Combination of a SAW-biosensor with MALDI mass spectrometric analysis

A S-sens K5 surface acoustic wave biosensor was coupled with mass spectrometry (SAW-MS) for the analysis of a protein complex consisting of human blood clotting cascade factor alpha-thrombin and human antithrombin III, a specific blood plasma inhibitor of thrombin. Specific binding of antithrombin III to thrombin was recorded as a function of time with a S-sens K5 biosensor. Two out of five elements of the sensor chip were used as references. To the remaining three elements coated with RNA anti-thrombin aptamers, thrombin and antithrombin III were bound consecutively. The biosensor measures mass changes on the chip surface showing that 20% of about 400fmol/cm2 thrombin formed a complex with the 1.7-times larger antithrombin III. Mass spectrometry (MS) was applied to identify the bound proteins. Sensor chips with aptamer-captured (1) thrombin and (2) thrombin-antithrombin III complex (TAT-complex) were digested with proteases on the sensor element and subsequently identified by peptide mass fingerprint (PMF) with matrix assisted laser desorption/ionization time-of-flight (MALDI-ToF) mass spectrometry. A significant identification of thrombin was achieved by measuring the entire digest with MALDI-ToF MS directly from the sensor chip surface. For the significant identification of both proteins in the TAT-complex, the proteolytic peptides had to be separated by nano-capillary-HPLC prior to MALDI-ToF MS. SAW-MS is applicable to protein interaction analysis as in functional proteomics and to miniaturized diagnostics.     

On-plate digestion of proteins using novel trypsin-immobilized magnetic nanospheres for MALDI-TOF-MS analysis

In this study, a novel method of on-plate digestion using trypsin-immobilized magnetic nanospheres was developed followed by MALDI-TOF-MS for rapid and effective analysis and identification of proteins. We utilized a facile one-pot method for the direct preparation of amine-functionalized magnetic nanospheres with highly magnetic properties and the amino groups on the outer surface. Through the reaction of the aldehyde groups with amine groups, trypsin was simply and stably immobilized onto the magnetic nanospheres. The obtained trypsin-linked magnetic nanospheres were then applied for on-plate digestion of sample proteins (myoglobin and Cytochrome c). Moreover, after digestion, the trypsin-linked nanospheres could be easily removed from the plate due to their magnetic property, which would avoid causing contamination on the ion source chamber in MS. The effects of the temperature and incubation time on the digestion efficiency were characterized. Within only 5 min, proteins could be efficiently digested with the peptide sequence coverage higher than or equal to that of the traditional in-solution digestion for 12 h. Furthermore, RPLC fractions of rat liver extract were also successfully processed using this novel method. These results suggested that our improved on-plate digestion protocol for MALDI-MS may find further application in automated analysis of large sets of proteins.     

An accurate mass tag strategy for quantitative and high-throughput proteome measurements

We describe and demonstrate a global strategy that extends the sensitivity, dynamic range, comprehensiveness, and throughput of proteomic measurements based upon the use of peptide "accurate mass tags" (AMTs) produced by global protein enzymatic digestion. The two-stage strategy exploits Fourier transform-ion cyclotron resonance (FT-ICR) mass spectrometry to validate peptide AMTs for a specific organism, tissue or cell type from "potential mass tags" identified using conventional tandem mass spectrometry (MS/MS) methods, providing greater confidence in identifications as well as the basis for subsequent measurements without the need for MS/MS, and thus with greater sensitivity and increased throughput. A single high resolution capillary liquid chromatography separation combined with high sensitivity, high resolution and accurate FT-ICR measurements has been shown capable of characterizing peptide mixtures of significantly more than 10(5) components with mass accuracies of < 1 ppm, sufficient for broad protein identification using AMTs. Other attractions of the approach include the broad and relatively unbiased proteome coverage, the capability for exploiting stable isotope labeling methods to realize high precision for relative protein abundance measurements, and the projected potential for study of mammalian proteomes when combined with additional sample fractionation. Using this strategy, in our first application we have been able to identify AMTs for >60% of the potentially expressed proteins in the organism Deinococcus radiodurans.     

Automated in-solution protein digestion using a commonly available high-performance liquid chromatography autosampler

A completely automated peptide mapping liquid chromatography/mass spectrometry (LC/MS) system for characterization of therapeutic proteins in which a common high-performance liquid chromatography (HPLC) autosampler is used for automated sample preparation, including protein denaturation, reduction, alkylation, and enzymatic digestion, is described. The digested protein samples are then automatically subjected to LC/MS analysis using the same HPLC system. The system was used for peptide mapping of monoclonal antibodies (mAbs), known as a challenging group of therapeutic proteins for achieving complete coverage and quantitative representation of all peptides. Detailed sample preparation protocols, using an Agilent HPLC system, are described for Lys-C digestion of mAbs with intact disulfide bonds and tryptic digestion of mAbs after reduction and alkylation. The automated procedure of Lys-C digestion of nonreduced antibody, followed by postdigestion disulfide reduction, produces both the nonreduced and reduced digests that facilitate disulfide linkage analysis. The automated peptide mapping LC/MS system has great utility in preparing and analyzing multiple samples for protein characterization, identification, and quantification of posttranslational modifications during process and formulation development as well as for protein identity and quality control.     

A bifunctional monolithic column for combined protein preconcentration and digestion for high throughput proteomics research

Enzymatic digestion of proteins is a key step in protein identification by mass spectrometry (MS). Traditional solution-based protein digestion methods require long incubation times and are limitations for high throughput proteomics research. Recently, solid phase digestion (e.g. trypsin immobilization on solid supports) has become a useful strategy to accelerate the speed of protein digestion and eliminate autodigestion by immobilizing and isolating the enzyme moieties on solid supports. Monolithic media is an attractive support for immobilization of enzymes due to its unique properties that include fast mass transfer, stability in most solvents, and versatility of functional groups on the surfaces of monoliths. We prepared immobilized trypsin monolithic capillaries for on-column protein digestion, analyzed the digested peptides through LC/FTICR tandem MS, and compared peptide mass fingerprinting by MALDI-TOF-MS. To further improve the digestion efficiency for low abundance proteins, we introduced C4 functional groups onto the monolith surfaces to combine on-column protein enrichment and digestion. Compared with immobilized trypsin monolithic capillaries without C4, the immobilized trypsin-C4 monolith showed improved digestion efficiency. A mechanism for increased efficiency from the combination of sample enrichment and on-column digestion is also proposed in this paper. Moreover, we investigated the effects of organic solvent on digestion and detection by comparing the observed digested peptide sequences. Our data demonstrated that all columns showed good tolerance to organic solvents and maintained reproducible enzymatic activity for at least 30 days.     

Downsizing proteolytic digestion and analysis using dispenser-aided sample handling and nanovial matrix-assisted laser/desorption ionization-target arrays

An efficient technique for enzymatic digestion of proteins in nanovial arrays and identification by peptide mass fingerprinting using matrix-assisted laser desorption/ionization (MALDI-MS) is presented in this work. Through dispensing of a protein solution with simultaneous evaporation the protein (substrate) is concentrated up to 300 times in-vial. At higher substrate concentrations the catalytic turnover numbers increase according to the Michaelis-Menten kinetics. Therefore, the dispenser-aided nanodigestion is valuable for identification of low-level proteins (10 nM-500 nM) as well as for automatic high efficiency digestions performed in 0.2-10 min. As an example of low-level protein identification, a 10 nM solution of lysozyme C was unambiguously identified after 5 min of nanodigestion. Moreover, only 30 s nanodigestion was sufficient to identify hemoglobin (10 microM), exemplifying the fast catalysis of the nanodigestion technique. The developed silicon flow-through piezoelectric dispenser is adapted for low-volume and preconcentrated samples in the nL-microL range and provides fast, accurate and contact-free sample positioning into the nanovials. In this work, the properties of the nanodigestion concept regarding proteins of different characteristics are explored. Furthermore, the potential of automated protein identification using precoated proteolytic nanovial-arrays is demonstrated.     

Proteomic analysis of acrylamide gel separated proteins immobilized on polyvinylidene difluoride membranes following proteolytic digestion in the presence of 80% acetonitrile

Two-dimensional polyacrylamide gel electrophoresis (2-D PAGE) combined with mass spectrometry (MS) is a highly accurate and sensitive means of identifying proteins. We have developed a novel method for digesting proteins on polyvinylidene difluoride (PVDF) membranes for subsequent matrix-assisted laser desorption/ionization-time of flight (MALDI-TOF) MS analysis. After Tricine sodium dodecyl sulfate (SDS)-PAGE, separated proteins were electroblotted onto PVDF membranes in a semidry discontinuous buffer system, visualized by staining with Coomassie Blue, excised, digested with trypsin or lysC in 80% acetonitrile, and then analyzed by MALDI-TOF MS. This method has several advantages over in-gel digestion in terms of sample handling, sensitivity, and time. We identified 105 fmol of Bacillus subtilis SecA and 100 approximately 500 fmol of standard proteins. We also analyzed the submembrane protein fraction solubilized by 1% n-dodecyl-beta-D-maltoside from B. subtilis membranes after separation by 2-D PAGE, and identified 116 protein spots. This method can detect proteins at the 10 approximately 50 fmol level by pooling more than ten identical electroblotted protein spots.     

Detection and identification of sub-nanogram levels of protein in a nanoLC-trypsin-MS system

Proteomic workflows involving liquid-based protein separations are an alternative to gel-based protein analysis, however the trypsin digestion procedure is usually difficult to implement, particularly when processing low abundance proteins from capillary column effluent. To convert the protein to peptides for the purpose of identification, current protocols require several sample handling steps, and sample losses become an issue. In this study, we present an improved system that conducts reversed-phase protein chromatography and rapid on-line tryptic digestion requiring sub-nanogram quantities of protein. This system employs a novel mirror-gradient concept that allows for dynamic titration of the column effluent to create optimal conditions for real-time tryptic digestion. The purpose behind this development was to improve the limits of detection of the online concept, to support flow-based alternatives to gel-based proteomics and to simplify the characterization of low abundance proteins. Using test mixtures of proteins, we show that peptide mass fingerprinting with high sequence representation can be easily achieved at the 20 fmol level, with detection limits down to 5 fmol (85 pg myoglobin). Limits of identification using standard data-dependent MS/MS experiments are as low as 10 fmol. These results suggest that the nanoLC-trypsin-MS/MS system could represent an alternative to the conventional "1D-gel to MS" proteomic strategy.     

On-chip microextraction for proteomic sample preparation of in-gel digests

Despite the high sensitivity and relatively high tolerance for contaminants of matrix-assisted laser desorption/ionization-time of flight mass spectrometry (MALDI-TOF MS) there is often a need to purify and concentrate the sample solution, especially after in-gel digestion of proteins separated by two-dimensional gel electrophoresis (2-DE). A silicon microextraction chip (SMEC) for sample clean-up and trace enrichment of peptides was manufactured and investigated. The microchip structure was used to trap reversed-phase chromatography media (POROS R2 beads) that facilitates sample purification/enrichment of contaminated and dilute samples prior to the MALDI-TOF MS analysis. The validity of the SMEC sample preparation technique was successfully investigated by performing analysis on a 10 nM peptide mixture containing 2 m urea in 0.1 m phosphate-buffered saline with MALDI-TOF MS. It is demonstrated that the microchip sample clean-up and enrichment of peptides can facilitate identification of proteins from 2-DE separations. The microchip structure was also used to trap beads immobilized with trypsin, thereby effectively becoming a microreactor for enzymatic digestion of proteins. This microreactor was used to generate a peptide map from a 100 nM bovine serum albumin sample.     

Analysis of protein tyrosine phosphatase interactions with microarrayed phosphopeptide substrates using imaging mass spectrometry

Microarrays of peptide and recombinant protein libraries are routinely used for high-throughput studies of protein–protein interactions and enzymatic activities. Imaging mass spectrometry (IMS) is currently applied as a method to localize analytes on thin tissue sections and other surfaces. Here, we have applied IMS as a label-free means to analyze protein–peptide interactions in a microarray-based phosphatase assay. This IMS strategy visualizes the entire microarray in one composite image by collecting a predefined raster of matrix-assisted laser desorption/ionization time-of-flight (MALDI–TOF) mass spectrometry spectra over the surface of the chip. Examining the bacterial tyrosine phosphatase YopH, we used IMS as a label-free means to visualize enzyme binding and activity with a microarrayed phosphopeptide library printed on chips coated with either gold or indium–tin oxide. Furthermore, we demonstrate that microarray-based IMS can be coupled with surface plasmon resonance imaging to add kinetic analyses to measured binding interactions. The method described here is within the capabilities of many modern MALDI–TOF instruments and has general utility for the label-free analysis of microarray assays.     

Hydrogel-based protein microchips: manufacturing,properties, and applications

Here a simple, reproducible, and versatile method is described for manufacturing protein and ligand chips. The photo-induced copolymerization of acrylamide-based gel monomers with different probes (oligonucleotides, DNA, proteins, and low-molecular ligands) modified by the introduction of methacrylic groups takes place in drops on a glass or silicone surface. All probes are uniformly and chemically fixed with a high yield within the whole volume of hydrogel semispherical chip elements that are chemically attached to the surface. Purified enzymes, antibodies, antigens, and other proteins, as well as complex protein mixtures such as cell lysates, were immobilized on a chip. Avidin- and oligohistidine-tagged proteins can be immobilized within biotin- and Ni-nitrilotriacetic acid-modified gel elements. Most gel-immobilized proteins maintain their biological properties for at least six months. Fluorescence and chemiluminescence microscopy were used as efficient methods for the quantitative analysis of the microchips. Direct on-chip matrix-assisted laser desorption ionization-time of flight mass spectrometry was used for the qualitative identification of interacting molecules and to analyze tryptic peptides after the digestion of proteins in individual gel elements. We also demonstrate other useful properties of protein microchips and their application to proteomics and diagnostics.     

A dual fluorescent/MALDI chip platform for analyzing enzymatic activity and for protein profiling

Being able to rapidly and sensitively detect specific enzymatic products is important when screening biological samples for enzymatic activity. We present a simple method for assaying protease activity in the presence of protease inhibitors (PIs) by measuring tryptic peptide accumulation on copolymer pMALDI target chips using a dual fluorescence/MALDI‐TOF‐MS read‐out. The small platform of the chip accommodates microliter amounts of sample and allows for rapid protein digestion. Fluorescamine labeling of tryptic peptides is used to indicate the proteolytic activity and is shown to be an affordable, simple process, yielding a strong fluorescence signal with a low background. Subsequent MALDI‐TOF‐MS analysis, performed in the same sample well, or in a parallel well without adding fluorescamine, detects the specific tryptic peptides and provides confidence in the assay. The dual read‐out method was applied to screen the inhibition activity of plant PIs, components of plant defense against herbivores and pathogens. Extracts of PIs from Solanum nigrum and trypsin were applied together to a pMALDI chip on which a suitable substrate was adsorbed. The fluorescence and MALDI‐TOF‐MS signal decrease were associated with the inhibitory effect of the PIs on trypsin. The developed platform can be modified to screen novel protease inhibitors, namely, those potentially useful for treating or preventing infection by viruses, including HIV and hepatitis C.     

Application of different surface plasmon resonance biosensor chips to monitor the interaction of the CaM-binding site of nitric oxide synthase I and calmodulin.

Surface plasmon resonance biosensors depend on modified gold surfaces to allow immobilization of proteins or peptides for interaction analysis. We investigated sensor chip surfaces that differ in the geometry of the immobilization matrix: two contain a three-dimensional coupling matrix and two have a surface with immobilization sites on a two-dimensional plane. Properties of sensor chips were compared by studying the interaction of calmodulin with a peptide representing the calmodulin-binding site of nitric oxide synthase I. Apparent K(D) values were determined by three different procedures in order to apply tests for self-consistency. At low surface densities (5-8 fmol/mm(2)) on three of the four tested surfaces, estimated K(D) values were within one order of magnitude and similar to the value found in solution (K(D) = 1-3 nM). When immobilization densities were increased by one to two orders of magnitude, apparent association rate constants were less distorted on a flat carboxymethylated surface than on dextran-coated sensor chips.     

Microwave-assisted protein preparation and enzymatic digestion in proteomics

The combinations of gel electrophoresis or LC and mass spectrometry are two popular approaches for large scale protein identification. However, the throughput of both approaches is limited by the speed of the protein digestion process. Present research into fast protein enzymatic digestion has been focused mainly on known proteins, and it is unclear whether these results can be extrapolated to complex protein mixtures. In this study microwave technology was used to develop a fast protein preparation and enzymatic digestion method for protein mixtures. The protein mixtures in solution or in gel were prepared and digested by microwave-assisted protein enzymatic digestion, which rapidly produces peptide fragments. The peptide fragments were further analyzed by capillary LC and ESI-ion trap-MS or MALDI-TOF-MS. The technique was optimized using bovine serum albumin and then applied to human urinary proteins and yeast lysate. The method enabled preparation and digestion of protein mixtures in solution (human urinary proteins) or in gel (yeast lysate) in 6 or 25 min, respectively. Equivalent (in-solution) or better (in-gel) digestion efficiency was obtained using microwave-assisted protein enzymatic digestion compared with the standard overnight digestion method. This new application of microwave technology to protein mixture preparation and enzymatic digestion will hasten the application of proteomic techniques to biological and clinical research.     

Improvement of an in-gel tryptic digestion method for matrix-assisted laser desorption/ionization-time of flight mass spectrometry peptide mapping by use of volatile solubilizing agents

The combination of matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS), in-gel enzymatic digestion of proteins separated by two-dimensional gel electrophoresis and searches of molecular weight in peptide-mass databases is a powerful and well established method for protein identification in proteomics analysis. For successful protein identification by MALDI-TOF mass spectrometry of peptide mixtures, critical parameters include highly specific enzymatic cleavage, high mass accuracy and sufficient numbers and sequence coverage of the peptides which can be analyzed. For in-gel digestion with trypsin, the method employed should be compatible both with enzymatic cleavage and subsequent MALDI-TOF MS analysis. We report here an improved method for preparation of peptides for MALDI-TOF MS mass fingerprinting by using volatile solubilizing agents during the in-gel digestion procedure. Our study clearly demonstrates that modification of the in-gel digestion protocols by addition of dimethyl formamide (DMF) or a mixture of DMF/N,N-dimethyl acetamide at various concentrations can significantly increase the recovery of peptides. These higher yields of peptides resulted in more effective protein identification.     

Improving sample treatment for in-solution protein identification by peptide mass fingerprint using matrix-assisted laser desorption/ionization time-of-flight mass spectrometry

Three ultrasonic energy sources were studied to speed up the sample treatment for in-solution protein identification by peptide mass fingerprint using matrix-assisted laser desorption/ionization time-of-flight mass spectrometry. Protein reduction, alkylation, and enzymatic digestion steps were done in 15 min. Nine proteins, including zinc resistance-associated protein precursor from Desulfovibrio desulfuricans strain G20 and split-soret cytochrome c from D. desulfuricans ATCC27774 were successfully identified with the new protocol.     

Mass spectrometric analysis of affinity-captured proteins on a dendrimer-based immunosensing surface: investigation of on-chip proteolytic digestion

The monolayer of fourth-generation poly(amidoamine) dendrimers was adopted to construct the immunoaffinity surface of an antibody layer. The antibody layer as a bait on the dendrimer monolayer was found to result in high binding capacity of antigenic proteins and a reliable detection. The affinity-captured protein at the immunosensing surface was subjected to direct on-chip tryptic digestion, and the resulting proteolytic peptides were analyzed by using matrix-assisted laser desorption/ionization time-of-flight mass spectrometry. The performance of the on-chip digestion procedure was investigated with respect to the ratio of trypsin to protein, digestion time, composition of a reaction buffer, and the amount of affinity-captured protein on a surface. Addition of a water-miscible organic solvent to a reaction buffer had no significant effect on the digestion efficiency under the optimized digestion conditions. The on-chip digestion method identified the affinity-captured bovine serum albumin (BSA), lysozyme, and ferritin at the level of around 100 fmol. Interestingly, the detected number of peptide hits through the on-chip digestion was almost similar regardless of the amount of captured protein ranging from low- to high-femtomole levels, whereas the efficiency of in-solution digestion decreased significantly as the amount of protein decreased to low-femtomole levels. The structural alignment of the peptide fragments from on-chip-digested BSA revealed that the limited exterior of the captured protein is subjected to attack by trypsin. The established detection procedures enabled the identification of BSA in the biological mixtures at the level of 0.1 ng/mL. The use of antibodies against the proteins involved in the metabolic pathway of L-threonine in Escherichia coli also led to discrimination of the respective target proteins from cell lysates.     

Integration of an on-line protein digestion microreactor to a nanoelectrospray emitter for peptide mapping

A method for integrating nanoelectrospray mass spectrometry with a microreactor for on-line digestion and fast peptide mass mapping from dilute protein samples is presented. Fused silica capillaries (i.d. 50 microm, o.d. 360 microm) are employed as the digestion microreactor and the nanoelectrospray emitter by immobilizing trypsin onto the surface of the inner wall of the fused silica capillary tubing. The procedure is demonstrated using solutions of 1pmol/mul angiotensin II, cytochrome c, hemoglobin, and beta-casein. Because the inner walls of the capillaries are modified by covalent chemical bonds, the adsorption of peptides and proteins to the inner walls of the capillaries is suppressed. This procedure was performed with solutions as dilute as 1fmol/mul (1nM) cytochrome c. This method shows generation of tryptic peptides with sequence coverage up to 90% within minutes; trypsin autolysis products are not detected. In addition, the immobilized enzyme can be cleaned easily, enabling the microreactor to be reused for nanoelectrospray.     

An optimized protein in-gel digest method for reliable proteome characterization by MALDI-TOF-MS analysis

Human lung epithelial cells (A549) were used as a model to develop a reliable proteome characterization method by peptide mass fingerprinting (PMF). Lung cell lysate proteins and protein standards were separated by 2D-gel electrophoresis, stained with Coomassie blue, gel plugs were subjected to commonly adapted as well as optimized in-gel digestion/sample preparation methods. Samples were analyzed by MALDI-TOF-MS. Optimization parameters included, use of NH(4)OAc in destaining and in-gel digestion buffers, detergent/salt removal prior to in-gel digestion, use of solvents of varying polarities (0%, 30%, 60% ACN containing 0.1% TFA) to improve peptide recoveries, matrix composition (alpha-cyano-4-hydroxycinamic acid-organic solvent combinations) and on-target salt removal. This led to enhanced mass spectral information and a sensitivity gain in the order of 6-10 fold compared to that of common procedures, yielding reliable, unambiguous protein identification with femtomol protein sensitivity by Autoflex MALDI-TOF-MS. Triplicate analyses by two analysts revealed consistent, wide range m/z values including in < 1200Da region by relieving matrix-exerted signal suppression, requiring one trial to obtain a unique protein identification with superior PMF results for the optimized method. Analyses of ten A549 proteins in replicates using the optimized method yielded fast, reliable characterization, suggesting the potential application of this method in high-throughput protein identification by PMF.