High Throughput Peptide Mass Fingerprinting and Protein Macroarray Analysis Using Chemical Printing Strategies*
Andrew J. Sloane
,
Janice L. Duff
,
Nicole L. Wilson
,
Parag S. Gandhi
,
Cameron J. Hill
,
Femia G. Hopwood
,
Paul E. Smith
,
Melissa L. Thomas
,
Robert A. Cole
,
Nicolle H. Packer
,
Edmond J. Breen
,
Patrick W. Cooley
,
David B. Wallace
,
Keith L. Williams
and
Andrew A. Gooley
,¶
Proteome Systems Limited, 1/3541 Waterloo Rd., North Ryde, Sydney, New South Wales 2113, Australia
Microfab Technologies, Inc., Plano, Texas 75074
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ABSTRACT
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We describe a chemical printer that uses piezoelectric pulsing for rapid, accurate, and non-contact microdispensing of fluid for proteomic analysis of immobilized protein macroarrays. We demonstrate protein digestion and peptide mass fingerprinting analysis of human plasma and platelet proteins direct from a membrane surface subsequent to defined microdispensing of trypsin and matrix solutions, hence bypassing multiple liquid-handling steps. Detection of low abundance, alkaline proteins from whole human platelet extracts has been highlighted. Membrane immobilization of protein permits archiving of samples pre-/post-analysis and provides a means for subanalysis using multiple chemistries. This study highlights the ability to increase sequence coverage for protein identification using multiple enzymes and to characterize N-glycosylation modifications using a combination of PNGase F and trypsin. We also demonstrate microdispensing of multiple serum samples in a quantitative microenzyme-linked immunosorbent assay format to rapidly screen protein macroarrays for pathogen-derived antigens. We anticipate the chemical printer will be a major component of proteomic platforms for high throughput protein identification and characterization with widespread applications in biomedical and diagnostic discovery.
The ability to accurately define protein expression in relationship to physiological changes associated with healthy or diseased states and the potential to discover novel drug targets are emerging themes of proteomic programs (1, 2). Understanding these dynamics is rendered complex given there is often no correlation between mRNA expression levels and protein expression (3), and the paradigm of one gene-one protein is known not to hold (4).
The rapid growth in proteomics has resulted in a technology-driven science oriented toward development of automated high throughput platforms (5). Sample prefractionation, advances in solubilization strategies, and improvements in two-dimensional gel electrophoresis (2-DE)1 are further refining this art (68). Identification and characterization of proteins is also becoming more rapid with the increasing development and application of mass spectrometry (MS) for peptide mass fingerprinting (pmf) and tandem MS sequence analysis (911).
Protein arrays are emerging state of the art technologies for high throughput proteomics (1216). Developments in protein array technology now encompass protein deposition on membranes, glass plates, microwells, polystyrene film (12, 1722), microfluidic chips, and biochips (2325) for screening complex protein mixtures for binding affinities, protein associations, and disease markers. With a move toward automation, deposition techniques used to produce these arrays now include pin-based or microdispensing liquid-handling robots (14), photolithography (26, 27), and ink-jet printing technology (2830).
Despite advantages of protein array technology such as speed, sensitivity, and multi-screening capabilities (15), chip-based proteomics has the major caveat that the protein arrays are either constructed from known proteins, such as antibodies, or an array of proteins derived from a recombinant expression system (15). Hence, the current chip-based approaches ignore the many protein isoforms produced by cells such as different co- and post-translationally modified forms of the same translated gene product, members of gene families, and variable spliced variants of mRNA and protein.
Recent advances in sample preparation have enabled many of the known protein isoforms to be displayed in 2-DE arrays (8). A Western blot of 2-DE separated proteins onto a membrane such as polyvinylidene fluoride (PVDF) or nitrocellulose represents a protein chip, albeit a macroarray. The protein macroarray differs from a protein chip microarray, because the coordinates of each protein are determined by the physical attributes of the isoelectric point and apparent molecular weight of the protein. Once the coordinates of each protein within the protein macroarray are identified by an image-capture device, each protein spot then has a defined X and Y position and can be manipulated by robotic platforms.
Here we present technology that combines the advantages of both protein chips and 2-DE, which we have described as a chemical printer (Fig. 1). The chemical printer uses a microjet device utilizing piezoelectric drop-on-demand-type ink-jet technology for rapid liquid microdispensing (3133). The ability of ink-jet printing to dispense minimal amounts of rare fluids and permit parallel processing of large numbers of tests means assay sizes can be decreased whereas assay density is increased (34, 35). These qualities have lead to increased applications for dispensing of bioactive materials. Immunodiagnostics and antibody/antigen dispensing (36), synthesis and deposition of oligonucleotides in microarray formats (29, 38, 39), protein and peptide analysis (40), and drug discovery (41) are a number of applications utilizing ink-jet printing technologies. We demonstrate in situ proteinase digests of membrane-immobilized protein macroarrays and subsequent MALDI-TOF MS analysis directly from the membrane surface. This approach bypasses the multiple liquid-handling steps associated with in-gel digestion procedures. Importantly, the ability to analyze immobilized proteins allows for both archiving of samples pre-/post-analysis and for multiple chemical reactions to be performed at different locations on an individual protein spot. We demonstrate identification of N-linked glycosylation sites by MALDI-TOF MS using sequential PNGase F and trypsin digestion, as well as preparation and extraction of oligosaccharides from PVDF membrane for structural analysis by LC-ESI MS.

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Fig. 1. A, schematic representation of the chemical printer. Piezoelectric microjets are connected to individual reagent reservoirs and an air pressure/vacuum control unit that enables ease of sample loading and fluid stabilization within the microjet devices. Fluid dispensing and motion of the target platform in both X and Y directions are controlled by integrated software and controller boxes. Droplet formation (panel B) and a top view of the target can be visualized using respective cameras and monitors. Image-capture software is used to define X and Y coordinate lists for automated fluid delivery. The height of the microjets (Z-axis) can be adjusted manually. B, a piezoelectric-generated droplet of 2-propanol. Sample was microdispensed from a glass capillary piezoelectric device with an orifice diameter of 55 µm. The droplet was generated by pulsing the device at a frequency of 240 Hz, with rise and fall times of 3 µs, respectively, a dwell time of 42 µs, and a dwell voltage of 30 V. The droplet has a volume of 100 pl. The image was captured by illuminating the droplet stream with a light-emitting diode (LED) that was pulsed concurrently at a frequency of 240 Hz.
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An exciting new high throughput assay also uses the chemical printer to microdispense antibodies onto membrane-immobilized proteins to rapidly define immunoreactivity and quantitate signals in a solid phase enzyme-linked immunosorbent assay-like format. The chemical printer thus represents a powerful tool for identification of novel protein targets for biomedical and diagnostic purposes.
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EXPERIMENTAL PROCEDURES
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Materials
Standard laboratory chemicals were obtained from Sigma unless specified otherwise. Human serum and plasma samples and 38 kDa tuberculosis (TB) protein were gifts from AP Clinical (Sydney, Australia). Where stipulated in the text, human serum albumin was depleted from plasma using methods described previously (42, 43). Human platelets were purchased from the Red Cross Blood Bank (Sydney, Australia). Contaminating red blood cells were removed from the platelets by centrifugation at 200 x g for 10 min at 4 °C. The platelet-rich plasma was then centrifuged at 1500 x g for 20 min at 4 °C. The platelet component of the pellet was removed gently and then resuspended in 50 mM Tris-HCl, 5 mM EDTA, pH 7.4. The platelets were washed similarly two more times. Whole platelets were finally solubilized using a ProteoPrepTM sample extraction kit (Sigma) using the supplied cellular and organelle membrane solubilizing reagent, to a final protein concentration of 4 mg/ml. Purified immunoglobulin was obtained from CSL (Parkville, Australia).
Chemical Printing
Solutions were dispensed using an
-version chemical printer being developed by Proteome Systems Ltd. (PSL) (Sydney, Australia) in collaboration with Shimadzu Biotech (Kyoto, Japan). Solutions were pre-filtered through either 0.22- or 0.45-µm membrane filters (Millipore). Glass capillary piezoelectric microjet devices (Microfab Technologies, Inc., Plano, TX) were used to dispense all solutions. X and Y coordinates of target protein spots were determined using ImagepIQTM, an in-house image-capture product (PSL).
Two-dimensional Gel Electrophoresis
Sample Preparation
36 µl of whole human plasma was made up to a final volume of 490 µl in 7 M urea, 2 M thiourea, 2% (w/v) CHAPS, and 5 mM Tris, pH 10.2. The sample was then ultrasonicated for 30 s, reduced with 3 mM tributylphosphine for 2 h, and then alkylated with 15 mM iodoacetamide for 1 h. Before rehydration of immobilized pH gradient strips, sample was ultrasonicated for 2 min and then centrifuged at 21000 x g for 5 min. The supernatant was collected, and 10 µl of Orange G was finally added as an indicator dye. Sample prefractionation into narrow range pI fractions was performed with an ElectrophoretIQTM multicompartment electrolyzer (8) (PSL).
First Dimension
Dry 11-cm immobilized pH gradient strips (Amersham Biosciences) were rehydrated for 6 h with 200 µl of protein sample. Rehydrated strips were focused on a Protean IEF cell (Bio-Rad) or PSL prototype IsoElectrIQTM electrophoresis equipment for 120 kV-h at a maximum of 10 kV. Focused immobilized pH gradient strips were equilibrated for 20 min in 6 M urea, 2% (w/v) SDS, 50 mM Tris-HCl, pH 7.0.
Second Dimension
Equilibrated strips were inserted into loading wells of 615% (w/v) Tris acetate SDS-PAGE pre-cast prototype 10 x 15-cm GelChipsTM (PSL). Electrophoresis was performed at 50 mA for 1.5 h. Proteins were electroblotted onto 0.45-µm nitrocellulose (Bio-Rad) or Immobilon PSQ PVDF membranes (Millipore) using a prototype ElectrophoretIQTM electroblotting apparatus (PSL) at 400 mA for 1.3 h and methods described by Kyhse-Andersen (44). Proteins were finally stained using Direct Blue 71.
One-dimensional SDS-PAGE Analysis of BSA
Titrated amounts of BSA were prepared in SDS-PAGE sample buffer containing 2% (w/v) SDS, 20% (v/v) glycerol, 0.025% (w/v) bromphenol blue, 50 mM dithiothreitol, 10 mM acrylamide, 0.375 M Tris, pH 8.8. Samples were allowed to reduce and alkylate for 1 h at room temperature prior to electrophoresis using a 615% (w/v) polyacrylamide ProteoGelTM (Sigma) and the conditions described above. Protein was finally electrotransferred onto an Immobilon PSQ PVDF membrane as described above.
On-membrane Protein Digestions
Immobilon PSQ PVDF membranes were first adhered to an Axima-CFR MALDI-TOF target plate (Kratos, Manchester, United Kingdom) using 3MTM electrically conductive tape 9703 (St. Paul, MN). Porcine trypsin (Promega, Madison, WI) at 200 µg/ml in 25 mM NH4HCO3, pH 8.5, or Staphylococcus aureus V8 endoproteinase Glu-C (Roche Molecular Biochemicals) at 200 µg/ml in 5 mM NaHPO4, pH 7.8, were dispensed as 50 or 25 iterations, respectively, onto protein spots at 1 nl per iteration. Prior to dispensing trypsin or Glu-C, either 3 x 1.5-nl iterations of 1% (v/v) n-octyl ß-D-glucopyranoside (OGP) or 5 nl of 1% (w/v) polyvinylpyrrolidone (PVP40) in 50% (v/v) methanol, respectively, were printed to pre-wet the PVDF membrane. Excess PVP40 was removed by washing with water using a transfer pipette. Digestion was performed for 3 h at 37 °C in a humidified environment. After digestion, 50 x 2-nl iterations of 10 mg/ml matrix solution,
-cyano-4-hydroxycinnamic acid in a methanol/2-propanol/2-butanol/0.5% (v/v) formic acid solution was then dispensed on top of the digestion zone of each spot. Digests were analyzed using an Axima-CFR MALDI-TOF mass spectrometer (Kratos). All spectra underwent an internal two-point calibration using autodigested trypsin peak masses, m/z 842.51 and 2211.10 Da. Software designed by PSL was used to resolve isotopic peaks from MS spectra (45). In-house databases and tools (PSL) and PeptIdent from the ExPASy molecular biology server (www.expasy.ch/tools/peptident.html) were used for pmf analysis using a mass tolerance of 100 ppm.
In-gel Tryptic Digestion
Protein gel pieces were excised using a prototype XciseTM system (PSL and Shimadzu Biotech) and then washed with 25 mM NH4HCO3, pH 8.5. Gel pieces were then dehydrated under vacuum for 15 min and digested with 10 µl of 20 µg/ml porcine trypsin in 25 mM NH4HCO3, pH 8.5, for 3 h at 37°C. Peptides were extracted from gel pieces with 10 µl of 50% (v/v) acetonitrile, 0.5% (v/v) formic acid and sonication for 10 min. Prior to MALDI-TOF MS analysis, peptides were concentrated and purified using a C18 ZipTip® (Millipore) and eluted onto a target plate in 2 µl of matrix solution and allowed to dry.
N-Linked Oligosaccharide Release
N-linked oligosaccharides were cleaved on the PVDF membrane, which was adhered to a MALDI-TOF plate by printing 50 x 10-nl iterations of 5 units/µl PNGase F (Roche Molecular Biochemicals) per protein spot and incubation for 3 h at 37°C in a humidified environment. Released oligosaccharides were extracted into 1 µl of water by pipette for LC-ESI MS analysis. The membrane was then washed with water using a transfer pipette. PNGase F-treated protein was subsequently digested on the membrane with trypsin using chemical printing followed by MALDI-TOF MS analysis.
LC-ESI MS
Sample was loaded onto a ThermoHypersil 5-µm Hypercarb column (Keystone Scientific Operations, Bellefonte, PA) using a Surveyor autosampler connected to an LCQ Deca mass spectrometer (ThermoFinnigan, San Jose, CA). Oligosaccharides were separated and eluted using a 30-min 025% (v/v) acetonitrile gradient in 10 mM NH4HCO3. Tandem MS analysis was performed in negative ion mode over a m/z range of 320 to 2000 Da. Oligosaccharide structures were predicted using the GlycoSuiteTM database (PSL).
Antigen Screening
Human serum was diluted 1:3 with phosphate-buffered saline containing 0.1% (v/v) Tween 20, 0.05% (w/v) NaN3, and 0.5% (w/v) casein, pH 7.4 (PBS-TAC), and then filtered through a 0.22-µm membrane (Millipore). Five applications of 10 nl of serum were printed onto proteins immobilized on a nitrocellulose membrane after blocking nonspecific binding sites with PBS-TAC for 15 min at room temperature. The membrane assay area was clamped onto a layer of absorbent tissue paper to prevent dispersal of fluid over the membrane surface during microdispensing. Excess antibody was removed by washing twice with 2 x 50-µl drops of PBS-TAC using a transfer pipette. Bound antibody was detected by pipetting 20 µl of goat anti-human IgG conjugated to fluorescein isothiocyanate (FITC) (Zymed Laboratories Inc., San Francisco, CA) diluted 1/10 with PBS-TAC. Fluorescence was detected using a Bio-Rad FluorSTM system.
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RESULTS
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Microdispensing Trypsin for High Throughput On-membrane pmf Analysis
Conventional pmf analysis of purified proteins involves isolation of individual protein spots from a gel (or membrane) followed by in-gel tryptic digestion, peptide extraction, peptide clean up, and finally loading the extracts onto a MALDI-TOF target (46). As an alternative rapid high throughput approach, we demonstrate dispensing of trypsin onto a macroarray of human plasma proteins on a PVDF membrane that had been adhered to a MALDI-TOF target plate (Fig. 2A). The most efficient digestion conditions were achieved by jetting 200 µg/ml trypsin in 50 x 1-nl iterations onto each protein spot. The small amount of drying time between each iteration increased the digestion efficiency by preventing excessive diffusion of trypsin solution across the membrane surface. Digestion sites on the hydrophobic PVDF membrane surface were pre-wet by printing either 4.5 nl of the non-ionic detergent nI-octyl ß-D-glucopyranoside or 5 nl of PVP40. This also prevented nonspecific binding of proteinase to the membrane. After digestion, matrix solution was dispensed directly onto the tryptic peptides prior to MALDI-TOF MS analysis directly from the membrane surface. Fig. 2A illustrates the relative size of the digestion zones (
200300-µm diameter). Of 14 protein spots representing a range of proteins present in various amounts (Fig. 2A) all were identified successfully by pmf analysis after on-membrane digestion (Table I). Fig. 2B shows a representative spectrum of apolipoprotein E generated after on-membrane digestion.

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Fig. 2. Microdispensing of trypsin for pmf analysis. A, reduced and alkylated plasma proteins were separated by 2-DE, pI 47, and then electroblotted onto Immobilon PSQ PVDF membrane. Proteins were visualized by staining with Direct Blue 71. The blot was then adhered to an Axima-CFR MALDI-TOF MS plate using 3MTM double-sided conductive adhesive tape. On-membrane tryptic digestions and subsequent MALDI-TOF MS directly from the membrane were then performed as described under "Experimental Procedures." Tryptic digestion sites are indicated by white spots caused by bleaching of the Direct Blue 71 by OGP (see inset). X and Y coordinates of the digestion sites were integrated across to the Axima mass spectrometer thereby permitting precise peptide analysis on the membrane. Peptide mass analysis data for 14 protein spots are shown in Table I. B, the mass spectrum (m/z range of 500 to 1800 Da) of tryptic peptides derived from spot 9 is shown. From 28 peptide matches this protein was identified as apolipoprotein E.
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TABLE I Comparison of pmf analysis of proteins identified from on-membrane versus in-gel tryptic digestions
Protein spots 114, as shown in Fig. 2, and spots 1520, as shown in Fig. 3, represent a range of proteins present in variable amounts as indicated by Direct Blue 71 staining intensity in human plasma and platelets, respectively. A comparison of pmf results for these proteins, digested either in-gel or on a PVDF membrane surface, is shown. Peptide hits include peptides containing carboxyamidomethylated cysteine and oxidized methione modifications.
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Detection of low abundance proteins is often a limitation in proteomic studies. Furthermore, alkaline proteins are even more difficult to identify given the difficulty in focusing such highly positive charged proteins. For this reason we have analyzed several low abundance alkaline platelet proteins to demonstrate that identification of such proteins is achievable using on-membrane digestion methods with the chemical printer (see Fig. 3 and Table I). Positive identification of nucleoside diphosphate kinase B (Table I) was confirmed following post-source decay analysis of the 1175.76 ion (data not shown).

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Fig. 3. On-membrane tryptic digestion of low abundance, alkaline whole-platelet proteins. Reduced and alkylated whole-platelet proteins were separated by 2-DE, pI 310, and then electroblotted onto an Immobilon PSQ PVDF membrane. Proteins were visualized by staining with Direct Blue 71. The blot was then adhered to an Axima-CFR MALDI-TOF MS plate as described previously. On-membrane tryptic digestion using the chemical printer and subsequent MALDI-TOF MS analysis directly from the membrane surface were then performed as described under "Experimental Procedures." Peptide mass analysis for the six proteins (spots 1520) is shown in Table I.
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The sequence coverages from peptides generated by on-membrane digestion were usually less than those from in-gel digests (Table I). This was not unexpected given the in-gel digests were each purified using a C18 ZipTip®, and the excised area of the in-gel digest was 1.2 mm in diameter, more than five times the area digested on-membrane. In some cases increased numbers of peptide hits were observed off the membrane, but lower sequence coverages were obtained relative to in-gel digests. This was a result of the higher abundance of smaller peptides extracted from the membrane surface (Table I). Nevertheless, with respect to sensitivity of peptide detection, analysis of on-membrane tryptic digests of BSA demonstrated that a targeted protein amount of 10 fmol of BSA was still sufficient for generating pmf data that enabled reliable protein identification (Table II).
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TABLE II MALDI-TOF MS sensitivity for detection of on-membrane tryptic peptides of BSA
Titrating amounts of BSA ranging from 2.5 pmol to 100 fmol per lane were prepared by one-dimensional SDS-PAGE using a 615% (w/v) polyacrylamide ProteoGelTM. Trypsin was dispensed using the chemical printer as described under "Experimental Procedures." The actual amount of protein digested, as estimated from the digestion area, was approximately 10% of the total band volume. BSA was visualized on the membrane (Immobilon PSQ PVDF) by Direct Blue 71 staining. The pmf results and sequence coverages are shown. Peptide hits include peptides containing propionamidomethylated cysteine and oxidized methione modifications and allow for one miscleavage. Peptide hits and % coverages are expressed as mean values ± S.D. obtained from four replicate experiments.
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Multiple Chemistry Subanalysis of PVDF Membrane-immobilized Proteins
The ability to dispense small volumes of reagents to specific locations permitted multiple chemical analyses of a single protein spot. Here we demonstrate release of N-linked oligosaccharides from human
-1-antitrypsin after chemical printing and on-membrane digestion with the endoglycosidase PNGase F. Released oligosaccharides were subsequently extracted from the membrane surface. LC-ESI MS analysis of these extracted oligosaccharides identified four different carbohydrate moieties on
-1-antitrypsin (Fig. 4A). Deglycosylation of Asn results in deamidation converting the Asn to an Asp and consequently increasing the m/z of the parent protein by 1.0 Da. This enables identification of sites of N-linked glycosylation following tryptic digestion and pmf analysis. This study revealed one of three predicted peptides, peptide 70101, with an observed m/z 3692.8 Da, implicating Asn-83 as an N-linked glycosylation site (Fig. 4B). This is the largest of the expected tryptic peptides of
-1-antitrypsin, which contained N-linked glycosylation. The other two glycosylation sites occur on peptide 4069 (predicted m/z 3181.6 Da) and peptide 244259 (predicted m/z 1755.9 Da). It is possible that sites Asn-46 and Asn-247 were not deglycosylated and hence not desorbed in reflectron mode. The peptide containing Asn-46 was definitely cleaved by trypsin as both peptides N- and C-terminal to peptide 4069 were identified in the MALDI-TOF spectrum. No peptides between residues 218 and 274 were identified, so it is possible that the tryptic peptide containing Asn-247 was never cleaved.

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Fig. 4. Microdispensing of multiple enzymes for characterizing N-linked glycosylation. A, reduced and alkylated human plasma proteins (human serum albumin depleted) were pre-fractionated using a multi-compartment electrolyzer, pI 47, and then separated by 2-DE, pI 56, and electroblotted onto an Immobilon PSQ PVDF membrane. An -1-antitrypsin spot was digested with PNGase F by chemical printing. Released N-linked oligosaccharides were analyzed by LC-ESI MS. Using GlycoSuiteTM database searches, four oligosaccharide structures were predicted from the MS spectrum as shown. B, PNGase F-treated -1-antitrypsin was digested secondarily with trypsin by chemical printing and subsequently analyzed using MALDI-TOF MS. Tryptic peptide peaks, representing 51.3% coverage of -1-antitrypsin, are shown. One peptide, m/z 3692.8 Da, was identified as a peptide containing an Asn residue (Asn-83) glycosylated previously based on an increase in m/z of 1.0 Da from the expected peptide mass resulting from the deamidation reaction.
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The ability to dispense multiple enzymes for increasing protein sequence coverage, and thus increase confidence in protein identification, has also been demonstrated (Table III). On-membrane digestion of a single protein spot, apolipoprotein A1 (a different sample from that described in Table I), with both Glu-C and trypsin, resulted in sequence coverages of 41.6 and 46.1%, respectively. The combined sequence coverages represented 66.7% of the total sequence of apolipoprotein A1.
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TABLE III Increased sequence coverage using on-membrane multiple enzyme digestion strategies
Reduced and alkylated human plasma proteins were separated by 2-DE, pI 47, and then electroblotted onto Immobilon PSQ PVDF membrane. Proteins were visualized by staining with Direct Blue 71. An apolipoprotein A-1 spot (SwissProt accession number P02647) was then digested by using the chemical printer to microdispense 5 nl of PVP40 followed by either 25 nl of 200 µg/ml Glu-C (inset, G) or 50 nl of 200 µg/ml trypsin (inset, T) in 1-nl iterations. Peptides generated after digestion with Glu-C (light grey boxes) and trypsin (dark grey boxes) resulted in sequence coverages of 41.6 and 46.1%, respectively. Italics and black boxes indicate the overlapping peptide sequences. The total sequence coverage after combining both sets of pmf data was 66.7%.
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Mapping Immunodiagnostic Markers
From a biomedical perspective we have demonstrated the ability to identify immunoreactive pathogen-derived antigens in human plasma and simultaneously compare immunoreactivity of multiple patient sera. Sera from six different patients (af) were sequentially printed onto a macroarray of plasma proteins that had been spiked with a 38-kDa mycobacterium TB protein. The results from two protein spots (1, a human (control) protein and 2, the TB protein) are shown (Fig. 5A). Antigen recognition was determined after subsequent application of anti-human IgG conjugated to FITC in reaction times of less than 3 min. Patients d and e demonstrated strong recognition of the 38-kDa TB antigen whereas patients c and f reacted weakly. Patients a and b were TB-negative controls. These findings demonstrate how potentially new pathogen-specific antigens can be identified using patient serum antibodies. In additional studies, titrated amounts of human immunoglobulin antigen were printed onto nitrocellulose. Subsequent to detection using excess anti-human IgG-FITC-conjugated antibody, comparison of relative signal intensities versus antigen concentration demonstrated a linear relationship, thus highlighting the potential for quantitating signal responses derived from chemical printing strategies (Fig. 5B).

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Fig. 5. A, microarray analysis for the detection of a TB antigen in macroarrayed human plasma using TB± sera. 36 µl of reduced and alkylated human plasma, spiked with 250 pmol of 38-kDa TB antigen, was separated by 2-DE, pI 310, and then electroblotted onto a nitrocellulose membrane. Protein spots were analyzed for their immunoreactivity against TB± sera from six different donors (af) (insets) using chemical printing as described under "Experimental Procedures." Results from two protein spots are shown. Positive signal was detected using FITC-conjugated goat anti-human secondary antibody followed by analysis with a Bio-Rad FluorSTM Multi-Imager with a 2-min exposure time. No signal for spot 1, an unknown, indicates it as a human protein whereas strong signals for spot 2 identifies it as the foreign 38-kDa TB protein. The poor image sharpness of this blot relative to the PVDF membrane in Fig. 2 is because of inherent poor staining qualities of nitrocellulose membranes. B, relationship between signal intensity and immobilized immunoglobulin levels. A 3 x 3 array of purified human IgG at titrating concentrations of 20, 40, and 60 µg/ml (inset, top row), 80, 100, and 120 µg/ml (inset, middle row), and 140, 160, and 180 µg/ml (inset, bottom row) was printed onto nitrocellulose at 100 drops (10 nl) per titer. The array was then treated with FITC-conjugated secondary antibody, and signal was detected as in A. Signal intensity was plotted against IgG concentration. The data presented represent the average of four replicate experiments. Error bars indicate standard deviations.
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DISCUSSION
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Although DNA microarrays have been heralded as a revolution in genomic studies, the role of protein microarrays in proteomic studies is not as simple, principally because of the challenges of developing high throughput strategies for preparing proteins prior to their deposition onto chip surfaces. Generally, protein arrays use recombinant proteins that are arrayed robotically onto surfaces. However, a fundamental problem with this approach is that the recombinant proteins are not unique, lacking the myriad co- and post-translational modifications that lead to protein isoforms, many of which are cell type-specific.
The strategy we have presented here is to array authentic samples using 2-DE gels as the primary protein array technology rather than robotic printing of recombinant proteins. This approach ensures that the proteins modified authentically are arrayed properly to a coordinate that is determined by the isoelectric point and apparent molecular weight of the protein. Depending on the sample preparation technique, hundreds to thousands of proteins can be arrayed using this "GelChip" approach.
The ability to miniaturize classical technologies like protein digestion and immunoblotting as a protein chip approach has been demonstrated in this report using chemical printing strategies. This printer technology can reproducibly dispense picoliter volumes of reagents to defined locations thereby permitting microscale chemical analyses. Printing is a non-contact process ensuring the fluid source is not contaminated by substrate during a printing event. Furthermore, the accuracy of dispensing is not affected by how the fluid wets a substrate as can be the case in other well established high throughput technologies where positive displacement or pin transfer systems "touch off" or stamp fluid onto a substrate during dispensing (14). The ability to free-fly fluid droplets over 0.5 mm or more allows fluid dispensing into wells or onto other substrate features such as those created by controlled wetting and chemical deposition.
Using human plasma and platelets as model systems, we have demonstrated how on-membrane tryptic digests can be generated rapidly after accurately dispensing trypsin directly onto a protein target. Adherence of the membrane to a MALDI-TOF plate during this procedure permits easy transition to the mass spectrometer for pmf analysis. The ability of chemical printing strategies to bypass the more time consuming procedures of in-gel digestion, peptide extraction, and C18 ZipTip® clean-up steps, without significantly compromising protein identification, provides both a much more rapid approach to pmf for high throughput mapping of complex protein solutions and the ability to archive samples for future analysis. Furthermore, these approaches enable identification of both high and low abundance proteins, and future studies will aim to further characterize the human platelet protein map.
The sensitivity of on-membrane digestion using the chemical printer has also been highlighted in this study by digestion and subsequent successful pmf identification of
10 fmol of BSA immobilized on an Immobilon PSQ PVDF membrane. This level of sensitivity is equal to, if not higher than, other reported in-gel digestion procedures (47, 48).
Another emerging technology for automated pmf analysis is the molecular scanner, which simultaneously digests and electrotransfers peptides onto a PVDF membrane (49). The strategy of the molecular scanner is not to visualize the polypeptides on the electroblot but to rapidly scan the membrane to detect the presence of peptides. The process is inefficient, because digested proteins only occupy a low percentage of the entire area that is scanned. Unlike the chemical printer, the molecular scanner cannot control delivery of different amounts of trypsin to different protein spots. Furthermore, the digestion of all of the sample on the membrane abolishes the ability to archive untreated samples. Subsequent analyses using alternate chemistries are therefore limited. The ability to archive and also subject a protein to multiple analyses are advantages of the chemical printer approach. Furthermore, the option to specifically select individual proteins for subanalysis using multiple chemistries increases both time efficiency and conservation of valuable reagents and samples.
Protein transfer onto a membrane is an inherent component of the experimental strategies presented here. Importantly, we have found routinely that protein transfer of a specific sample onto a particular membrane type is a highly reproducible process. However, it must be appreciated that buffer conditions should be optimized for analysis of a particular proteome (50). The studies presented here have used the transfer conditions described by Kyhse-Andersen (44) that were optimized for proteins with molecular mass less than 200 kDa and pI 47. Thus, other buffer systems, as well as membrane types, should be considered if particular proteins with specific characteristics, such as size, antigenicity, pI, or hydrophobicity are required for analysis (51).
Although other studies have demonstrated remarkable examples of large scale protein identification (52), the ability for multiple analyses on a specific protein(s) within the same sample, such as mapping post-translational modifications, is limited in these approaches. We have demonstrated successful on-membrane digestion by sequentially delivering PNGase F and trypsin for mapping sites of N-glycosylation on human
-1-antitrypsin. With the increasing interest in post-translational modifications, particularly glycosylation (37), this technology also represents a powerful tool, particularly when coupled with LC-ESI MS, for structural analyses of oligosaccharides released from a solid-phase membrane. Furthermore, the ability to analyze a single protein spot using multiple endoproteinases has demonstrated the ability to increase markedly the sequence coverage of a protein, thus increasing confidence of a successful identification. In principle it should be possible to achieve complete characterization of proteins with such an approach. This is a significant advantage, particularly when considering characterization of low abundance proteins or proteins that contain minimal cleavage sites for a single enzyme.
One of the major outcomes of the proteomic era will be the identification of novel protein targets useful for biomedical applications, particularly in the diagnostic arena. In this study we have printed nanoliter volumes of serum from different patients onto individual plasma protein spots of a macroarray in a quantitative miniaturized enzyme-linked immunosorbent assay format. Unlike Western blotting protocols practiced currently that routinely require at least 3 h per analysis, rapid dispensing of multiple antibodies can be used to screen for antigens in several minutes. Using chemical printing, Western blotting becomes a rapid and quantitative user-independent technology. We have thus demonstrated one strategy that permits mapping immunoreactive antigens using human sera for subsequent identification by pmf analysis with implications for identifying vaccine and diagnostic targets.
Understanding the dynamic and complex nature of the proteome of an organism will require the development of high throughput multi-tasking proteomic platforms to cope with this enormous task. The chemical printer represents a technology that can function as a component of a proteomic platform working in conjunction with the powerful resolving tools of 2-DE and MS or as a standalone work station.
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ACKNOWLEDGMENTS
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We thank Dr. Tracey Edgell for assistance in plasma sample preparation and Dr. Alice Zhou (AP Clinical, Sydney, Australia) for the generous supply of serum and plasma samples and TB protein.
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FOOTNOTES
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Received, March 18, 2002, and in revised form, June 26, 2002.
Published, MCP Papers in Press, July 3, 2002, DOI 10.1074/mcp.M200020-MCP200
1 The abbreviations used are: 2-DE, two-dimensional gel electrophoresis; BSA, bovine serum albumin; CFR, curved field reflectron; ESI, electrospray ionization; FITC, fluorescein isothiocyanate; LC, liquid chromatography; MALDI-TOF, matrix-assisted laser desorption/ionization time of flight; MS, mass spectrometry; OGP, n-octyl ß-D-glucopyranoside; PBS-TAC, phosphate-buffered saline containing 0.1% (v/v) Tween 20, 0.05% (w/v) NaN3, and 0.5% (w/v) casein, pH 7.4; pmf, peptide mass fingerprinting; PSL, Proteome Systems Limited; PVDF, polyvinylidene fluoride; TB, tuberculosis. 
* This work was supported in part by an AusIndustry R and D START program and by Shimadzu Corporation, Kyoto, Japan. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. 
¶ To whom correspondence should be addressed. Tel.: 61-2-9889-1830; Fax: 61-2-9889-1805; E-mail: andrew.gooley{at}proteomesystems.com
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