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In This Article

  • Erratum Notice
  • Summary
  • Abstract
  • Introduction
  • Protocol
  • Results
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Erratum
  • Reprints and Permissions

Erratum Notice

Important: There has been an erratum issued for this article. Read More ...

Summary

An RNA pull-down protocol is optimized here for detection of interactions between RNA-binding proteins (RBPs) and noncoding as well as coding RNAs. An RNA fragment from androgen receptor (AR) was used as an example to demonstrate how to retrieve its RBP from lystate of primary brown adipocytes.

Abstract

RNA-binding proteins (RBPs) are emerging as a regulatory layer in the development and function of adipose. RBPs play a key role in the gene expression regulation at posttranscriptional levels by affecting the stability and translational efficiency of target mRNAs. RNA pull-down technique has been widely used to study RNA-protein interaction, which is necessary to elucidate the mechanism underlying RBPs' as well as long non-coding RNAs' (lncRNAs) function. However, the high lipid abundance in adipocytes poses a technical challenge in conducting this experiment. Here a detailed RNA pull-down protocol is optimized for primary adipocyte culture. An RNA fragment from androgen receptor's (AR) 3' untranslated region (3'UTR) containing an adenylate-uridylate-rich elementwas used as an example to demonstrate how to retrieve its RBP partner, HuR protein, from adipocyte lystate. The method described here can be applied to detect the interactions between RBPs and noncoding RNAs, as well as between RBPs and coding RNAs.

Introduction

RBPs are proteins that bind to the double or single stranded RNA in cells and participate in forming RNA-protein complexes. RBPs may bind a variety of RNA species, including mRNA and long noncoding RNAs (lncRNAs), and exert their influence at post-transcriptional levels. Both RBPs and lncRNAs are emerging as novel regulators in adipose development and function1,2,3. To understand the mechanism of RBP- and lncRNA-mediated regulation of cellular pathways, it is often necessary to detect the interaction between a specific RNA molecule and one or several RBPs, and, sometimes, to identify the full spectrum of protein partners of a RNA transcript. However, the experiment can be challenging due to the high content of lipids in adipocytes. The RNA pull-down protocol described here can be employed to retrieve the protein partners of a specific RNA from the adipocyte lysates of primary cultures4,5.

Rationale for this protocol is summarized as follows. An RNA bait is in vitro transcribed from an DNA template, biotin-labeled and conjugated to streptavidin-coated magnetic beads4. The RNA bait is incubated with cellular lysates to allow for the formation of RNA-protein complexes, which are subsequently pulled down on a magnetic stand. More specifically, the RNA pull-down protocol described below use an RNA fragment from AR 3'UTR as the bait to retrieve HuR protein, a universally expressed RBP bound to 3'UTR of mRNAs6,7, from theadipocytelysate of primary culture. To test the binding specificity of this assay, a non-relevant RNAas well as blank streptavidin beads is included as control. This protocol is compatible with western blotting or mass spectrometry (MS) to confirm the capture of a specific RBP or to identify the full repertory of captured RBPs, respectively8.

Several techniques are available to study RNA-protein interactions. To reveal RNAs bound by a given RBP, RIP (RNA immunoprecipitation) and CLIP (UV crosslinking and immunoprecipitation) can be applied. In contrast, to identify protein partners of a given RNA, RNA pull-down, ChIRP (chromatin isolation by RNA purification), CHART (capture hybridization analysis of RNA targets) and RAP (RNA antisense purification) can be applied. In comparison with the later ones, RNA pull-down technique takes less effort to set up. It can be employed to capture proteins in vitro and in vivo. The in vivo approach of RNA pull-down, which is technically more challenging than its in vitro counterpart, preserves RNA-protein interactions by crosslinking in cells, captures aptamer-tagged RNAs of interest from cells, and subsequently detects bound RBPs. RNA pull-down can be used to enrich low abundant RBPs, and to isolate and identify the RNA-protein complexes that have diverse functional roles in controlling cellular regulation9,10.

Protocol

NOTE: The RNA of interest in the context of this study is a fragment of AR 3'UTR.

1. Preparation of Biotin-labeled RNA

  1. To obtain the RNA, amplify T7-AR-oligo by PCR, followed by in vitro transcription using a commercial kit and following manufacturer's instructions11.
    NOTE: Primers for PCR are listed in Table 4: T7-AR-F and T7-AR-R.
  2. For non-specific binding control, amplify a partial sequence of the firefly luciferase (FL) DNA by PCR from psiCHECK-2 plasmid, followed by in vitro transcription.
    NOTE: Primers for PCR are listed in Table 4: hluc(+)-T7-probe-F and hluc(+)-probe-R. Table 4. Sequences of template and primers for PCR amplification.
  3. For a 50 µl PCR reaction, mix 50 ng DNA (oligo or plasmid), 4 µl dNTPs (2.5 mM of each individual dNTP), 5 µl 10x reaction buffer, 1 µl 2.5 U/µl DNA polymerase, 2 µl 10 µM forward primer, 2 µl 10 µM reverse primer, and nuclease-free water.
    1. Run PCR amplification in a thermal cycler using the following program. STEP1: one cycle of 95 °C for 2 min; STEP2: 35 cycles of 95 °C for 30 sec, 55 °C for 30 sec and 72 °C for 30 sec (AR) or 60 sec (FL); STEP3: one cycle of 72 °C for 10 min.
  4. Synthesize biotinylated RNAs using an in vitro transcription kit following manufacturer's instructions11. In this experiment, use PCR products as templates for RNA synthesis. For a 20 µl in vitro transcription reaction, mix 200 ng PCR amplified DNA, 2 µl of each individual NTP, 1 µl 10mM biotin-CTP, 2 µl 10x reaction buffer, and 2 µl T7 RNA polymerase. Incubate the mixture at 37 °C for 4 hr.
  5. Following in vitro transcription, treat reaction mixture with 1 µl 2 U/µl DNase at 37 °C for 15 min to degrade template DNA. Finally, dilute the biotinylated RNA to a total volume of 60 µl for subsequent purification.
  6. Purify biotinylated RNAs to remove salts and unincorporated nucleotides by using purification columns following manufacturer's instructions12. Measure RNA concentration and store at -80 °C for subsequent pull-down assays.
  7. To ensure proper secondary structure for RNA of interest in RNA-protein interaction, heat 50 µl biotinylated RNA (50 pM) at 90 °C for 2 min, chill on ice for 2 min, then supply with 50 µl 2x RNA structure buffer (Table 3), and allow for the RNA folding at RT for 30 min13,14.

2. Preparation of RNA-conjugated Beads

NOTE: Use a magnetic stand for separation of the magnetic beads and supernatant.

  1. Resuspend the streptavidin-coated magnetic beads in the original vial by brief vortexing following manufacturer's instructions. Transfer 150 µl resuspended beads to a 1.5 ml tube. Place the tube on magnet for 1 min. Discard supernatant. Keep bead pellet.
    NOTE: In RNA pull-down assays, when aliquoting resuspended beads from original vial, use 50 µl beads for an assay followed by western blotting, and 200 µl beads for an assay followed by MS.
  2. Wash beads once by re-suspending bead pellet with 1 ml of the manufacturer's recommended 1x W&B (binding and washing) buffer (Table 3), followed by rotating the tube for 5 min at room temperature in a rotator. Discard supernatant. Keep bead pellet.
  3. To inactivate RNase on beads, wash beads twice, each time by re-suspending bead pellet with 400 µl buffer A. Buffer A is an alkaline solution containing 0.1 M NaOH and 0.05 M NaCl (Table 3). Rotate the tube for 2 min at room temperature in a rotator. Discard supernatant. Keep bead pellet.
  4. To remove NaOH from beads, wash beads twice, each time by re-suspending bead pellet with 400 µl buffer B (Table 3), followed by rotating the tube for 2 min at room temperature in a rotator. Discard supernatant. Keep bead pellet.
  5. Resuspend bead pellet with 300 µl 2x W&B buffer, split beads equally and transfer into three 1.5 ml tubes (100 µl beads per tube). Supply the bead-containing tubes with 100 µl RNase free water, 100 µl biotinylated FL RNA and 100 µl biotinylated AR 3'UTR RNA, respectively.
  6. Incubate each bead mixture for 1 hr at room temperature with rotation. Place tubes on magnet for 1 min. Discard all supernatant. Keep bead pellets.
  7. Wash beads twice, each time by re-suspending each bead pellet with 400 µl 1x W&B buffer, followed by rotating tubes for 5 min at room temperature in a rotator.
  8. Place tubes on magnet for 1 min. Discard all supernatant. Resuspend each bead pellet with 50 µl nuclear isolation buffer (Table 3).

3. Preadipocyte Isolation and Adipogenesis Induction

  1. As described in previous publications5, dissect preadipocytes from the interscapular brown fat pad (C57BL6 wild type mice, 3 weeks old).
  2. Grow and in vitro differentiate the preadipocytes5. Cells are ready for downstream application 4-5 days after initiation of differentiation.

4. Preparation of Cellular Lysate from Primary Adipocytes

NOTE: Ensure all procedures of cell lysate preparation are made on ice, and all buffers are chilled on ice. Pre-chill dounce glass homogenizers on ice.

  1. Grow and differentiate preadipocytes in 15 cm dishes5 (see section 3.2). Each dish provides adequate cells for one RNA pull-down assay. On day 4 or day 5 of differentiation, discard cell culture medium, and wash cells once with 1x PBS.
  2. To harvest cells, add 10-15 ml 1x PBS to cells, scrape to collect cells in a 50 ml tube, and pellet cells by centrifugation at 200 x g for 5 min at RT. Discard supernatant by using 1 ml pipette.
  3. Resuspend cell pellet in 2 ml hypotonic buffer (Table 3), and incubate cells on ice for 15 min. Transfer cells to a 15 ml dounce glass homogenizer, and shear cells mechanically on ice with 20 strokes.
  4. Pellet cell nuclei by centrifugation at 3,300 x g for 15 min at 4 °C. Keep nuclei pellet on ice for further use (see section 4.6). Transfer supernatant to 1.5 ml tubes, add 3M KCl to supernatant to obtain a final concentration of 150 mM, and spin at 20,000 x g for 15 min at 4 °C.
  5. Following centrifugation, carefully remove lipidlayeron the top by using 1 ml pipette, and collect supernatant as the cytoplasmic cellular lysate.
  6. Resuspend nuclei pellet (see section 4.4) in 1 ml nuclear isolation buffer. Transfer nuclei to a 15 ml dounce glass homogenizer using 1 ml pipette, and shear nuclei mechanically on ice with 100 strokes. Pellet nuclear debris by centrifugation at 20,000 x g for 15 min at 4 °C, and collect supernatant as the nuclear cellular lysate.
  7. Either combine the nuclear and cytoplasmic cellular lysates, or use each fraction separately, for downstream pull-down application. In this demo experiment, these two fractions of cell lysate were combined at a volume ratio of 1:1.
  8. Add RNase inhibitor to this unfractionated cell lysate to obtain a final concentration of 0.5 U/µl. Set aside 100 µl of cell lysate as input control for western blotting15.

5. Binding and Elution of RBP

  1. Split cell lysate into three equal aliquots (1ml cell lysate in a 1.5 ml tube), and incubate with blank, FL RNA-conjugated and AR 3'UTR RNA-conjugated beads (see section 2.8), respectively, for 3 hr at 4 °C with rotation.
  2. Place tubes on magnet for 1 min. Collect supernatant using a 1 ml pipette, followed by RNA isolation from supernatant to confirm RNA integrality. Isolate RNA by using an acid guanidinium thiocyanate-phenol solution following manufacturer's instructions (Table 2). Assess the RNA intactness by analyzing 28S and 18S subunits of ribosomal RNA. Keep bead pellets on ice.
  3. Wash the magnetic beads six times, each time by resuspending each bead pellet with 1 ml nuclear isolation buffer containing 40 U RNase inhibitor and 0.25% IGEPAL, followed by rotating tubes for 2 min at room temperature in a rotator. Use a magnetic stand for separation of the magnetic beads and supernatant. Discard all supernatant. Keep bead pellets on ice.
  4. Use following steps to elute RNA-protein complexes from beads for western blotting. First, resuspend each bead pellet in 75 µl nuclear isolation buffer; then, add 25 µl 4x western blot loading buffer (containing SDS) to obtain a total volume of 100 µl. Finally, boil beads in this 100 µl solution at 95 °C for 5 min.
    NOTE: Use following steps to elute RNA-protein complexes from beads for MS. STEP1: resuspend each bead pellet in 100 µl elution buffer (Table 3); STEP2: incubate bead samples for 2-3 hr at room temperature with rotation; STEP3: centrifuge and collect protein-containing supernatant; STEP4: concentrate protein solutions to 20-30 µl before submission for MS.
  5. Centrifuge each 100 µl of bead sample at 12,000 x g for 30 sec at 4 °C, and collect supernatant. Aliquot 15 µl supernatant for western blot analysis (see section 6.1 and 6.2). Probe the resulting membrane with the diluted HuR mouse monoclonal antibody (1:1,000 dilution), overnight.

6. Western Blotting for Verification of RBP

  1. Separate RBPs by SDS-PAGE using standard techniques.
  2. Conduct western blotting using standard techniques by probing for the RBPs associated with the RNA of interest.
    NOTE: In this demo experiment, HuR mouse monoclonal antibody was used for the immunodetection of HuR protein.
  3. Incubate the resulting membrane with the diluted HuR antibody (1:1,000 dilution) in 5% w/v nonfat dry milk, 1x TBS, 0.1% Tween-20 at 4 °C with gentle shaking, overnight. Wash membrane three times with 1x TBST. Incubate membrane with the secondary antibody (goat anti-mouse IgG-HRP) at room temperature for 1 hr. Wash membrane. Develop and record signal.

Results

In this demo experiment, an AR RNA fragment was used as the bait to capture its binding protein HuR. Both a FL RNA bait that is non-relevant to HuR protein, and an aliquot of unconjugated blank streptavidin beads served as negative controls. RNA-protein interactions can occur either in nucleus or cytoplasm, and this pull-down protocol can be applied to either total or fractionated (nuclear or cytoplasmic) cell lysates. Analysis of proteins by western blotting shows that the sample of 15 &...

Discussion

lncRNAs and RBPs have vital roles in health and disease, however the molecular mechanisms of these molecules are poorly understood. Identification of proteins that interact with lncRNA molecules is a key step towards elucidating the regulatory mechanisms. Enrichment of RBPs by the RNA pull-down assay system is based on in-solution capture of interacting complex so that proteins from a cell lysate can be selectively extracted using biotinylated RNA baits bound to streptavidin magnetic beads. Several other methods such as ...

Disclosures

No conflicts of interest declared.

Acknowledgements

This work was funded by Singapore NRF fellowship (NRF-2011NRF-NRFF001-025) as well as CBRG (NMRC/CBRG/0070/2014).

Materials

NameCompanyCatalog NumberComments
Major materials used in this study.
MEGAscript kit Ambion
Biotin-14-CTP Invitrogen
NucAway spin columns Ambion
Dynabeads M-280 Streptavidin Invitrogen
HuR (3A2) mouse monoclonal antibody (sc-5261) Santa Cruz Biotechnology
Goat anti-mouse IgG-HRP(sc-2005) Santa Cruz Biotechnology
Hypure Molecular Biology Grade Water (nuclease-free) HyClone
Phosphate Buffer Saline (1×PBS) HyClone
RNase inhibitor Bioline
Protease inhibitor Sigma
Pfu Turbo DNA polymerase Agilent Technologies
TRIsure Bioline
NameCompanyCatalog NumberComments
Major equipment used in this study.
Sorvall Legend Micro 21R centrifuge Thermo Scientific
Sorvall Legend X1R centrifuge Thermo Scientific
Bio-Rad T100 thermal cycler Bio-Rad
Nanodrop 2000 Thermo Scientific
BOECO rotator Multi Bio RS-24 BOECO,Germany
Protein gel electrophoresis and blotting apparatus Bio-Rad
DynaMag-2 magnet Life Technologies

References

  1. Huot, M. &. #. 2. 0. 1. ;., et al. The Sam68 STAR RNA-binding protein regulates mTOR alternative splicing during adipogenesis. Mol Cell. 46 (2), 187-199 (2012).
  2. Sun, L., et al. Long noncoding RNAs regulate adipogenesis. Proc Natl Acad Sci U S A. 110 (9), 3387-3392 (2013).
  3. Engreitz, J. M., et al. The Xist lncRNA exploits three-dimensional genome architecture to spread across the X-chromosome. Science. 341 (6147), 1237973 (2013).
  4. Zhao, X. Y., Li, S., Wang, G. X., Yu, Q., Lin, J. D. A long noncoding RNA transcriptional regulatory circuit drives thermogenic adipocyte differentiation. Mol Cell. 55, 372-382 (2014).
  5. Alvarez-Dominguez, J. R., et al. De novo reconstruction of adipose tissue transcriptomes reveals long non-coding RNA regulators of brown adipocyte development. Cell Metab. 21, 764-776 (2015).
  6. Adams, D. J., Beveridge, D. J., van der Weyden, L., Mangs, H., Leedman, P. J., Morris, B. J. HADHB, HuR, and CP1 bind to the distal 3-untranslated region of human renin mRNA and differentially modulate renin expression. J Biol Chem. 278 (45), 44894-44903 (2003).
  7. Yeap, B. B., et al. Novel binding of HuR and poly(C)-binding protein to a conserved UC-rich motif within the 3´ untranslated region of the androgen receptor messenger RNA. J Biol Chem. 277, 27183-27192 (2002).
  8. König, J., Zarnack, K., Luscombe, N. M., Ule, J. Protein-RNA interactions: new genomic technologies and perspectives. Nat Rev Genet. 13, 77-83 (2012).
  9. Ferrè, F., Colantoni, A., Helmer-Citterich, M. Revealing protein-lncRNA interaction. Briefings in Bioinformatics. , 1-11 (2015).
  10. McHugh, C. A., Russell, P., Guttman, M. Methods for comprehensive experimental identification of RNA-protein interactions. Genome Biol. 15 (1), 203 (2014).
  11. Lee, Y. S., et al. AU-rich element-binding protein negatively regulates CCAAT enhancer binding protein mRNA stability during long term synaptic plasticity in Aplysia. Proc Natl Acad Sci U S A. 109 (38), 15520-15525 (2012).
  12. Hermann, M., Cermak, T., Voytas, D. F., Pelczar, P. Mouse genome engineering using designer nucleases. J Vis Exp. (86), (2014).
  13. Tsai, M. C., et al. Long Noncoding RNA as Modular Scaffold of Histone Modification Complexes. Science. 329 (5992), 689-693 (2010).
  14. Wan, Y., et al. Landscape and variation of RNA secondary structure across the human transcriptome. Nature. 505, 706-709 (2014).
  15. Li, H., et al. Identification of mRNA binding proteins that regulate the stability of LDL receptor mRNA through AU rich elements. J Lipid Res. 50 (5), 820-831 (2009).
  16. McHugh, C. A., et al. The Xist lncRNA interacts directly with SHARP to silence transcription through HDAC3. Nature. 521 (7551), 232-236 (2015).
  17. Chu, C., et al. Systematic Discovery of Xist RNA Binding Proteins. Cell. 161 (2), 404-416 (2015).
  18. Chu, C., Spitale, R. C., Chang, H. Y. Technologies to probe functions and mechanisms of long noncoding RNAs. Nat Struct Mol Biol. 22 (1), 29-35 (2015).
  19. Zhao, J., et al. Genome-wide identification of Polycomb-associated RNAs by RIP-seq. Mol Cell. 40 (6), 939-953 (2010).

Erratum


Formal Correction: Erratum: Detection of RNA-binding Proteins by In Vitro RNA Pull-down in Adipocyte Culture
Posted by JoVE Editors on 8/20/2016. Citeable Link.

A correction to the author list was made to: Detection of RNA-binding Proteins by In Vitro RNA Pull-down in Adipocyte Culture.

The author list has been updated from:

Qianfan Bai1*, Zhiqiang Bai1*, Lei Sun1,2

1Cardiovascular and Metabolic Disorders Program, Duke-NUS Medical School

2Institute of Molecular and Cell Biology, Singapore

*These authors contributed equally

to:

Qianfan Bai1*, Zhiqiang Bai1*, Shaohai Xu3, Lei Sun1,2

1Cardiovascular and Metabolic Disorders Program, Duke-NUS Medical School

2Institute of Molecular and Cell Biology, Singapore

3Division of Bioengineering, School of Chemical & Biomedical Engineering, Nanyang Technological University

*These authors contributed equally

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