From the Biotechnologie, Biocatalyse, Biorégulation, Unité Mixte de Recherche 6204, Centre National de la Recherche Scientifique, Université de Nantes, 2 rue de la Houssinière, 44322 Nantes, France;
ProtNeteomix, Université de Nantes, 2 rue de la Houssinière, 44322 Nantes, France; and ¶ Cancer Research UK Molecular Oncology Unit, Barts and The London School of Medicine, London EC1M 6BQ, United Kingdom
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ABSTRACT |
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Many diseases are associated with, or even result from, modulations in protein expression. Therefore, monitoring simultaneously the expression profiles of a large number of proteins by antibody arrays can provide important information about the physiological status of the organism and can help to identify disease-specific biomarker candidates (2). Two main strategies have been proposed to compare and evaluate protein expression in cell lysates, both based on protein competition for binding to arrayed antibodies. The two-color approach detects differences in protein concentration between two cell lysates labeled by different fluorescent dyes and mixed in an equal ratio (3, 4). Two parallel experiments are run with mutually exchanged fluorescent dyes to reduce the possible interference from bio-conjugation bias of the dyes to proteins in the two samples. This method has been applied to evaluate protein profiling in human cancer cells and tissues (513). Recently a one-color approach (referred to as "competitive displacement") has been described that detects protein variations in lysates when the reference sample alone is labeled with a fluorescent dye (14, 15). Fluorescence intensity decreases differentially to be equivalent to, greater, or less than 50% displacement depending on the abundance of unlabeled proteins mixed in equal quantity with the labeled reference. This cost effective approach appears to be more convenient for large scale proteomic investigations. However, no data are available demonstrating the real competitiveness of labeled and unlabeled proteins on an antibody array, and it is important, therefore, to assess displacement activity in a single-protein competitive binding assay and to compare directly the performance of these two protein profiling detection methods.
In cells, many proteins are assembled into structural complexes in which a target epitope might be masked and thus not recognized by the corresponding antibody. To address this issue, we have used bacterial RNA polymerase (RNAP),1 a complex protein model assembled via the dimerization of subunits and the binding of ß, ß',
, and one of the exchangeable
subunits into a functionally active holoenzyme recognizing specific promoter sequences (16). To evaluate the one-color and two-color detection methods in protein profiling with antibodies arrayed on a nitrocellulose (NC) membrane, we have chosen near-infrared fluorescent dyes (IRDyes) for labeling proteins. Near-infrared fluorescence provides high sensitivity on membrane supports (17) and has been successfully used to detect molecular interactions on arrayed purified proteins (18), phage-displayed peptides (19), rat neuronal membrane fractions (20), and crude prokaryotic extracts (21). As the Escherichia coli
subunit of RNAP (
RNAP), labeled by IRDye, retains its binding ability to arrayed transcriptional factors (21), it has been used as a reporter to assess the competitiveness of labeled and unlabeled molecules in binding assays.
The information acquired from competition between individual prokaryotic proteins (RNAP and its subunits) has been used to compare more complex protein expression profiles in breast tumor-derived MDA MB-231 and SKBR3 cell lines with the aim of gaining insight into the functional grouping of targets involved in regulatory pathways. The data obtained with both detection methods were concordant for a few proteins; however, two-color detection allowed the abundance of a greater number of target proteins to be assessed, and we therefore conclude that this technique is better suited to high throughput protein profiling.
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EXPERIMENTAL PROCEDURES |
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Preparation of Bacterial Lysates for Competition Experiments
Recombinant E. coli BL21Star (DE3) strain (Invitrogen), carrying the plasmids pET rpoA-his or pET duet1 his-rpoA, rpoB/pACYC duet1 rpoC, rpoZ, were grown in LB medium to an OD600 of 0.60.8 and induced with 1 mM IPTG for up to 5 h. Aliquots were taken at 0, 1, 2, and 5 h of incubation, harvested by centrifugation, and resuspended in lysis buffer containing 50 mM NaH2PO4 pH 8.0, 300 mM NaCl, 10 mM imidazole, 1 mg/ml lyzozyme. The cells, after incubation at 4 °C for 2 h, were sonicated and cleared by centrifugation. The supernatant was filtered through 0.2-µm hydrophilic sterile filters (Fisher Labosi, Elancourt, France). This step significantly reduced fluorescent "noise" during subsequent assays on NC membrane-immobilized antibody arrays. Total protein concentration was measured by a biophotometer (Eppendorf, Le Pecq, France) using the bicinchoninic acid method (22) or the Bradford method (23) with BSA as the calibration standard. If necessary, the lysates were labeled and used to assess competition of respective proteins under different experimental conditions (see "Results").
Preparation of Eukaryotic Lysates for Competition Experiments
Human breast carcinoma cell lines MDA MB-231 and SKBR3 were grown in Dulbeccos modified Eagles medium with 4.5 g/liter glucose and L-glutamine (BioWhittaker, Verviers, Belgium) containing 10% FBS (BioMedia, Boussens, France) and 11.2 units/liter penicillin/11.2 µg/liter streptomycin at 37 °C and 5% CO2. Cells were washed three times with PBS (137 mM NaCl, 2.7 mM KCl, 4.3 mM Na2HPO4 pH 7.4) and lysed in PBS with 1% Nonidet P-40 and 1x protease inhibitor mixture at 4 °C for 15 min. Cellular DNA was sheared by brief sonication, and the solubilized proteins were harvested by centrifugation at 13,000 rpm for 15 min. Subcellular Proteome Extraction kit (Calbiochem) was also used to recover a higher proportion of nondenatured target proteins from various cellular compartments. The yield and quality of partial proteomes corresponding to cytosolic, membrane/organelle, nucleus, and cytoskeleton proteins were verified by SDS-PAGE analysis according to the manufacturers recommendations. Protein concentration was determined as described above.
Labeling Purified and Total Proteins in Cell Lysates with IRDyes
Purified proteins and prokaryotic or eukaryotic lysates were labeled with Alexa Fluor 680 (Molecular Probes, Cergy Pontoise, France) and/or IRDye 800CW (LiCOR Biosciences, Lincoln, NE) using a protocol adopted from Molecular Probes. Briefly, 5 µl of freshly prepared 1 M sodium bicarbonate buffer pH 8.3 was added to 50 µl of 2 mg/ml protein solution with the corresponding fluorescent dye, then incubated in the dark for 1 h with gentle shaking. The conjugated dye-protein complex was separated from free dye by gel filtration and eluted with PBS buffer. The average number of conjugated dye molecules was estimated, and samples with a final molar ratio of 23 dye molecules to 1 protein molecule were used to evaluate protein competitiveness in binding assays. Protein concentration was determined with a biophotometer as described above.
Western Blotting
Ten micrograms of total protein of prokaryotic cell extracts or 40 µg of total protein of eukaryotic cell extracts were separated on 12% SDS-PAGE and transferred to NC membrane. After blocking with PBS/0.05% Tween 20/5% skimmed milk, the membrane was incubated with the corresponding monoclonal primary antibody in PBS/0.05% Tween 20/3% BSA at room temperature for 2 h. After washing in PBS/0.05% Tween 20, the membrane was incubated for 1 h with Alexa Fluor 680 goat anti-mouse IgG secondary antibody or IRDye 800-conjugated affinity-purified goat anti-rabbit IgG (LiCOR Biosciences). Fluorescent detection was achieved by scanning the membranes at 700 or 800 nm using the Odyssey Infrared Imaging system (LiCOR Biosciences). The fluorescent protein bands were quantified by Molecular Analyst (Bio-Rad Laboratories).
Preparation of Antibody Arrays
Both monoclonal (mAb) and polyclonal antibodies (pAb) against selected proteins were used to fabricate several designs of arrays with different sets of antibodies depending on the experimental purpose. The mAbs generated against E. coli RNA polymerase subunits (mAb clone 4RA2), ß (mAb clone NT63), and ß' (mAb clone NT73) were purchased from NeoClone Biotechnology International (Madison, WI). Antibodies against eukaryotic proteins involved in stress response, cell-cycle progression, oncogenesis, apoptosis, and metastases were purchased from Interchim (Montlucon, France), BD PharMingen (San Diego, CA), Sigma-Aldrich (Lyon, France), and VWR International (Fontenay sous Bois, France). AP-2
(clone 8G8) and AP-2
(clone 6E4) mAbs were described previously (24). Antibodies were serially 2-fold titrated within a range of 10.125 mg/ml and printed on glass slides covered in-house with Protran BA83 NC sheet or on commercial FASTTM slides (Schleicher & Schuell, Equevilly, France) using a manual microarray system (Microcaster, Schleicher & Schuell, Equevilly, France).
Binding Assays
Two methods were used to evaluate protein binding to NC-immobilized antibodies. To assess competitive displacement by one-color detection (14), the arrayed membranes were blocked prior to use in PBS containing 0.12% Tween 20 by slow agitation on a platform rocker at room temperature for 1 h. The blocking solution was discarded and membranes were then incubated with a labeled probe (usually at 1 µg/ml concentration) or with a mixture of labeled and unlabeled protein samples. If necessary, a competitive unlabeled sample (as purified protein or total protein in lysates) was added at increasing ratios corresponding to 1, 10, or 100 µg/ml of total protein concentration. Membranes were incubated at room temperature for 30 min, washed three times with high-salt PBS-T buffer (PBS containing 500 mM sodium chloride and 0.1% Tween 20), and then dried. Fluorescent signals were detected by scanning membranes with the Odyssey Infrared Imaging system (LiCOR Biosciences).
In two-color detection, antibody arrays were incubated with an equal mixture of samples labeled with IRDye 800CW and Alexa Fluor 680 under the conditions described above and washed using a Protein Array Workstation (PerkinElmer Life Sciences).
Data Acquisition and Statistical Analysis
The software GenePix Pro 4.0 (Axon Instruments, Union City, CA) was used to quantify the image data. The local background in the near-infrared fluorescent wavelength channel was subtracted from the fluorescent signal registered from each antibody spot. Only spots displaying a fluorescent intensity greater than twice the level of background noise were used for further analysis.
Mean values of quadruplicate readings were used for the analysis of fluorescent intensity from spots detected by the one-color method. The degree of competition between labeled and unlabeled samples displaced at a 1:1 ratio (the best statistical fit to monitor displacement), were subtracted from values obtained after competition between the same labeled reference and another unlabeled sample.
In the two-color evaluation, data were scaled such that the average mean ratio value for all of the spots on each separate array was normalized to 1, with the premise that the average spot on the chip would represent unchanged protein expression. A data-based criterion was determined, above or below which proteins were found to be differentially expressed. To determine such a cutoff level, a hierarchical model approach was used (4) in which the parameters were estimated using ANOVA.
Normalized ratio (NMRAT) values outside the interval of 0.721.28 were considered differentially expressed with 95% statistical confidence when analyzing E. coli cell extracts in imitation experiments. NMRAT values outside the interval of 0.831.17 and 0.731.27 were considered differentially expressed with, respectively, 70 and 90% statistical confidence when analyzing total protein lysates of breast cancer MDA MB-231 and SKBR3 cell lines. To analyze proteins derived from the nuclear subfraction of the same cell lines, NMRAT values outside the intervals 0.821.18 and 0.711.29 were considered differentially expressed with, respectively, 70 and 90% statistical confidence.
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RESULTS |
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A four-parameter logistic regression method (25), used for competitive binding immunoassays, was applied to construct a plot of signal intensity versus analyte concentration.
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This shows the inverse relationship between the fluorescent signal y (fluorescence intensity at 700 or 800 nm) and the concentration of the unlabeled analyte x (protein in µg/ml) in which a is the maximum fluorescence estimated at zero concentration of x; b is the slope factor for the transition between a and d; c is the mid-range concentration of analyte corresponding to the point of inflection on the sigmoid; and d is the minimal signal at infinite x concentration corresponding to the background detected on an NC membrane. Signals can be normalized as a ratio of B and B0 corresponding to two fluorescent signals calculated respectively as a d and y d.
Assuming that no dissociation and rebinding occurs under the standardized conditions, the competition between labeled and unlabeled proteins for the single-antibody epitope should lead to 50, 90, and 99% displacement, respectively, at a mixed labeled:unlabeled sample ratio of 1:1, 1:10, and 1:100 as compared with the labeled reference protein or lysate. A typical competitive displacement curve for the purified bacterial RNAP, displayed on a semi-log plot, shows that the diminution of the fluorescent signal intensity (% B/B0) is dependent on an increase in the unlabeled analyte concentration within a detectable concentration range of immobilized antibodies (Fig. 2). B/B0 was plotted against the logarithm of the concentration of unlabeled
RNAP using Origin 7.0 software (OriginLab Corporation, Northampton, MA).
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Next, the immobilized anti-RNAP mAb (printed from 2-fold titrated solutions at concentrations ranging from 1 to 0.06 mg/ml) was probed with labeled
RNAP alone or a mixture of labeled:unlabeled
RNAP at various ratios. A diminution in the fluorescent signal, close to the expected theoretical values, was detected from spots corresponding to anti-
RNAP from 1 and 0.5 mg/ml antibody dilutions (see Fig. 2). The signal was weaker and poorly interpretable from spots printed at antibody concentrations less than 0.25 mg/ml. Therefore, further measurements were done by taking into account only signal intensities detected on spots printed from 1 and 0.5 mg/ml antibody concentrations.
To evaluate the accuracy of the competition between RNAP molecules, we took advantage of the two-color fluorescent detection method, enabling us to monitor the behavior of identical molecules labeled differentially. Purified
RNAP samples, separately labeled with Alexa Fluor 680 and IRDye 800CW, were mixed in different ratios and probed with the immobilized anti-
RNAP mAb. The reduction in fluorescent intensity at 700 nm (Fig. 3A) was accompanied by the appearance of a fluorescent signal at 800 nm (Fig. 3B). A good correlation in the modulation of the signal intensity confirmed the inverse relationship of the binding competition between two identical proteins, for the anti-
RNAP mAb arrayed on an NC membrane (Fig. 3C).
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Competition between RNAP and the RNAP Complex
Next, we were interested in determining whether competition occurs between small RNAP and large RNAP molecules. A labeled lysate (1 µg/ml total protein) of the E. coli BL21Star (DE3) (pET rpoA-his) cells, induced with IPTG for 1 h, was competed with purified unlabeled RNAP. A clear diminution in fluorescence intensity was detected corresponding to 30 and 70% displacement of
RNAP, respectively, for 1:1 and 1:10 ratios (Fig. 4A). However, this displacement rate was weaker compared with the competition between individual
RNAP molecules (see the previous section).
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These data showed that RNAP and the RNAP complex can compete for immobilized anti-
RNAP mAb. However, the large protein complex was less competitive compared with the smaller
RNAP molecule, and this can be explained, at least partially, by the lower molar presentation of the
-subunit in RNA polymerase.
Competitive Displacement of the RNAP Complex in Bacterial Cell Lysates
To gain insight into the competition behavior of a whole RNAP, we assessed its displacement in a mixture of labeled extract of E. coli BL21Star (DE3) (pET duet1 his-rpoA, rpoB/pACYC duet1 rpoC, rpoZ) cells after 1-h IPTG induction and in the unlabeled RNAP. The binding was followed in parallel assays with anti-RNAP, anti-ßRNAP, and anti-ß'RNAP mAbs immobilized on the same NC membrane. As shown in Fig. 4C, 55 and 95% displacement of the labeled lysate by unlabeled RNAP was detected with the anti-
RNAP mAb, respectively, at 1:1 and 1:10 ratios. Low fluorescence was observed from anti-ßRNAP and anti-ß'RNAP mAb spots with and without addition of unlabeled RNAP, which indicated that no displacement occurred under the conditions used (data not shown).
Similar experiments were performed with labeled and unlabeled lysates from E. coli BL21Star (DE3) (pET duet1 his-rpoA, rpoB/pACYC duet1 rpoC, rpoZ) obtained from 1-h IPTG-induced cells. Again, displacement was clearly observed with the anti-RNAP mAb, whereas no competition was detected with anti-ßRNAP and anti-ß'RNAP mAbs (data not shown).
To clarify this discrepancy in the competitive displacement, we followed the kinetics of , ß, and ß' subunit expression (as soluble proteins in the supernatant) in IPTG-induced cells of E. coli BL21Star (DE3) (pET duet1 his-rpoA, rpoB/pACYC duet1 rpoC, rpoZ) using Western blotting. As shown in Fig. 5, an abundant band corresponding to each protein appeared after 1-h induction. Densitometry of these protein bands revealed that the yield of
, ß, and ß' subunits was, respectively, 11-, 6-, and 4-fold greater in 1-h-induced cells compared with noninduced ones. However, further induction of the cells up to 5 h resulted only in 1.3- and 1.8-fold further increases in the yield of
RNAP and ß'RNAP, whereas the yield of ßRNAP increased 1.6-fold after 2 h induction and thereafter decreased to the level of a 1-h induction.
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Imitation of Protein Profiling Using Crude Bacterial Lysates
We next asked whether the competitive displacement can be detected in lysates obtained from bacterial host cells in which whole polymerase or its subunit were differentially expressed. To compare the amount of
RNAP synthesized in 1- and 2-h-induced cells, we mixed labeled and unlabeled lysates at 1:1 ratio and incubated the mixture with the arrayed anti-
RNAP mAb. The difference in protein expression deduced from the spots was found to be +25% when the labeled reference was the 1-h-induced lysate (Fig. 6A, compare the first two columns), whereas it was 15% when the labeled reference was a 2-h-induced lysate (Fig. 6A, compare the last two columns). Similar displacement values were obtained by following the behavior of RNAP in 1- and 2-h-induced cells, again using anti-
RNAP mAb for detection. However, no differential expression of RNAP was observed in cells when ßRNAP/anti-ßRNAP mAb or ß'RNAP/anti-ß'RNAP mAb couples were used for detection. The failure to detect the RNAP displacement with anti-ß'RNAP mAbs was not related to small differences in the amount of 1- and 2-h-induced lysates (see Fig. 5) because negative results were also obtained with mixtures of 1- and 5-h-induced cell lysates (data not shown).
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Comparative Protein Profiling in Breast Cancer Cells by One-color and Two-color Detection
Given the data obtained with "profiling" bacterial RNAP, we used one-color and two-color methods to evaluate their performance in assessing the differential expression of numerous proteins in breast cancer cell lines. An array of 72 selected antibodies was prepared by spotting each antibody in quadruplicate on FAST slides.
First, we compared the competitive displacement of labeled total proteins from MDA MB-231 cell lysates by unlabeled proteins from the same lysate. A decrease in fluorescence intensity was observed for many spots when mixing the two lysates at 1:1 and 1:10 ratios as compared with the reference array bound labeled lysate alone (Fig. 7, slides 1 and 2, and data not shown). We used data from the most informative 28 antibodies that gave the highest signals and analyzed the displacement characteristics at two ratios of mixed lysates. The expected theoretical values of 50 and
90% fluorescence diminution were detected for only 10 and 8 mAbs, respectively, whereas others gave significant deviations from the expected displacement values.
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In a parallel assay with the same antibody array, total proteins from the MDA MB-231 and SKBR3 cell lines were analyzed by two-color fluorescence detection (Fig. 8). Seven proteins, AP-2, cyclin D3, cyclin E, thymidylate synthase, catalase, 14.3.3
, and ErbB2, were found to be more abundant in SKBR3 cells than in MDA MB-231 cells with 70% statistical confidence. Moreover, even at the more stringent 90% statistical confidence level, 14.3.3
and ErbB2 were still found to be up-regulated in SKBR3 cells.
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These data indicated that both the one-color and two-color methods detected differential expression of the same four proteins, AP-2, catalase, thymidylate synthase, and ErbB2. However, overall two-color detection was more reliable than the one-color method in terms of its capacity to evaluate precise differential expression of a greater number of proteins in cells under the conditions used.
Improving Protein Profiling with Enriched Nuclear Proteins Using the Two-color Method
Analysis of NMRAT values indicated that some nuclear proteins showed a tendency toward differential expression with 60% statistical confidence when total protein lysates were used for profiling with the two-color method. Assuming that nuclear proteins are under-represented in our total cellular lysates, we wondered whether the profiling performance could be improved using an enriched nuclear subfraction.
We therefore performed similar experiments with nuclear extracts from MDA MB-231 and SKBR3 cell lines followed by two-color fluorescence detection. Eight proteins were found to be differentially expressed. Cyclin D1, AP-2, AP-2
, cyclin E, and cyclin D3 were expressed at higher levels in SKBR3 cells, whereas p53, c-Jun, and JNK1/2 were reduced in the same cells with 70% statistical confidence (Fig. 9). The remarkable differential expression of AP-2
, cyclin E, cyclin D3, AP-2
, and JNK1/2 was further validated using a more stringent NMRAT interval of 0.711.29 corresponding to 90% statistical confidence. Western blotting of total protein from MDA MB-231 and SKBR3 cells confirmed that cyclin D1 and AP-2
were overexpressed in SKBR3 cells, whereas c-Jun and JNK1/2 were at a lower abundance in these cells (see Fig. 8). The presence of two bands for JNK1/2 is due to recognition of the same epitope on two related JNK proteins by the anti-JNK1/2 mAb. These data confirmed that nuclear protein subfractionation provides more precise profiling information about the nuclear proteome in these cells.
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DISCUSSION |
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A model protocol, composed of mAbs immobilized on an NC membrane probed with bacterial RNA polymerase subunits and analytes containing purified or nonpurified target proteins, showed that one-color detection provides an accurate assessment of the competitiveness of RNAP or RNAP, when displacement is determined with an anti-
RNAP mAb. In contrast, no displacement of RNAP could be detected using anti-ß'RNAP mAbs with the one-color method, whereas this was possible with the same mAb using the two-color evaluation. How can this discrepancy be explained?
Random conjugation of almost 1 kDa of fluorescent dyes to the reference protein (23 dye molecules/protein) increases not only a proteins molecular mass, but also affects its folding, solubility, migration, and molecular recognition properties. As a consequence, the competitiveness of labeled proteins can be dramatically changed with respect to unlabeled ones when evaluated by one-color detection. In contrast, in two-color evaluation, both protein samples are labeled by chemically similar dyes through amine-reactive NHS ester bonds of the IRDyes. Even if physico-chemical properties are disrupted in the labeled proteins, the two samples remain highly similar to each other and hence are likely to display similar competition activity for the antibody, and thus the displacement better reflects protein expression differences in mixed analytes. Moreover, running two binding assays in parallel with mutually exchanged dyes results in, after normalization, a significant decrease in interference from dye conjugation bias.
These conclusions were born out when we profiled complex protein mixtures in breast cancer cell lysates using the two detection methods. The expression profile determined for several proteins using the one-color method was not confirmed by Western blot. However, the two-color method detected modulations in the level of expression of proteins that were not revealed using one-color detection. Therefore, we conclude that two-color profiling extends the utility of fluorescent assessment to a larger number of target proteins and is clearly better suited to high throughput analysis of differential expression of complex proteomes from mammalian cells.
The specificity of antigen-antibody interaction is a function of their affinity and antibody cross-reactivity, and this takes on a special significance in protein profiling studies (2931). Indeed, we have found that data obtained from some spots are impossible to interpret because of the high cross-reactivity of the antibodies as revealed by subsequent Western blot analysis. In addition, this study raises other important issues that can be useful for further improving the performance of high throughput protein profiling with array technology.
Western blot analysis has shown that anti-ßRNAP and anti-ß'RNAP mAbs bind to many smaller-molecular-mass species that accumulated in lysates from IPTG-induced cells (see Fig. 5). Such a pool of truncated ß and ß' subunits can interfere with the competitive displacement of whole RNAP assembled from full-length subunits. Notably, truncated derivatives were also observed for overexpressed cyclin E, 14.3.3, and ErbB2 in SKBR3 as well as for c-Jun in MDA MB-231 breast cancer cells. Therefore, we suggest that the presence of truncated proteins will contribute to a diminution in the specificity of antigen-antibody interactions and can thereby disrupt protein profiling performance.
We have also shown that the assessment of RNA polymerase expression depends strongly on the accessibility of the target epitopes by anti-subunit mAbs. Neither of the two methods detected variations in RNAP expression when competition was monitored by ß subunit binding to the anti-ßRNAP mAb. In agreement with this observation, the affinity purification of E. coli RNA polymerase using anti-ßRNAP mAb has been found to be inefficient in comparison with anti-RNAP and anti-ß'RNAP mAbs (32, 33). The three-dimensional structure of the related Thermus thermophilus RNA polymerase is available (34) and suggests a logical explanation for these negative results. It turns out that the ß epitope is almost completely masked by the other subunits, whereas the epitopes in the two
and ß' subunits are exposed on the surface of the RNAP holoenzyme (see Fig. 1A). As many proteins are organized into multi-molecular complexes in eukaryotic cells, we speculate that the efficiency of profiling proteins in their native state will be heavily influenced by the usually unpredictable accessibility of antibody recognition sites.
Low protein abundance is another limiting factor for protein profiling on minute planar spot surfaces when a total protein lysate is used. Near-infrared fluorescence allows the detection of attomol quantities of target molecules without signal amplification from protein patterns immobilized on a porous nitrocellulose support (21) with a sensitivity that is comparable to tyramide amplification and sufficient to assess the phosphorylation state in arrayed total proteins extracted from cancer biopsies (35). Unfortunately, the low proportion of target molecules in total protein lysates, used as solution analyte or as a printed analyte, strongly restricts the number of molecules that can be captured by the antibodies and thence be detected by near-infrared fluorescence. This limitation cannot be overridden by increasing the analyte concentration due to spot saturation. However, an analyte, enriched by target proteins isolated from the nucleus, can allow the identification of differential nuclear expression patterns that would not be detected using a total lysate. It appears that the use of a compartment-specific fraction provides both an augmentation in the proportion of target molecules in the analyte and a diminution in antibody cross-reactivity toward nontarget molecules located in other cellular compartments. Both aspects are crucial to increase the specificity of antigen recognition and the sensitivity of protein profiling.
A major advantage of antibody array technology is the protein profiling of tumors in a single experiment. Here, 12 proteins have been identified as increased or decreased in expression in two breast cancer cell lines, SKBR3 versus MDA MB-231, using a microarray prepared from 72 selected antibodies. Similar data obtained by other methods confirm these results for AP-2 and AP-2
(36), ErbB2 (37, 38), p53 (26), and c-Jun (37). A clear modulation of seven more proteins, including three cyclins D1, D3, and E, JNK1/2, thymidylate synthase, catalase, and 14.3.3
, underlies a wider pleiotropic effect of the cancer mutation(s) in the two cell lines.
The correlation between high levels of the AP-2 and AP-2
DNA binding transcription factors with overexpression of the ERBB2 proto-oncogene in tumor-derived cell lines has been documented previously (36). The antibody array data presented here were able to confirm this functional linkage by detecting the up-regulation of the AP-2 factors in ErbB2-positive SKBR3 cells versus ErbB2-negative MDA MB-231 cells, particularly when protein lysates enriched for nuclear factors were employed (see Fig. 9). This provides an important validation of our methodology and supports the possibility of being able to derive biological information by comparing the proteomes of other tumor-derived cell lines and ultimately tumor samples, and this is now under investigation.
We have also used our current data to compare more narrowly the biology of the two cell lines used in this study. Although not phenotypically alike, the two breast tumor-derived cell lines compared in this study share several features characteristic of poor prognosis breast cancer patients. Both lines are negative for the estrogen receptor and also carry mutations in their p53 genes. Moreover, the MDA MB-231 line is noted for carrying an activated Ha-Ras gene, and SKBR3 cells are extensively studied due to the amplification of their ERBB2(neu) gene, which contributes to the overexpression of this receptor, as noted above (see Fig. 8). In breast epithelial cells, ErbB2 lies upstream of Ras in the mitogenic signaling pathway (39), which leads to transcriptional induction of cyclin D1 (40, 41). Furthermore, activation of cyclin D1 by this pathway is essential in this cell type as demonstrated by studies in cyclin D1 null mice that are resistant to mammary carcinogenesis induced by either ras or neu oncogenes (42). By complexing with their partner kinases Cdk4/6 and Cdk2 to induce progressive phosphorylation and inactivation of pRb, the D-type and E-type cyclins control G1 to S phase transition during normal cell-cycle progression. Therefore, as both MDA MB-231 and SKBR3 cells are activated in essentially the same pathway and both have an intact RB gene, the levels of expression of these key growth factor target genes might be expected to be similar in the two cell lines. In our proteomic study, however, we find clear increased levels of cyclins D1, D3, and E in SKBR3 cells compared with the MDA MB-231 line, particularly when nuclear extracts are compared (see Fig. 9). Previous comparison of these lines at the RNA level had not indicated these differences in expression level (43). This suggests therefore that for mitogenic cyclins, post-transcriptional regulation of their protein levels is important.
Given the apparently mammary-specific wiring of the ERBB2/neu-Ras-cyclin D1 pathway, it has been argued that an anti-cyclin D1 therapy would be optimal for patients overexpressing ErbB2 (42). However, elevated cyclin E (both full-length and low-molecular-mass forms) has also been associated with poor survival in this disease and in multivariate analysis was more closely associated with outcome than levels of cyclin D1, D3, or ErbB2 (44). Moreover, because cyclin E acts downstream of cyclin D1, cells and tumors expressing even slightly elevated levels may bypass therapies targeted to cyclin D1 alone. The subtle differences, highlighted here, between two lines activated in the same signaling pathway could therefore prove to be a useful model system to test the efficacy of such therapies.
The data presented here show that NC-prepared microarrays provide repetitive and precise measurements of antigen-antibody interactions through protein competition for corresponding antibodies using both eukaryotic and prokaryotic lysates. We have recently demonstrated the possibility of an accurate comparative assessment of the antibody binding affinity of IgG purified from the sera of AIDS patients using a panel of arrayed phage-displayed peptides (19). Together, these data are encouraging in terms of the development of reliable immunoassays to assess binding parameters of complex protein mixtures within a range of the sensitivity useful for biomedical investigations and applications.
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ACKNOWLEDGMENTS |
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FOOTNOTES |
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Published, MCP Papers in Press, February 2, 2005, DOI 10.1074/mcp.M400181-MCP200
1 The abbreviations used are: RNAP, RNA polymerase; AP-2, activator protein-2; Cdk, cyclin-dependent kinase; ERK1, extracellular signal-regulated kinase 1; IgG, immunoglobulin G; IPTG, isopropyl-1-ß-D-thio-1-galactopyranoside; IRDye, near-infrared fluorescence dye; JNK1/2, c-Jun N-terminal kinase 1/2; LB medium, Luria-Bertani medium; mAb, monoclonal antibody; MDM2, mouse double minute 2 protein; NC, nitrocellulose; NHS, N-hydroxysuccinimide; Ni-NTA, nickel-nitrilotriacetic acid; NMRAT, normalized ratio; pAb, polyclonal antibody; Rb, retinoblastoma; VEGF, vascular endothelial growth factor.
2 G. Lebon, F. Marc, and V. Sakanyan, manuscript in preparation.
* This study was supported by the "Post-Génome" program (Contrat Etat Région des Pays de la Loire). G. Y. and G. L. are postgraduate students supported respectively by the National Council for Scientific Research Lebanon (CNRSL) and Ministère de la Recherche (ANRT)/ProtNeteomix.
|| To whom correspondence should be addressed: Biotechnologie, Biocatalyse, Biorégulation, Unité Mixte de Recherche 6204, Centre National de la Recherche Scientifique, Université de Nantes, 2 rue de la Houssinière, 44322 Nantes, France. Tel.: 33-251125620; Fax: 33-251125637; E-mail: Vehary.Sakanyan{at}chimbio.univ-nantes.fr, v.sakanyan{at}protneteomix.com
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REFERENCES |
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