| Research Article |
Open Access |
|
| A Chloroform-Assisted Protein Isolation Method Followed by
Capillary NanoLC-MS Identify Estrogen-Regulated Proteins
from MCF7 Cells |
| Adaikkalam Vellaichamy1,a, Chin-Yo Lin1, Thin Thin Aye1, Govindarajan R. Kunde1, Alexey I. Nesvizhskii2, Edison T. Liu1, Siu Kwan Sze1,b* |
| 1Genome Institute of Singapore, 60 Biopolis Street, Singapore, 138672 |
| 2Department of Pathology, University of Michigan, MI 48109, USA |
| Present address: |
| aInstitute for Genomic Biology, UIUC, Urbana, IL 61801, USA |
| bSchool of Biological Sciences, Nanyang Technological University, Singapore |
| *Corresponding author: |
Siu Kwan Sze, PhD
Assistant Professor
School of
Biological Sciences
Nanyang Technological University
Singapore 637551
Tel: +65-6316-2852
Fax: +65-6791-3856
E-mail: sksze@ntu.edu.sg |
|
| |
| Received June 12, 2010; Accepted June 29, 2010; Published June 29, 2010 |
| |
| Citation: Vellaichamy A, Lin CY, Aye TT, Kunde GR, Nesvizhskii AI, et al. (2010) A Chloroform-Assisted Protein Isolation Method Followed by Capillary NanoLC-MS Identify Estrogen-Regulated Proteins from MCF7 Cells. J Proteomics Bioinform 3:
212-220. doi:10.4172/jpb.1000142 |
| |
| Copyright: © 2010 Vellaichamy A, et al. This is an open-access article distributed
under the terms of the Creative Commons Attribution License, which permits
unrestricted use, distribution, and reproduction in any medium, provided the
original author and source are credited. |
| |
| Abstract |
| Most commonly reported non-commercial protein isolation methods require the use of detergents and/or chaotropes
for better yield, and they all need additional Purification or clean-up steps for subsequent mass spectrometry analysis.
Moreover, there is no simple procedure available for obtaining both soluble and membrane proteins from the same
sample. Here we describe a simple and detergent-free chloroform-assisted protein isolation (ChlAPI) method for
mammalian cells and tissues, and demonstrated its suitability to mass spectrometry based proteome analysis. In this
single-step method, cultured cells or grounded tissue were mixed in 10% chloroform in ammonium bicarbonate buffer
to separate whole cell proteome into biphasic layers. Total number of aqueous phase proteins, as assessed by 2DE,
was comparable to the proteins isolated with commonly used detergent containing buffer. Shotgun proteomics analysis
of the aqueous and organic phase proteome fractions of MCF7 cells by LC-MS/MS resulted in Identification of a total
of 752 and 593 proteins, respectively from IPI human protein database. Among the total of 1134 distinct and nonredundant
proteins, 29.5% were predicted to be membrane localized; 78% of them wereidentified from organic phase
fraction. Application of this new procedure to estrogen-treated MCF cells lead to the Identification of previously known as
well as unknown estrogen-responsive gene products. These fi ndings suggest that the simple and inexpensive ChlAPI
method described here is suitable for protein isolation from mammalian samples, and is readily compatible with 2DE
and LC-MS/MS analyses. |
| |
| Keywords |
| Proteomics; Chloroform; Protein isolation; MCF-7 cells;
Estrogen; 2DE; nanoLCMS/MS |
| |
| Abbreviations |
| E2: 17β-estradiol; MS: Mass spectrometry; MS/
MS: Tandem Mass Spectrometry; IPI: International Protein Index;
ACN: Acetonitrile; FA: Formic acid; TFA: Trifluoroacetic Acid; DMSO:
Dimethyl sulphoxide; PBS: Phosphate Buffered Saline |
| |
| Introduction |
| Several proteomic strategies have been developed to identify
constituent proteins from various organisms and cell types. These
approaches rely on different separation methods coupled to mass
spectrometric techniques such as matrix assisted laser-desorption/
ionization mass spectrometry (MALDI-MS) and electrospray ionization
mass spectrometry (ESI-MS). Global bottom-up proteomic profiling
approaches, such as the multidimensional protein identification
technology (MudPIT) (Wolters et al., 2001), isotope coded affinity
tagging (Smolka et al., 2001), and isobaric tag for relative and absolute
quantitation (iTRAQ) (Ross et al., 2004) mass spectrometry are now
the widely used procedures that can potentially identify and quantify
both high and low abundant proteins in complex biological mixtures.
Recently, the intact protein based top-down proteomics is also
gaining momentum for high throughput on-line analysis of complex
samples (Parks et al., 2007). However, one of the key factors to the
success of these mass spectrometry based analyses is the availability
of efficient as well as simple sample preparation procedures that
minimize ion suppression by impurities. |
Detergents and chaotropes are commonly used in protein isolation
protocols as solubilizing and stabilizing agents. Non-ionic and ionic
detergents such as NP-40, Triton X100, and SDS are compatible with
conventional biochemical methods, but they interfere with both
chromatographic separation and mass spectrometric ionization
(Loo et al., 1994) resulting in suppression and obscuring of peptide
signals as well as in the formation of adducts. Efforts to remove
these surfactants require multiple purification steps which lead to
significant sample losses (Barnidge et al., 1999; Blonder et al., 2002). |
Organic solvents such as methanol and chloroform have been used
in the isolation of proteins from cells or tissues of diverse species from
virus to human (Abramsky and London, 1975; Fillingame, 1976; Tsai
et al., 1985). These studies originally focused on isolating selected
lipoproteins, hydrophobic proteins, or removing lipid contaminants
from protein preparations. Use of these solvents have been extended
to proteomic studies of hydrophobic and membrane proteins. For
example, membrane proteins from E. coli were isolated using a
chloroform/methanol mixture, followed by solubilizing in urea and
detergents, and subjected to 2-dimensional electrophoresis (Molloy
et al., 1999). Similarly, detergent-solubilized bacteriorhodopsin
was extracted into chloroform/methanol and analyzed by LC-MS
(Barnidge et al., 1999). Ferro and colleagues (Ferro et al., 2000)
used chloroform/methanol mixture to selectively isolate membrane
proteins from chloroplasts, while Goshe and co-workers applied methanol/ammonium bicarbonate to solubilize bacterial membrane
proteins prior to MS analysis (Goshe et al., 2003). In another example,
over 110 mitochondrial membranes proteins wereidentified through
chloroform/methanol extraction, and alkaline/saline treatments
followed by LC-MS/MS (Brugiere et al., 2004). A multi-step, chloroform
and methanol/water protocol was used for delipidation of proteins
in order to enrich the identification of membrane proteins by mass
spectrometry (Mirza et al., 2007). Zhang et al have recently reported
the isolation of membrane proteins from red blood cells by the use
of methanol and TFE for shotgun analysis (Zhang et al., 2007b). Thus,
these alternate solubilization techniques have been used either for
solubilize proteins or to enrich membrane proteins. |
Here we describe the use of chloroform to disrupt mammalian
cells and create an organic/aqueous phase partitioning, leading to
the isolation of both aqueous soluble and hydrophobic proteins.
We applied this single-step chloroform-assisted proteome isolation
(ChlAPI) method to isolate proteomes of human breast cancer cells
and mouse liver tissue. Two dimensional gelelectrophoresis (2DE)
was used to assess the efficiency of protein extraction in comparison
with detergent aided protein extraction, and protein isolation by
French Pressure Cell Press. LC-MS/MS analysis of breast cancer (MCF-
7) cell proteome isolated with and without estrogen (E2) treatment
revealed known as well as previously unknown estrogen-regulated
proteins. |
| |
| Materials and Methods |
| |
| Chemicals and column materials |
| Strong cation exchange (SCX) column (ThermoHypersil-Keystone,
Biobasic; dimension: 100 x 0.32 mm; particle size: 5 μ) was purchased
from Thermo Fisher Scientific (San Jose, CA, USA) and the C18 particles
(particle size: 5 μ) were obtained from Michrom Bioresources, Inc.
(Auburn, CA, USA). Fused silica nanospray emitter tips (Picofrit: 75 μm
i.d.; 360 μm o.d.) were purchased from New Objective Inc. (Woburn,
MA, USA). Sequencing grade trypsin was from Promega (Madison, WI,
USA). Trifluoroacetic acid and formic acid were purchased from sigma-
Aldrich (St. Louis, MO, USA). HPLC grade acetonitrile was purchased
from Burdick and Jackson (Muskegon, MI, USA), and high purity water
was from J. T. Baker (Mallinckrodt Baker, Inc., Phillipsburg, NJ, USA). |
| |
| Cell culture and harvest |
| Human breast cancer cell line MCF-7 (ATCC No. HTB-22) was
maintained in DMEM/F12 medium (Invitrogen, Carlsbad, CA, USA)
containing 10% standard fetal bovine serum (Hyclone, Logan, UT,
USA) at 37°C with 5% CO2. At 80% confluence, the above medium
was replaced with phenol red free DMEM/F12 medium containing
charcoal treated fetal calf serum (Hyclone) after washing the cells
with sterile PBS. After 40 hours, the cells were treated with 100 nM
of 17β-estradiol (Sigma-Aldrich) in DMSO for 45 minutes. Control
cells were treated only with DMSO. Cells were washed with PBS and
harvested after 5 min incubation at room temperature with 0.025%
trypsin, 0.5% ETDA. The cells were centrifuged at 2400 rpm at 4°C,
and the cell pellet was washed with PBS before protein isolation. |
| |
| Protein isolation |
| Unless otherwise stated, the protein isolation was performed
either on ice or at 4°C. Cells obtained from five 150 x 25 mm cell
culture plates (~1 X 108 cells) were resuspended in 6 ml of ammonium
bicarbonate sample buffer (50 mM ammonium bicarbonate, 10 mM
ammonium chloride, 2 mM PMSF, pH 8.0) in a 15 ml polypropylene
tube. Chloroform was added to achieve 10% (v/v) final concentration
of the cell suspension and incubated in a rotary shaker for 10
minutes. Subsequent centrifugation at 5,000 rpm for 15 minutes
resulted in biphasic separation into a top aqueous and bottom
organic layers, and the two fractions were collected separately. In
order to obtain a clear phase separation, one ml of chloroform was
added to the sample before centrifugation. The aqueous fraction was
further centrifuged at 10,000 rpm for 10 minutes to remove debris,
and PMSF was added freshly. Chloroform was evaporated completely
from the organic fraction using a speedvac system (SAVANT
instruments, Inc., Holbrook, NY, USA), and the sample was subjected
to digestion. Mouse liver tissue of about 1g wet weight was ground
in liquid nitrogen using Pestle and Mortar, and sample buffer was
added to obtain a cell suspension. Proteins were extracted using 10%
chloroform as described above. |
Cells dissolved in ammonium bicarbonate sample buffer was
poured into the sample holder of FRENCH pressure cell press
(Thermo Spectronic ITS 40K; Thermo IEC, MA, USA) and were
broken by applying a pressure gauge level of 1000 psi as per the
manufacturer’s instructions. The lysate was centrifuged, and soluble
proteins were collected for 2DE. Detergent aided lysis was carried
out by resuspending the cells in RIPA buffer (50mM Tris-HCl buffer
(pH 8.0) containing 150mM NaCl, 10 mM EDTA, 0.2% Triton X100,
0.5% NP40 and 2mM PMSF), and subsequent sonication of the crude
lysate by using an ultrasonic processor (Cole-Parmer Instrument
Company, Illinois, USA) with 20% amplitude, 45 seconds pulse and
cooling on ice for 60 seconds. Lysate was centrifuged at 10,000 rpm
for 10 minutes and the aqueous phase proteins were obtained for
2DE. Protein estimation of various samples were done using Bradford
assay (Bio-Rad Laboratories, Hercules, CA, USA). |
| |
| Two-dimensional electrophoresis and protein spot analysis |
| The quality of the proteome isolation with the above three
methods were assessed by 2DE, and three replicates were performed
for each method. For 2DE proteome separation, first dimension
isoelectric focusing (IEF) was done as described earlier (Gorg et al.,
2000). Briefly, 18 cm Immobiline™ Dry strips (Amersham Biosciences
Corporation, Piscataway, NJ, USA) with nonlinear pH gradients from
3-10 were used. One hundred microgram of protein was mixed in
sample buffer (6M urea, 2M thiourea, 4% (w/v) CHAPS, 10mM DTT,
trace amount of Bromophenol blue), and 7.5 μl of IPG Buffer (pH:
3-10), and the total volume was made up to 350 μl. Strips were loaded
onto Ettan™ IPGphor™ horizontal electrophoresis system (Amersham
Biosciences Corporation) and rehydrated at 20°C for 10 hrs. The strips
were focused for overnight with voltage gradients starting from 10 V
to 8,000 V in stepwise and until reaching 50,000 V hrs. The focused
strips were equilibrated for 30 minutes in equilibration solution (30%
glycerol, 2% SDS, 2% DTT, 50 mM Tris-HCl pH 8.8 and 0.005% w/v
bromophenol blue). Second dimension separation was performed on
a 12% SDS-polyacrylamide gel using PROTEAN II XL Cell apparatus
(Bio-Rad Laboratories). Electrophoresis was carried out at 300 V for
1 hr and then at 600 V until the dye front reached the end of the gel.
Silver staining was performed using a commercial silver staining kit
as per the manufacturer’s instructions (SilvestQuest™ Silver staining
kit, Invitrogen Corporation). The stained gels were scanned using
Image scanner (Amersham pharmacia) and the protein spots were
counted using Compugen Z3 desktop version 3.0 software. Manual
verification of protein spots was performed after making a high
quality print of the image and counting the spots after dividing the
image into multiple sectors. |
| |
| Digestion of proteins |
| Soluble proteins in sample buffer was diluted to a concentration of 2 mg/ml and mixed with an equal volume of 100 mM ammonium
bicarbonate, pH 8.0. Proteins were reduced by 10mM DTT and
alkylated with 50mM iodoacetamide before adding trypsin at a
trypsin: protein ratio of 1:50 (w/w), and incubated at 37°C for 16 hrs.
Second aliquot of trypsin was added and digestion continued for
another 4 hrs, and the enzyme reaction was stopped by acidifying
the solution with 0.5% TFA. The organic phase proteins were digested
separately following the protocol described by Washburn et al. (2001).
Briefly, the dried sample pellet was acidified by formic acid and
cleaved by cyanogen bromide. After adjusting the solution pH with
solid ammonium bicarbonate and water, the sample was digested by
trypsin as described above. Trypsin digested peptides were desalted
by a peptide trap of 200 ?g capacity (Michrom Bioresources, Inc.,
Auburn, CA, USA). Peptide trap was conditioned with buffer B (70%
ACN, 0.1% FA in HPLC water), and equilibrated with buffer A (0.1% FA,
3% ACN in HPLC water) prior to sample loading using a syringe pump.
After washing with 1.2 ml of buffer A, peptides were eluted using
buffer B. Eluted peptides were dried using speedvac and dissolved in
buffer A for LC-MS/MS analysis. |
| |
| Liquid chromatography and mass spectrometry |
| A Surveyor LC system (Thermo Fisher Scientific, San Jose, CA,
USA) with an in-house built solvent splitter was coupled to a LCQ™
Deca XP plus mass spectrometer (Thermo Fisher Scientific) for LC-MS/
MS analysis. Digested peptide samples was separated online by an
SCX column and then followed by a C-18 reversed phase (RP) capillary
column. The RP column with nanospray emitter was packed with 5
?m C18 particles under 400 psi of helium using a pressure bomb.
For each experiment (estrogen treated and untreated), peptides
purified from 200 μg digested proteins were injected onto the SCX
column using an auto sampler, and fractionated using 9 salt steps of
increasing concentration of (0, 10, 20, 30, 50, 70, 90, 120, and 400
mM) NH4Cl solutions. Peptides from each salt elution were trapped in
an online peptide trap and desalted by 3% ACN and 0.1% FA solution
(solvent A). The online desalted peptides was eluted to and separated
by the C18 analytical column using a 160 min. chromatographic
gradient, and 200 nL/min flow rate. The gradient was ramped from
5% B (97% CAN in H2O, 0.1% FA) at 5 min. to 40% B in 130 min., then to
80% B in 145 min. After an additional 5 min. in 80% B for it is ramped
back to 5% B. Eluted peptides were ionized by a nanospray emitter
that is arranged in line with the inlet of the LCQ. The transfer capillary
temperature and spray voltage of the emitter tip were set at 180ºC
and 1.6 kV, respectively. Normalized collision energy was fixed at
35% for MS/MS. For the detection of peptides, one full (MS) scan (m/z
range of 400-2000) was followed by fragmentation (MS2) scan on five
most abundant ions. |
| |
| Informatics and data analysis |
| Raw data were obtained from mass spectrometer for aqueous
and organic phase protein fractions using Xcalibur (Thermo Fisher
Scientific) software. The Raw files were converted into mzXML
files for SEQUEST (Eng et al., 1994) search against the IPI Human
database version 3.16 (62322 entries). Search parameters used were:
precursor mass tolerance of 3 Da, peak extraction with average mass,
semi-tryptic search with two or fewer missed cleavages, and fixed
carbamidomethylation of cysteine residues. Cleavage at methionine
was added for the organic phase samples that have undergone
cyanogen bromide treatment. Peptide and protein assignments were
validated using PeptideProphet (Keller et al., 2002) and ProteinProphet
(Nesvizhskii et al., 2003) tools which are available as a part of the
Trans-Proteomic Pipeline (www.proteomecenter.org). List of protein
identifications was filtered using a 0.9 probability threshold, which
corresponds to less than 1% estimated false discovery rate (FDR).
The data sets acquired on control_aqueous, control_organic, E2_
aqueous, and E2_organic were analyzed separately. Protein groups
in each set with indistinguishable protein accession numbers were
collapsed into a single group. |
For comparative analysis, two data sets from control and E2
treatments were combined, and proteins belonging to common,
control-specific, and E2 treatment-specific were obtained using inhouse
software. This software analysis allowed removal of ambiguities
arising from protein isoforms and multiple accessions. The resulting
combined dataset was used for spectral count analysis (Vellaichamy
et al., 2009). Total number of MS2 spectra that were assigned to
peptides was calculated and the dataset was further normalized to
account for differences in the total number of peptidesidentified.
Subsequently, ratio of normalized spectrum counts was calculated for
proteinsidentified in both experiments, and then log-transformed.
Resulting distribution was fitted using a robust Gaussian distribution
fitting procedure with 10% outlier removal, and the mean and
standard deviation (SD) were determined. Subsequently for proteins
identified in common, two-SD threshold was applied to derive the
list of differentially expressed proteins. In addition, proteins were
designated as differentially expressed if they wereidentified only
in either the control (down-regulated) or E2-treated sample (upregulated)
with four or more spectra. |
Gene ontology (GO) searches for cellular localization of the
proteins using the gene identifiers were performed at the SOURCE
web-site (http://smd.stanford.edu/cgi-bin/source/sourceSearch).
Transmembrane domain analysis of the proteins was performed using
the TMHMM server 2.0 (http://www.cbs.dtu.dk/services/TMHMM/). |
| |
| Results and Discussion |
| |
| Proteome isolation by chloroform treatment |
| Suspension of MCF-7 cells in the aqueous ammonium
bicarbonate buffer containing chloroform resulted in the rupture
of cell membrane which was observed by microscopic examination.
Preliminary experiments were conducted by varying the amount of
chloroform and the incubation time on constant number (~1x 108)
of cells to optimize lysis conditions. A 10% chloroform mixture,
and 8-10 minutes of incubation time resulted in complete cell lysis.
Upon centrifugation, the lysate partitioned into a biphasic organic
and aqueous layers with soluble proteins in the aqueous layer,
and presumably the hydrophobic and membrane proteins in the
chloroform layer. The disintegration of cell membrane is considered
to be due to the dissolution of membrane lipids by chloroform during
the mixing process as the chloroform is known to act on hydrophobic
membrane lipids (Barnidge et al., 1999; Mirza et al., 2007). Herein
we denote this isolation protocol as ‘chloroform-assisted protein
isolation (ChlAPI)’ method. |
To check the quality of sample preparation and efficiency of
the isolation method, we used 100 ?g of the soluble proteins and
performed 2DE. Silver staining of the 2DE gel for MCF-7 cell proteins
obtained through ChlAPI method showed that proteins are distributed
within a wide range of pI (pH 3-10) and molecular weights (Figure
1A). There were a total of 1362 protein spots that were sharp and
distinct (Figure 1A). The appearance of these clearer 2DE gel spots
with ChlAPI isolated proteins were probably due to the removal of
lipids and hydrophobic impurities by chloroform (Mirza et al., 2007). |
| |
 |
Figure 1: Two-dimensional gel electrophoresis images of MCF-7 cell and mouse liver tissue proteomes isolated by different protein isolation methodologies. Aqueous
phase proteins isolated by using chloroform-assisted protein isolation (ChlAPI) method from MCF-7 cells (A) and mouse liver tissue (D). MCF-7 cell total soluble
proteome isolated by detergent lysis followed by sonication (B), and by French Pressure Cell Press(C). |
|
| |
| To directly compare ChlAPI method with conventional detergentbased
protein extractions, MCF-7 cells were ruptured by non-ionic detergents IGEPAL (NP-40) and Triton X100 followed by ultrasonication
to enhance cell lysis. The 2DE image of the detergentextracted
soluble proteins (Figure 1B) showed more or less the same
distribution of the proteins as those obtained by the ChlAPI method
(Figure 1A), and the total number of spots counted was1333. We also
tested French pressure cell press aided cell lysis to isolate proteins,
and subsequently obtained similar results (Figure 1C; 1286 protein
spots). This indicated that the ChlAPI method of protein isolation
is comparable to the commonly used method of protein isolation,
however avoids the use of detergents. |
Previous publications on the 2DE gel analysis of breast cancer
cells report similar number of proteins. For example, Canelle and
colleagues documented 1249 proteins from 150 μg of whole cell
extracts of MCF cells using a 2DE lysis buffer containing urea,
thiourea, CHAPS, and Triton X-100 (Canelle et al., 2006). Similarly,
using 2DE lysis buffer extracted 800 μg of MCF cell proteins, Bianchi
and others were able to identify an average of 1700 proteins from the
silver stained 2DE gels (Bianchi et al., 2005). Although, these studies
have resolved proteins at a pI scale of 3-10, they have obtained the
above number of protein spots using whole cell lysates prepared
in 2DE buffer whereas comparable numbers of protein spots were
observed here with only the aqueous fraction of ChlAPI method. This
suggests that protein isolation using ChlAPI method could potentially
leads to higher proteome coverage if both fractions were analyzed.
ChlAPI method was also tested on intact tissue samples such as mouse
liver tissue. The total number of protein spots obtained with 100 μg
protein extract was 1127. In addition, the spot distribution pattern
on the 2DE gel including the many linearly arranged protein spot
cluster across the pI dimension (Figure 1D) was observed to be similar
to the previously published 2DE images of mouse liver proteome
available at the Swiss-Prot 2D PAGE database (http://au.expasy.org/
ch2d/2DHunt) ; images can be retrieved through text search using
‘liver_mouse’). Thus, it is evident that the ChlAPI method can also be
extended to isolate proteins from mammalian tissue samples. |
| |
| ChlAPI method is compatible with LC-MS/MS |
| After the 2DE based verification of the complexity of proteins
isolated using ChlAPI method, we next asked whether we could apply
this procedure for shotgun LC-MS/MS (MudPIT) based interrogation
of the whole cell proteome of MCF-7 cells treated with and without
estrogen (17β-estradiol a.k.a E2). MCF-7 cells express high levels of
ER α which is known to exert pleiotropic cellular responses upon
binding to estrogens (Klinge, 2000; Moggs and Orphanides, 2001).
As described in the methods section, aqueous and organic phase
proteome fractions were isolated from control and E2-treated
MCF7 cells using ChlAPI method. Proteins present in the aqueous
phase are presumably hydrophilic which were subjected to trypsin
digestion; whereas the organic fraction was speculated to contain
a higher amount of hydrophobic and membrane proteins, and they
were udergone pre-cleavage by cyanogen bromide. Accordingly, the
automated MudPIT LC-MS/MS runs were conducted for four samples
(control_aqueous, control_organic, E2_aqueous, E2_organic). |
SEQUEST search analysis of all the spectra obtained from control_
aqueous sampleidentified a total of 752 unique protein groups from the IPI human database with the minimum protein- p value of 0.9
which corresponds to a false discovery rate (FDR) of <1%. The protein
groups consisted of IPI accessions that matched to the same set of
peptides. Data analysis of the control_organic sample spectra resulted
in the identification of 593 unique protein groups. Combining the
results of control_aqueous and control_organic samples showed
the presence of a total of 1134 non-redundant proteins (Table 1).
Similarly, SEQUEST searches of the E2_treated samplesidentified a
total of 1145 proteins with FDR of <1% (Table 1). |
| |
|
Table 1: MCF7 cell proteinsidentified after chloroform-assisted protein isolation
(ChlAPI) and mass spectrometry. |
|
| |
| Comparative analysis of data obtained from control and E2-treated
samples, and subsequent spectral count analysis revealed proteins
dysregulated by estrogen in MCF7 cells. An in-house software was
used for combining database search results from control and E2-
treated data and lead to global identification of proteins that are
common (887 proteins), unique to control (255 proteins), and uniqueto E2-treatment (266 proteins) (Figure 2A). After the conversion of
IPI accessions to entrez gene accessions, final list of non-redundant
accessions obtained for common, specific to control, and specific to
E2-treated were 879, 255, and 266, respectively. Additionally, MS2
spectra based normalization and statistical analysis was performed
(see Material and Methods section) for assessing differential protein
expression. Distribution of protein expression (log) ratios obtained
for proteinsidentified in both control and E2-treated sample is given
in Figure 2B. Proteins that pass the threshold cut-off, and considered
up and down- regulated by estrogen are colored in red and green,
respectively (Figure 2B). Based on the normalization and statistical
analysis, proteinsidentified only in control and only in E2-treated
samples were also further trimmed (see Material and Methods
section). Consequently, totals of 90 and 74 proteins were considered
up- and down- regulated respectively, by estrogen in MCF7 cells
(Figure 2C). These estrogen-responsive gene products are further
discussed in later sections. |
| |
|
Figure 2: Total and estrogen-regulated proteinsidentified from MCF-7 cells after
ChlAPI and nanoLC-MS/MS. (A) Venn diagram showing the total number
of proteinsidentified by mass spectrometry analysis of aqueous and organic
phase samples from control (-E2) and treated (+E2) MCF-7 cells with a false
discovery rate of <1%. (B) Protein expression ratio distribution of MCF-7 proteins
identified from both control and E2-treated samples. Entrez accessions for
common proteins listed in ‘A’ are further curated to remove redundant identifi cations
(Keen and Davidson). Protein spectral count (log 2) ratios were placed
into bins separated by 0.27 and plotted against the number of proteins in each
bin. Those that are marked green and red are considered true differentials and
are unexpected by chance based on threshold. (B) Venn diagram showing the
number of estrogen down- and up-regulated proteins based on the cut-off used.
Proteins shown in the middle are considered unchanged based on the threshold
used. |
|
| |
| One of the unique properties of higher organisms is the
complexity of cellular organization with compartmentalization. Any
phenotypic changes such as the development of cancer in those
cells are the result of coordinated and dynamic changes of proteins
at these sub-cellular compartments. Therefore, it is important that
the protein isolation methodology is able to extract proteins from
different sub-cellular compartments so as to help interrogate the
changes or perturbations. In addition, a good protein isolation
method should be unbiased towards any cellular compartment.
Accordingly, ChlAPI method isolated MCF-7 proteins were analyzed
for their cellular localizations. As they wereidentified from two
independent ChlAPI experiments, the 879 entrez identifiers that were
common to control and E2-treated samples were interrogated to
access the reproducibility. Report on cellular location was found for
480 proteins. Search outputs mapped these proteins to more than 50
different types of cellular compartment annotations, and they were
further collapsed manually into 26 categories (Figure 3A). As shown
in the pie chart, proteins from almost all of the cellular compartments
have been isolated with a typical proportion of proteins in the major
compartments. Percentage ofidentified proteins exclusive to the
major compartments such as cytoplasm, nucleus, and mitochondria
were, 24, 20, and 17.5, respectively, and a total of about 14%
annotated to be localized both in nucleus and cytoplasm (Figure 3A).
This showed that the ChlAPI method is efficient to obtain proteins
from majority of the cellular compartments. |
| |
 |
Figure 3: Cellular localization of MCF-7 proteins isolated using ChlAPI method.
(A) Cellular localization of MCF-7 proteinsidentified as common from two LCMS/
MS experiments (control and E2-treated) showing their percentage distribution
into each of the 26 categories. Given here are the characterized locations
for 879 proteins. (B) Comparison of transmembrane helices on MCF-7 proteins
identified from aqueous and organic phases of ChlAPI method. |
|
| |
| As reported by several workers, mass spectrometry analysis of
membrane proteins has been difficult due to the intrinsic nature of
the hydrophobicity and difficulty in isolating them with common
buffers. Various attempts were made to improve the identification of
these biologically important class of proteins (Barnidge et al., 1999;
Blonder et al., 2002; Ferro et al., 2000; Mirza et al., 2007; Molloy et
al., 1999; Zhang et al., 2007b). It has been documented that about
30% of the mammalian proteome is made up of these membrane
proteins (Stevens and Arkin, 2000). Interestingly, total number of
membrane proteins detected in this study from two independent
ChlAPI experiments, as shown for two sets of samples (control total,
and E2-treated total), was close to 30% (Table 1) which matches
perfectly to the expected coverage of membrane proteome (Stevens
and Arkin, 2000). Moreover, as expected the organic phase samples
(either control or treated samples) contained 40% membranes
proteins (Table 1) whereas the aqueous phase samples had only 12-
15%. An average, 78% of total membrane proteins wereidentified
from organic phase. The efficiency of ChlAPI method to extract higher
number of membrane proteins into the organic phase is further
supported by the prediction of number of transmembrane domains
on theidentified proteins (Figure 3B). While there were only few
aqueous phase proteins that contained one or two transmembrane
domains, large number of organic phase proteins contained three or
more transmembrane domains (Figure 3B). It is also noticeable that
the organic phase samples still had a major proportion of proteins
from other non-membrane locations of the cell (Table 1). This
observation apparently indicated that while the ChlAPI method could
be used to selectively enrich either membrane or non-membrane
proteins, combining the mass spectrometry data from aqueous and
organic phases help to increase the total proteome coverage. |
| |
| Analysis of estrogen-responsive gene products |
| Estrogens and their receptors are known to play key roles in
the genesis, progression, and treatment of breast cancers. MCF-7
cells have been used extensively as an in vitro model for studying
the effects of estrogen exposure, estrogen receptor activation and
inhibition on hormone-dependent breast tumor cell proliferation
(Keen and Davidson, 2003; Sandhu et al., 2005). To determine
whether the proteinsidentified in MCF-7 proteome are involved in
estrogen response, ‘SEQUEST’ search results were normalized and
spectral count-based differential protein expression analysis was
performed with high confidence as described before. This resulted in
the identification of 90 and 74 proteins as estrogen up-regulated and
down-regulated, respectively (Figure 2; Tables 2 and Table 3). Proteomics
analysis of MCF-7 proteins has been previously reported by several
workers (Bianchi et al., 2005; Canelle et al., 2006; Huber et al., 2004;
Kim et al., 2005; Lee et al., 2006; Malorni et al., 2006; Sandhu et
al., 2005; Zhu et al., 2008). Some of these studies have performed
E2 treatment, and several proteins reported as estrogen-regulated
in their studies areidentified as estrogen responsive in our analysis.
For example, dCTP pyrophosphatase 1 (XTP3TPA/ DCTPP1) which was
identified as an estrogen up-regulated protein with highest protein
expression ratio in this study (Table 2A) was reported as estrogen
up-regulated by Lee et al. (2006). Transcripts of XTP3TPA were found
to be affected by E2 metabolites (Kim et al., 2005). Similarly, histone
H1 and HSP90 ?identified in our study as dysregulated by estrogen
were also reported to be up-regulated by other workers (Table 2A).
Interestingly, expression of prohibitin 2 (PHB) appear to be downregulated
following E2 treatment in our study (Table 3A) although
it was reported earlier to be up-regulated by E2 (Zhu et al., 2008). |
| |
|
Table 2a: Proteins up-regulated by estrogen in MCF7 cells. Proteins identified
from control and E2-treated MCF7 cells. |
|
| |
|
Table 2b: Proteins up-regulated by estrogen in MCF7 cells. Proteins identified
from E2-treated MCF7 cells only. |
|
| |
|
Table 3a: Estrogen down-regulated proteins from MCF7 cells. Proteins
identified from control and E2-treated MCF7 cells. |
|
| |
|
Table 3b: Estrogen down-regulated proteins from MCF7 cells. Proteins identified
from control MCF7 cells only. |
|
Recently, the PHB which is also an estrogen receptor co-regulator
was shown to play a repressive role in estrogen signaling in MCF-
7 cells (He et al., 2008), supporting our observation. In addition to
the above examples, many proteins that were previously reported to
be directly linked to estrogen and estrogen receptor such as TPD52,
SHC, ILK, TOP2A, FEN1, CSTB, and GRB2 are indicated in Tables 2 and
3 along with the references (Acconcia et al., 2006; Al-Gubory et al.,
2008; Byrne et al., 1996; Canesi et al., 2007; Deroo et al., 2004; Kolar
et al., 1989, Moggs et al., 2005; Schultz-Norton et al., 2007; Song et
al., 2002; Suzuki et al., 2004; Tang and Wade, 2009; Toffolatti et al.,
2006; Verma et al., 2004; Walker et al., 2007; Zhang et al., 2007a;
Zhang et al., 2004). |
For integrative analysis of transcriptomic and proteomic data,
we compared the list of allidentified proteins with results from a
gene expression profiling study performed using high density DNA
microarrays to detect hormone-responsive changes in transcript
levels (Finlin et al., 2001). Using Locus Link reference accession
numbers as common identifiers between the two datasets, we
observed an overlap of 84 proteins (Supplementary file 1) out of a
total of 1400 proteins detected by mass spectrometry analysis, and 694 estrogen-responsive genesidentified in the microarray study
(including the previously reported genes) (Lin et al., 2004). The
estrogen responsive proteins that pass the stringent threshold set in
our analysis are indicated in Supplementary file 1. Transcript levels of
seven (XTP3TPA, SEC24D, BAG1, FEN1, TOP2A, PHB2, and ATP6V1A) of
the 11 E2-regulated proteins showed concordant trend in expression,
where as four of them (SET, ARHGAP1, MCM3, and MCM6) showed
the opposite. The discordance between protein expression and their
transcript levels points to a possible involvement of E2-dependent
post-transcriptional control mechanism for such proteins in MCF-7
cells. The proportion of estrogen responsive proteins in the MCF-7
proteome (6%; 84/1400) is comparable to that of the responsive genes
(4%; 694/17735) detected in the transcriptome by microarray analysis
(Lin et al., 2004). |
It is noteworthy that several proteins that are previously unknown
to be regulated by estrogen are designated as estrogen-regulated
(Tables 2 and 3) in our analysis, and are interesting candidates for
future study. For example, histidine triad nucleotide-binding protein
1 (HINT1) is found as down-regulated by estradiol (Table 3A). Very
recently, the tumor suppressor HINT1 is reported to inhibit the
phosphorylation of p27 by Src (Cen et al., 2009), an event leading to
increased cell proliferation (Chu et al., 2007). The inhibition of p27
phosphorylation involved down-regulation of Src (Cen et al., 2009).
Interestingly, it was previously known that estradiol bound ER activates
Src, culminating in cell proliferation (Migliaccio et al., 1996). Thus, it
is conceivable that estradiol regulate HINT1 negatively, leading to
the up-regulation of Src which in turn is responsible for increased cell
proliferation. Identification of HINT1 as estrogen down-regulated in
our proteomics analysis supports this hypothesis. Overall, the above
results indicate that the ChlAPI method described in this report and LC-MS/MS are effective for identifying and characterizing proteomic
constituents that are important for basic breast cancer biology. |
| |
| Conclusion |
| High throughput technologies such as transcriptomics and
proteomics offer the capacity to find alterations in large scale, and
identify previously unknown novel targets in cancer. One of the
problems in the widely used mass spectrometry based proteomics
is the interference of detergents and other impurities in the sample
that arise from the protein isolation procedures. Yet another problem
is the tremendous complexity of the biological samples that exceeds
the current analytical method and requires fractionation to detect
low abundance proteins and also the membrane proteins. Here, we
have used a chloroform-assisted, detergent-free protein isolation
method (ChlAPI) to isolate and fractionate mammalian proteome into
aqueous (hydrophilic) and organic (hydrophobic) fractions. Our result
showed that the ChlAPI method is an efficient and unbiased method
as revealed by the quality and quantity of proteome detected by 2DE
and LCMS/ MS. Application of ChlAPI method is demonstrated for the
proteome profiling of breast cancer cell line, MCF-7 with and without
estrogen, and subsequentlyidentified both known and previously
unknown estrogen-regulated gene products. From a total of 1400
proteinsidentified, 6% of their transcripts are estrogen responsive
in MCF-7 cells, and is comparable with the proportion of estrogen
responsive genes from microarray studies. Furthermore, our results
show that the ChlAPI method could be used to selectively isolate or
enrich membrane proteome that is suitable for mass-spectrometry analysis. Thus, the simple, detergent-free, and inexpensive ChlAPI
method described here could be used for mass spectrometry based
proteome analysis of mammalian cells or tissues. |
| |
| Competing Interests |
| The authors declare that they have no competing interests. |
| |
| Authors’ Contributions |
| SKS, AV conceived the study, and AV performed the experiments. AV and
AIN analyzed the data, AIN performed informatics analysis. TTY helped AV
in experiments, and GRK helped in data analysis. AV, CYL, SKS drafted the
manuscript, and ETL helped in coordination of the work. |
| |
| Acknowledgement |
| We thank Singapore Agency for Science Technology and Research (A*Star)
for its generous financial support. We are also grateful to Tech Yew Low and Ivy
Widyaja for technical help. |
| |
| References |
- Abramsky O, London Y (1975) Purification and partial characterization of two
basic proteins from human peripheral nerve. Biochim Biophys Acta 393: 556-
562.
- Acconcia F, Manavathi B, Mascarenhas J, Talukder AH, Mills G, et al. (2006) An
inherent role of integrin-linked kinase-estrogen receptor alpha interaction in cell
migration. Cancer Res 66: 11030-11038.
- Al-Gubory KH, Bolifraud P, Garrel C (2008) Regulation of key antioxidant
enzymatic systems in the sheep endometrium by ovarian steroids. Endocrinology 149: 4428-4434.
- Barnidge DR, Dratz EA, Jesaitis AJ, Sunner J (1999) Extraction method for
analysis of detergent-solubilized bacteriorhodopsin and hydrophobic peptides
by electrospray ionization mass spectrometry. Anal Biochem 269: 1-9.
- Bianchi L, Canton C, Bini L, Orlandi R, Menard S, et al. (2005) Protein profi le
changes in the human breast cancer cell line MCF-7 in response to SEL1L
gene induction. Proteomics 5: 2433-2442.
- Blonder J, Goshe MB, Moore RJ, Pasa-Tolic L, Masselon CD, et al. (2002)
Enrichment of integral membrane proteins for proteomic analysis using liquid
chromatography-tandem mass spectrometry. J Proteome Res 1: 351-360.
- Brugiere S, Kowalski S, Ferro M, Seigneurin-Berny D, Miras S, et al. (2004)
The hydrophobic proteome of mitochondrial membranes from Arabidopsis cell
suspensions. Phytochemistry 65: 1693-1707.
- Byrne JA, Mattei MG, Basset P (1996) Definition of the tumor protein D52
(TPD52) gene family through cloning of D52 homologues in human (hD53) and
mouse (mD52). Genomics 35: 523-532.
- Canelle L, Bousquet J, Pionneau C, Hardouin J, Choquet-Kastylevsky G, et
al. (2006) A proteomic approach to investigate potential biomarkers directed
against membrane-associated breast cancer proteins. Electrophoresis 27:
1609-1616.
- Canesi L, Borghi C, Fabbri R, Ciacci C, Lorusso LC, et al. (2007) Effects of
17beta-estradiol on mussel digestive gland. Gen Comp Endocrinol 153: 40-46.
- Cen B, Li H, Weinstein IB (2009) Histidine triad nucleotide-binding protein 1 upregulates
cellular levels of p27KIP1 by targeting ScfSKP2 ubiquitin ligase and
Src. J Biol Chem 284: 5265-5276.
- Chu I, Sun J, Arnaout A, Kahn H, Hanna W, et al. (2007) p27 phosphorylation
by Src regulates inhibition of cyclin E-Cdk2. Cell 128: 281-294.
- Deroo BJ, Hewitt SC, Peddada SD, Korach KS (2004) Estradiol regulates the
thioredoxin antioxidant system in the mouse uterus. Endocrinology 145: 5485-
5492.
- Eng JK, McCormack AL, Yates JR III, (1994) An Approach to Correlate Tandem
Mass Spectral Data of Peptides with Amino Acid Sequences in a Protein
Database. J Am Soc Mass Spectrom 5: 976-989.
- Ferro M, Seigneurin-Berny D, Rolland N, Chapel A, Salvi D, et al. (2000)
Organic solvent extraction as a versatile procedure to identify hydrophobic
chloroplast membrane proteins. Electrophoresis 21: 3517-3526.
- Fillingame RH (1976) Purification of the carbodiimide-reactive protein
component of the ATP energy-transducing system of Escherichia coli. J Biol
Chem 251: 6630-6637.
- Finlin BS, Gau CL, Murphy GA, Shao H, Kimel T, et al. (2001) RERG is a novel
ras-related, estrogen-regulated and growth-inhibitory gene in breast cancer. J
Biol Chem 276: 42259-42267.
- Gorg A, Obermaier C, Boguth G, Harder A, Scheibe B, et al. (2000) The current
state of two-dimensional electrophoresis with immobilized pH gradients.
Electrophoresis 21: 1037-1053.
- Goshe MB, Blonder J, Smith RD (2003) Affinity labeling of highly hydrophobic
integral membrane proteins for proteome-wide analysis. J Proteome Res 2:
153-161.
- He B, Feng Q, Mukherjee A, Lonard DM, DeMayo FJ, et al. (2008) A repressive
role for prohibitin in estrogen signaling. Mol Endocrinol 22: 344-360.
- Huber M, Bahr I, Kratzschmar JR, Becker A, Muller EC, et al. (2004) Comparison
of proteomic and genomic analyses of the human breast cancer cell line T47D
and the antiestrogen-resistant derivative T47D-r. Mol Cell Proteomics 3: 43-55.
- Keen JC, Davidson NE (2003) The biology of breast carcinoma. Cancer 97:
825-833.
- Keller A, Nesvizhskii AI, Kolker E, Aebersold R (2002) Empirical statistical
model to estimate the accuracy of peptide Identifications made by MS/MS and
database search. Anal Chem 74: 5383-5392.
- Kim SH, Lee SU, Kim MH, Kim BT, Min YK (2005) Mitogenic estrogen
metabolites alter the expression of 17beta-estradiol-regulated proteins
including heat shock proteins in human MCF-7 breast cancer cells. Mol Cells
20: 378-384.
- Klinge CM (2000) Estrogen receptor interaction with co-activators and corepressors. Steroids 65: 227-251.
- Kolar Z, Jarvinen M, Negrini R (1989) Demonstration of proteinase inhibitors
cystatin A, B and C in breast cancer and in cell lines MCF-7 and ZR-75-1.
Neoplasma 36: 185-189.
- Lee SU, Kim BT, Min YK, Kim SH (2006) Protein profi ling and transcript
expression levels of heat shock proteins in 17beta-estradiol-treated human
MCF-7 breast cancer cells. Cell Biol Int 30: 983-991.
- Lin CY, Ström A, Vega VB, Kong SL, Yeo AL, et al (2004) Discovery of estrogen
receptor alpha target genes and response elements in breast tumor cells.
Genome Biol 5: R66.
- Loo RR, Dales N, Andrews PC (1994) Surfactant effects on protein structure
examined by electrospray ionization mass spectrometry. Protein Sci 3: 1975-
1983
- Malorni L, Cacace G, Cuccurullo M, Pocsfalvi G, Chambery A, et al. (2006)
Proteomic analysis of MCF-7 breast cancer cell line exposed to mitogenic
concentration of 17beta-estradiol. Proteomics 6: 5973-5982.
- Migliaccio A, Di Domenico M, Castoria G, de Falco A, Bontempo P, et al. (1996)
Tyrosine kinase/p21ras/MAP-kinase pathway activation by estradiol-receptor
complex in MCF-7 cells. EMBO J 15: 1292-1300.
- Mirza SP, Halligan BD, Greene AS, Olivier M. (2007) Improved method for the
analysis of membrane proteins by mass spectrometry. Physiol Genomics 30:
89-94.
- Moggs JG, Orphanides G (2001) Estrogen receptors: orchestrators of
pleiotropic cellular responses. EMBO Rep 2: 775-781.
- Moggs JG, Murphy TC, Lim FL, Moore DJ, Stuckey R, et al. (2005) Antiproliferative
effect of estrogen in breast cancer cells that re-express ER alpha
is mediated by aberrant regulation of cell cycle genes. J Mol Endocrinol 34:
535-551.
- Molloy MP, Herbert BR, Williams KL, Gooley AA (1999) Extraction of Escherichia
coli proteins with organic solvents prior to two-dimensional electrophoresis. Electrophoresis 20: 701-704.
- Nesvizhskii AI, Keller A, Kolker E, Aebersold R (2003) A statistical model for
identifying proteins by tandem mass spectrometry. Anal Chem 75: 4646-4658.
- Parks BA, Jiang L, Thomas PM, Wenger CD, Roth MJ, et al. (2007) Top-down
proteomics on a chromatographic time scale using linear ion trap fourier
transform hybrid mass spectrometers. Anal Chem 79: 7984-7991.
- Ross PL, Huang YN, Marchese JN, Williamson B, Parker K, et al. (2004)
Multiplexed protein quantitation in Saccharomyces cerevisiae using aminereactive
isobaric tagging reagents. Mol Cell Proteomics 3: 1154-1169.
- Sandhu C, Connor M, Kislinger T, Slingerland J, Emili A (2005) Global protein shotgun expression profi ling of proliferating mcf-7 breast cancer cells. J
Proteome Res 4: 674- 689.
- Schultz-Norton JR, Walt KA, Ziegler YS, McLeod IX, Yates JR, et al. (2007) The
deoxyribonucleic acid repair protein flap endonuclease-1 modulates estrogenresponsive
gene expression. Mol Endocrinol 21: 1569-1580.
- Smolka MB, Zhou H, Purkayastha S, Aebersold R (2001) Optimization of the
isotopecoded Affinity tag-labeling procedure for quantitative proteome analysis. Anal Biochem 297: 25-31.
- Song RX, McPherson RA, Adam L, Bao Y, Shupnik M, et al. (2002) Linkage of
rapid estrogen action to MAPK activation by ERalpha-Shc association and Shc
pathway activation. Mol Endocrinol 16: 116-127.
- Stevens TJ, Arkin IT (2000) Do more complex organisms have a greater
proportion of membrane proteins in their genomes? Proteins 39: 417-420.
- Suzuki N, Itoh S, Poon K, Masutani C, Hanaoka F, et al. (2004) Translesion
synthesis past estrogen-derived DNA adducts by human DNA polymerases eta
and kappa. Biochemistry 43: 6304-6311.
- Tang YP, Wade J (2009) Effects of estradiol on incorporation of new cells in
the developing zebra fi nch song system: Potential relationship to expression of
ribosomal proteins L17 and L37. Dev Neurobiol 69: 462-475.
- Toffolatti L, Rosa Gastaldo L, Patarnello T, Romualdi C, Merlanti R, et al. (2006)
Expression analysis of androgen-responsive genes in the prostate of veal
calves treated with anabolic hormones. Domest Anim Endocrinol 30: 38-55.
- Tsai WP, Copeland TD, Oroszlan S (1985) Purification and chemical and
immunological characterization of avian reticuloendotheliosis virus gag-geneencoded
structural proteins. Virology 140: 289-312.
- Vellaichamy A, Sreekumar A, Strahler JR, Rajendiran T, Yu J, et al. (2009) Proteomic interrogation of androgen action in prostate cancer cells reveals
roles of aminoacyl tRNA synthetases. PLoS One 4: e7075.
- Verma S, Ismail A, Gao X, Fu G, Li X, et al. (2004) The ubiquitinconjugating
enzyme UBCH7 acts as a coactivator for steroid hormone receptors. Mol Cell
Biol 24: 8716-8726.
- Walker G, MacLeod K, Williams AR, Cameron DA, Smyth JF, et al. (2007)
Estrogen-regulated gene expression predicts response to endocrine therapy in
patients with ovarian cancer. Gynecol Oncol 106: 461-468.
- Washburn MP, Wolters D, Yates JR 3rd (2001) Large-scale analysis of the yeast
proteome by multidimensional protein Identification technology. Nat Biotechnol
19: 242- 247.
- Wolters DA, Washburn MP, Yates JR 3rd (2001) An automated multidimensional
protein Identification technology for shotgun proteomics. Anal Chem 73: 5683-
5690.
- Zhang B, Chambers KJ, Faller DV, Wang S (2007a) Reprogramming of the
SWI/SNF complex for co-activation or co-repression in prohibitin-mediated
estrogen receptor regulation. Oncogene 26: 7153-7157
- Zhang H, Lin Q, Ponnusamy S, Kothandaraman N, Lim TK, et al. (2007b)
Differential recovery of membrane proteins after extraction by aqueous
methanol and trifl uoroethanol. Proteomics 7: 1654-1663.
- Zhang Z, Kumar R, Santen RJ, Song RX (2004) The role of adapter protein Shc
in estrogen non-genomic action. Steroids 69: 523-529.
- Zhu Z, Boobis AR, Edwards RJ (2008) Identification of estrogen-responsive
proteins in MCF-7 human breast cancer cells using label-free quantitative
proteomics. Proteomics 8: 1987-2005.
|
| |
|
This Article |
DOWNLOAD |
|
CONTRIBUTE |
|
SHARE |
|
|
EXPLORE |
|
| |
|
|
|
|
