The differentiation of ESC coincides with cell-type specific changes in the structure and composition of chromatin. The detection of those changes provides valuable insights into the mechanisms that define stemcellness and cell differentiation. Chromatin immunoprecipitation (ChIP) represents a valuable method to dissect the molecular mechanisms underlying stem cell differentiation.
The functional and structural complexity of the myriad of cells in metazoan organisms arises from a small number of stem cells. Stem cells are characterized by two fundamental properties: self-renewal and multipotency that allows a stem cell to differentiate into virtually any cell type 1. The progression stem cell to differentiated cell is characterized by loss of multipotency, structural and morphological changes and the hierarchic activity of transcription factors and signaling molecules, whose activities establish and maintain cell-type specific gene expression patterns. At the molecular level, cell differentiation involves dynamic changes of the structure and composition of chromatin and the detection of those dynamic changes can provide valuable insights into the functional features of stem cells and the cell differentiation process 2,3. Chromatin is a highly compacted DNA-protein complex that forms when cells package chromosomal DNA with proteins, mainly histones 4. Stemcellness and cell differentiation has been correlated with the presence of specific arrays of regulatory proteins such as epigenetic factors, histone variants, and transcription factors 2,3,5.
Chromatin immunoprecipitation (ChIP) provides a valuable method to monitor the presence of RNA, proteins, and protein modifications in chromatin 6,7. The comparison of chromatin from different cell types can elucidate dynamic changes in protein-chromatin associations that occur during cell differentiation.
Chromatin immunoprecipitation involves the purification of in vivo cross-linked chromatin. The isolated chromatin is reduced to smaller fragments by enzymatic digestion or mechanical force. Chromatin fragments are precipitated using specific antibodies to target proteins or protein and DNA modifications. The precipitated DNA or RNA is purified and used as a template for PCR or DNA microarray based assays. Prerequisites for a successful ChIP are high quality antibodies to the desired antigen and the availability of chromatin from control cells that do not express the target molecule. ChIP can correlate the presence of proteins, protein and RNA modifications, and RNA with specific target DNA, and depending on the choice of outread tool, detects the association of target molecules at specific target genes or in the context of an entire genome. The comparison of the distribution of proteins in the chromatin of differentiating cells can elucidate the dynamic changes of chromatin composition that coincide with the progression of cells along a cell lineage.
Thawing ES cells (Not Featured in Video)
ES cells are frozen in medium containing 10% DMSO. Since DMSO can induce the differentiation of ES cells, it can be possible to thaw the cells late in the day and so to change the medium the following morning to minimize the effects of residual DMSO.
Passage and expansion of ES cell cultures
ES cells are routinely passaged every 2/3 days, and the medium is changed on alternate days. Thus, ES cells require daily attention. In our experience, feeder-independent ES cells grow rapidly and quickly acidify the medium, turning it yellow. Allowing the cells to acidify the medium (by not changing the media every day or by passaging the cells at too low a dilution) will cause the cells to undergo crisis, triggering excess differentiation and cell death, after which their totipotency cannot be guaranteed. Plating cells at too low a density, insufficient dispersion of cells during passage, or uneven plating can cause similar problems, as the cells will form large clumps before reaching confluence and the cells within these clumps will differentiate or die. Germline transmission is a significantly reduced in cells that have been mistreated, even when they appear healthy at the time of injection.
Freezing ES cells
ChIP-on-chip PROCEDURE
Immunoprecipitation
Preparing magnetic beads (Steps are all performed at 4°C)
Cell sonication
Chromatin immunoprecipitation
Wash
Elution
Crosslink reversal
Purification DNA
NB: The following steps including library preparation and amplification use a modified GenomePLex WGA kit with 10X Amp Mix from Sigma without dNTPs:
Library preparation
Available in the GenomePLex WGA kit with 10X Amp Mix from Sigma
Amplification
Available in the GenomePLex WGA kit with 10X Amp Mix from Sigma
Fragment amplified targets
Component Volume/Amount in 1 Rxn |
Double-Stranded DNA 7.5 µg |
10X cDNA Fragmentation 4.8 µl |
UDG, 10 U/µl 1.5 µl |
APE 1, 100 U/µl 2.25 µl |
Nuclease-free water up to 48 µl |
Component Volume/Amount in 1 Rxn |
Double-Stranded DNA 9 µg |
10X cDNA Fragmentation 4.8 µl |
UDG, 10 U/µl 1.5 µl |
APE 1, 100 U/µl 2.25 µl |
Nuclease-free water up to 48 |
Label fragmented double-stranded DNA
Component Volume/Amount in 1 Rxn |
5X TdT Buffer 12 µl |
TdT 2 µl |
DNA Labelling Reagent, 5 mM 1 µl |
Total volume 15 µl |
Gel-shift analysis
Array hybridization & Array washing
Performed by the Genomic Center of the University of California Riverside.
Array analysis
Performed by computational analysis.
BUFFER COMPOSITIONS:
Block Solution: PBS + 0.5% Bovine Serum Albumin (BSA).
Lysis Buffer: 50 mM HEPES-KOH, pH 7.5
140 mM NaCl
1 mM EDTA
1% Triton X-100
0.1% SDS
1mM PMSF
Final pH 7.5
IP1: Lysis Buffer + 500 mM NaCl
IP2: 10 mM Tris-HCl
250 mM LiCl
1 mM EDTA
0.5% NP-40
0.5% Sodium Dioxycholat
Final pH 8.0
TE: 10 mM Tris, pH 7.4
1 mM EDTA
Final pH 8.0
Elution Buffer: TE Buffer + 1% SDS.
Chromatin immunoprecipitation (ChIP) offers a valuable technique for the dissection of chromatin-based processes during cellular differentiation. Prerequisites for the success of this method are good antibodies and the availability of chromatin from control cells or tissues that lack the antigen of interest. By combining ChIP with DNA microarray technology, vast amounts of information can be obtained. The validation of ChIP results depends on the availability of suitable test systems that can link the dynamic association of proteins, protein modifications and/or RNA with the execution of biological processes during cell development.
The presented work is supported by a grant (RS1-00477-1) from the California Institute for Regenerative Medicine (CIRM) to F.S.
Material Name | Tipo | Company | Catalogue Number | Comment |
---|---|---|---|---|
Poteinase-K | Reagent | Roche | #EO0491 | |
RNase-A | Reagent | Fermentas | #EN0531 | |
formaldehyde 37% | Reagent | EMD | FX040-13 | |
Chloroform | Reagent | EMD | 3150 | |
Ethanol | Reagent | Goldshield | ||
phenol:chloroform:isoamyl alcohol | Reagent | Invitrogen | 15593-031 | |
SA, fraction V | Reagent | EMD | 2930 | |
Dubecco’s Phosphate Buffered Saline | Reagent | Gibco | 14190 | |
HEPES | Reagent | EMD | 5330 | |
Sodium Chloride | Reagent | Fisher Scientific | S271-10 | |
EDTA | Reagent | EMD | 4050 | |
Triton X-100 | Reagent | EMD | 9410 | |
Sodium Dodecyl Sulfate | Reagent | J.T Baker | 4095-02 | |
Lithium chloride | Reagent | EMD | 5910 | |
Tris-HCl | Reagent | EMD | 9230 | |
NP-40 | Reagent | Calbiochem | 492015 | |
Deoxycholic acid, sodium salt | Reagent | Fisher Scientific | BP349-100 | |
Ammonium acetate | Reagent | Applichem | 631-61-8 | |
Glycine | Reagent | EMD | 4840 | |
Glycine | Reagent | EMD | 4840 | |
dynalbeads, protein A | Reagent | Invitrogen | 100.02D | |
dynalbeads, protein G | Reagent | Invitrogen | 100.04D | |
1.5ml Low Retention Microtubes, Xtreme | Altro | Phenix Research Products | MAX-815S | |
Phase Lock Gel Light, 2.0 ml | Reagent | Eppendorf | 955154037 |