Biomek Liquid Handler or multichannel pipettor).
   2. Add 20 μl of CL assay buffer (Targeting Systems) to each well.
   3. Add 10 μl of Cypridina luciferin substrate (Targeting Systems) to each well and detect CL activity using a luminometer (the Pherastar plate reader produced by BMG for example).
2. Detection of FL and RL activity:
   1. Lyse the cells by first removing the culture medium. This can be accomplished rapidly by turning plate upside down and tossing medium in a sink. Remaining medium can be removed by gently tapping the upside down plate on paper towels. Add 30 μl of 1X Passive Lysis Buffer (Promega) to each well of cells using the Multidrop and place on a platform rocker (Bellco is one company that makes these) set a medium speed for 5 min at the RT.
   2. Add 20 μl of the Luciferase Assay Reagent II (part of the Promega Dual Luciferase Kit) using the Multidrop and immediately measure FL activity using the luminometer. Next, add Stop & Glo Reagent (Promega) that will quench the FL activity and allow measurement of RL activity. Note: unless you are using substrate mixes that allow extended signal duration (such as Dual-Glo Luciferase Kits from Promega), the use of flash kits requires rapid measurement upon substrate addition (within 5 min).

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Wyniki

Despite advances in mapping the mutational landscape of various cancers using massive genome sequencing efforts^12-14, we still do not have in place a systematic approach for translating these observations into intervention strategies. In colorectal cancer (CRC), mutations that are predicted to affect components of three cellular processes - Wnt/β-catenin, p53, and Kras signaling - are found in 99% of all tumors suggesting they are key drivers of cellular transformation in the gut¹³. Thus, cance...

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Dyskusje

There are several purveyors of luciferase-based reporter systems (such as Promega, Targeting Systems, New England BIolabs, and Thermo Fisher) that provide useful on-line resources for those entertaining a high-throughput screen for the first time. In addition, a number of excellent reviews regarding optimizing the use of high-throughput screens for gene discovery and how RNAi-based screening results can be integrated with other -omics-based datasets should be helpful^15,16. Methods for the selection of "hits" f...

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Materiały

Name	Company	Catalog Number	Comments
REAGENTS
PathDetect Elk1 Trans-Reporting System	Agilent Technologies Inc.	219005
Pathway Profiling Luciferase System 4 pp53-TA-Luc Vector	Clontech Lab Inc.	631914
Effectene Transfection Reagent	Qiagen Inc.	301427
Dual-Luciferase Reporter Assay System	Promega Corp.	E1960
Cypridina Luciferase Assay reagent	Targeting Systems	VLAR-1
HCT116 cells	ATCC	CCL-247
CytoTox-Fluo Cytotoxicity Assay	Promega Corp.	G9260
EQUIPMENT
MultiFlo Microplate Dispenser	Labsystems Inc.	Model 832
Biomek FXP Laboratory Automation Workstation	Beckman Coulter Inc.	A31842
PHERAstar FS-multi-mode HTS microplate reader	BMG Labtech Inc.	0471-101A
Bright-Line Reichert Hemacytometers	Hausser Scientific Company	1490