Here, we present a quantitative and scalable protocol to perform targeted small molecule screens for kinase regulators of the naïve-primed pluripotent transition.
Embryonic stem cells (ESCs) can self-renew or differentiate into all cell types, a phenomenon known as pluripotency. Distinct pluripotent states have been described, termed "naïve" and "primed" pluripotency. The mechanisms that control naïve-primed transition are poorly understood. In particular, we remain poorly informed about protein kinases that specify naïve and primed pluripotent states, despite increasing availability of high-quality tool compounds to probe kinase function. Here, we describe a scalable platform to perform targeted small molecule screens for kinase regulators of the naïve-primed pluripotent transition in mouse ESCs. This approach utilizes simple cell culture conditions and standard reagents, materials and equipment to uncover and validate kinase inhibitors with hitherto unappreciated effects on pluripotency. We discuss potential applications for this technology, including screening of other small molecule collections such as increasingly sophisticated kinase inhibitors and emerging libraries of epigenetic tool compounds.
Embryonic stem cells (ESCs) have the capacity to self-renew or differentiate into any cell type in the adult body, a phenomenon known as pluripotency1. Recent evidence indicates that developmentally distinct pluripotent states exist, termed "naïve" and "primed" pluripotency2. Naïve ESCs represent a state of development similar to that found in the preimplantation embryo3. In contrast, primed pluripotent ESCs are poised to exit pluripotency and differentiate into specialized embryonic lineages4,5.
Naïve and primed pluripotent states are marked by distinct gene regulatory networks. Naïve pluripotency is characterized by expression of key pluripotency transcription factors such as Nanog, Krueppel-like transcription factors (Klfs), Rex12 and Esrrb6. In mouse ESCs (mESCs), primed pluripotency is characterized by reduced expression of naïve markers and a specific gene expression signature which includes the de novo DNA methyltransferase Dnmt3b7. In vivo, primed pluripotent post implantation epiblast stem cells (EpiSCs)4,5 additionally express the Epiblast marker Fgf5 and markers of lineage priming such as Brachyury8.
mESCs provide a tractable model to probe mechanisms that control naïve-primed pluripotent transitions in vitro. When cultured in leukemia inhibitory factor (LIF) and fetal bovine serum (FBS), mESCs undergo dynamic transition between naïve and primed pluripotent states9,10. LIF-Jak-Stat3 signaling functions to promote a naïve gene regulatory network11, whilst autocrine signaling via the fibroblast growth factor 4 (Fgf4) Erk1/2 pathway drives transition to the primed state12. However, it remains a challenge to systematically evaluate the role of protein kinases in specifying distinct pluripotent states.
Here, we describe a quantitative and scalable platform by which to perform targeted small molecule screens for kinase regulators of the naïve-primed pluripotent transition. We use simple mESC culture conditions and standard reagents, materials and equipment to uncover and validate kinase inhibitors with hitherto unappreciated ability to stabilize naïve pluripotency. Furthermore, we discuss potential extended applications for this technology, including for screening of other small molecule collections such as emerging inhibitor libraries targeting epigenetic regulators.
1. Collation of Small Molecule Kinase Inhibitor Libraries
2. mESC Culture Conditions and Procedures for Screen Preparation
3. Kinase Inhibitor Screening Analysis
4. Analysis of Screen Data and Validation of Inhibitors as Bona Fide Pluripotency Regulators
NOTE: This is a critical step to ensure that only bona fide pluripotency modulators are identified. It is essential to triage inhibitors based on both Nanog:Dnmt3b ratio and overall signal, to ensure that kinase inhibitors which adversely affect mESC survival are not selected for further analysis.
Using the procedure presented here (Figure 1), we screen the LINCS library of 228 potent and selective kinase inhibitors to identify those which modulate mESC pluripotency. The library is prepared at a concentration of 0.1 mM for a 1:100 dilution and final screening concentration of 1 µM in mESCs. 48 h later, mESCs were lysed and extracts prepared for quantitative dot blot analysis of Nanog and Dnmt3b expression (Figure 2, top). Results from other screening concentrations are not represented here for brevity. Nanog:Dnmt3b ratio is determined for each kinase inhibitor and compounds ranked and a 2x cut-off applied (Figure 2, bottom). Total Nanog and Dnmt3b signal relative to control is overlaid onto inhibitor ranking and subjected to a 0.5x cut-off, to allow triaging of inhibitors which show significant mESC toxicity. Select kinase inhibitors which stabilize the naïve state are validated using conventional Nanog/Dnmt3b immunoblotting (Figure 3). The primary kinase targets of these inhibitors are presented in Table 1. We also demonstrate the applicability of this screen to identify inhibitors which stabilize the primed state14.
Figure 1: Workflow for screening kinase inhibitors that modulate naïve-primed transition. mESC were treated with a 228 compound kinase inhibitor library at a final concentration of 1 µM. Lysates were prepared and transferred onto nitrocellulose membranes for immuno dot-blot analysis, and Nanog and Dnmt3b levels determined (Figure adapted from Williams et al.14). Please click here to view a larger version of this figure.
Figure 2: Naïve-primed pluripotency screen analysis and inhibitor identification. (Top) Representative Nanog and Dnmt3b immuno dot-blot images. (Bottom) Nanog and Dnmt3b values for each kinase inhibitor were determined relative to the DMSO control, and Nanog:Dnmt3b ratios and total relative Nanog+Dnmt3b signal determined and inhibitors ranked in comparison to DMSO control. Inhibitors found to alter Nanog:Dnmt3b ratio beyond a 2-fold threshold above or below DMSO control were identified as drivers of naïve or primed pluripotency. A threshold of 2x below DMSO control was set to triage inhibitors which compromise mESC survival. Inhibitors selected for further validation are highlighted. (Figure adapted from Williams et al.14). Please click here to view a larger version of this figure.
Figure 3: Validation of selected hit compounds identified. mESCs were treated with either 1 µM AZD4547 (a selective FGFR inhibitor) or the indicated inhibitors identified from the screen in Figure 2. Nanog:Dnmt3b levels determined by standard SDS-PAGE and immunoblot analysis. Numerical values of relative Nanog:Dnmt3b and Nanog+Dnmt3b are indicated in the table below, and inhibitors which stabilize the naïve pluripotent state highlighted in green. Please click here to view a larger version of this figure.
Compound | Primary Targets | Other Targets | |
AV-951 | VEGFR | ||
HG-6-64-01 | ABL, BRAF, RET, CSF1R, EGFR, EPHA8, FGFR, FLT3, KIT, LOK, MAP4K1, p38b, MUSK,PDGFR, TAOK3, TNNI3K | ||
WH-4-023 | Lck | Src | |
R406 | Syk | ||
GW-572016 | HER2 | EGFR | |
KIN001-244 | PDK1 | ||
WZ-4-145 | CSF1R, DDR1, EGFR, TIE1, PDGFR2 | ||
WZ-7043 | CSF1R, DDR1, FGFR and TAO1 | ||
GW786034 | VEGFR1 | VEGFR2, VEGFR3 | |
AZD-1480 | JAK2 |
Table 1: Selected hit compounds and their primary kinase target(s).
Here we demonstrate a widely accessible methodology to probe the role of kinase signalling pathways in regulating naïve-primed pluripotent transition. This addresses a key question in the ESC field. Although high-throughput genomics and transcriptomics approaches are routinely used to identify key transcriptional regulators of naïve and primed pluripotent states, elucidating pluripotency signalling networks has proven to be challenging. We now provide a flexible strategy employing chemical inhibitors to identify kinases that control naïve-primed pluripotent transition in mESCs. This relies on simple equipment, reagents and materials that are available to most laboratories that study cell signalling and ESC biology. Critical to the success of this platform is our development of a robust assay to quantify the transition between naïve and primed pluripotent states. Establishing this assay required significant iterative modifications to cell plating density, time of inhibitor incubation and immunoblotting conditions.
Small molecule approaches are gaining traction for rational use in therapeutic ESC applications15,16. A major strength of small molecule screening is that tool compounds are designed and/or modified for efficient cellular uptake. Transfection efficiency is not limiting, and use of hazardous delivery systems such as lentivirus is not necessary. Furthermore, inhibitors frequently inhibit multiple isoforms within a kinase family (e.g. Fgfr1-4, Jak1-3), which overcomes functional redundancy that hinders genetic/genomic interference techniques such as RNAi and CRISPR/Cas9. As more potent and selective tool compounds become available from both academic and pharmaceutical drug discovery programmes, understudied and poorly understood kinases will be pushed to the forefront of ESC research. We therefore propose that this high-throughput screening approach will open up new avenues of research into core ESC regulatory networks.
One minor limitation of this technology is that even the most potent and selective small molecule inhibitors engage and inhibit multiple unrelated kinases in vivo. However, increasingly comprehensive kinase inhibitor profiling data allows functional targets of kinase inhibitors to be readily identified (http://lincs.hms.harvard.edu/kinomescan; http://www.kinase-screen.mrc.ac.uk/kinase-inhibitors). Finally, in principle our platform can be applied to interrogate any small molecule collection and/or cellular assay for which high-quality immunoblotting antibodies are available. This will allow study of multiple regulatory systems in pluripotency regulation and facilitate identification of small molecule inhibitors which modify diverse cellular processes. Specifically, we envisage that application of emerging small molecule collections such as the epigenetic probes being developed by the Structural Genomics Consortium (http://www.thesgc.org/chemical-probes/epigenetics) has the potential to uncover further novel regulators of pluripotent transitions.
The authors have nothing to disclose.
C.A.C.W is supported by a Medical Research Council PhD studentship. G.M.F. is supported in part by a Medical Research Council New Investigator Award (MR/N000609/1) and a Tenovus Scotland research grant.
mESC media | |||
CCE mESCs | ATCC | ATCC SCRC-1023 | |
DMEM Media | Gibco | 11965092 | |
L-Glutamine | Gibco | 25030081 | Final: 2mM |
Penicillin/Streptomycin | Gibco | 15140122 | Final: 50U/ml |
2-mercaptoethanol | Sigma | M6250 | Final: 0.1mM |
Leukemia Inhibitory Factor (GST fusion) | MRC-PPU reagents and services | Final: 100ng/ml | |
Leukemia Inhibitory Factor | Thermo | PMC9484 | Final: 100ng/ml |
Non-Essential Amino Acids | Gibco | 11140050 | Final: 0.1mM |
Sodium Pyruvate | Gibco | 11360070 | Final: 1mM |
KnockOut Serum Replacement | Invitrogen | 10828-028 | Final: 5% |
Defined Fetal Bovine Serum | Fisher | 10703464 | Final: 10% |
Name | Company | Catalog Number | コメント |
TC materials | |||
Trypsin-EDTA (0.05%), phenol red | Thermo | 25300054 | |
Gelatin from porcine skin | Sigma | 1890 | |
Nunc MicroWell 96-Well Microplates | Thermo | 156545 | |
DPBS, no calcium, no magnesium | Gibco | 14190136 | |
V-bottom 96 well plates | Greiner Bio-one | 651261 | |
Name | Company | Catalog Number | コメント |
Lysis Buffer | |||
Tris buffer | VWR | 103157P | |
Sodium Chloride | VWR | 97061 | |
EDTA | Sigma | E4884 | |
1% NP-40 | Sigma | 9016-45-9 | |
Sodium Deoxycholate | Sigma | D6750-100g | |
β-glycerophosphate | Sigma | G9422 | |
Sodium Pyrophosphate | Sigma | 13472-36-1 | |
Sodium Fluoride | Sigma | 450022 | |
Sodium Orthovanadate | Sigma | 450243 | |
Roche Complete Protease Inhibitor Cocktail Tablets | Sigma | CO-RO | |
Name | Company | Catalog Number | コメント |
Chemicals | |||
Tween | Sigma | P1379-1L | |
Milk Powder | Marvel | ||
Name | Company | Catalog Number | コメント |
Western Blotting | |||
Protran BA 85 Nitrocellulose 0.45uM Pore size (20 X 20cm Sheets) (25 Sheet) | GE | 10401191 | |
Ponceau S | Sigma | P7170-1L | |
Name | Company | Catalog Number | コメント |
Laboratory Equipment | |||
Minifold I System | GE | 10447850 | |
ChemiDoc imager | BioRad | 1708280 | |
LiCor Odyssey Imager | LiCor | ||
Name | Company | Catalog Number | コメント |
Antibodies | |||
Anti-mouse Nanog | Reprocell | RCAB001P | |
Anti-Dnmt3b | Imgenex | IMG-184A | |
IRDye 800CW Donkey anti-Rabbit | Licor | 926-32213 | |
Anti-mouse-HRP | Cell Signalling Technology | 7076S | |
Anti-Klf2 | Millipore | 09-820 | |
Anti-Klf4 | R&D Systems | AF3158 | |
Anti-Oct4 | Santa Cruz | sc-5279 |