Characterization of nonenzymatic glycation on a monoclonal antibody

We present here an improved analytical method for the analysis of glycation events in proteins. Nonenzymatic glycation of an IgG2 monoclonal antibody was studied using affinity chromatography, mass spectrometry, and chemical derivatization. Analysis of both forced-degraded and bulk-drug substance (BDS) samples showed the presence of glycated protein. A new peptide mapping procedure, incorporating derivatization using sodium borohydride, allowed the development of a sensitive method for detecting and identifying the sites of modification. When combined with tandem mass spectrometry, peptides glycated by glucose showed dramatically improved MS/MS spectra as compared to underivatized controls. Using these methods we were able to map a number of glycation sites in both forced-degraded and BDS samples that were distributed across both light and heavy chain subdomains. The combination of affinity chromatography, high-resolution mass spectrometry, and a simple derivatization procedure should allow the facile analysis of glycation for other antibody and protein samples.     

Improved sensitivity and physical properties of sol-gel protein chips using large-scale material screening and selection

Protein chips are a powerful emerging technology with extensive biomedical applications. However, the development of optimal, economical surface materials capable of maintaining the activity of embedded proteins is a challenge. Here, we introduce a new optimized, low-cost, sol-gel biomaterial for use in protein chips with femtogram-level sensitivity. A novel protein chip material with significantly improved physical properties and sensitivity was produced using unique screening and selection methods. Using this platform, the sensitive, specific detection of the interactions between an HIV antigen and its antibody and between a cyclin-kinase protein pair was observed. This study is the first to demonstrate the detection of protein-protein interactions on sol-gel microarrays and describes an important improvement in the physical properties of sol-gel-derived protein chip materials for biomedical research.     

Acid-labile isotope-coded extractants: a class of reagents for quantitative mass spectrometric analysis of complex protein mixtures

Quantitative mass spectrometry using stable isotope-labeled tagging reagents such as isotope-coded affinity tags has emerged as a powerful tool for identification and relative quantitation of proteins in current proteomic studies. Here we describe an integrated approach using both automated two-dimensional liquid chromatography/ mass spectrometry (2D-LC/MS) and a novel class of chemically modified resins, termed acid-labile isotope-coded extractants (ALICE), for quantitative mass spectrometric analysis of protein mixtures. ALICE contains a thiol-reactive group that is used to capture all cysteine (Cys)-containing peptides from peptide mixtures, an acid-labile linker, and a nonbiological polymer. The acid-labile linker is synthesized in both heavy and light isotope-coded forms and therefore enables the direct relative quantitation of peptides/proteins through mass spectrometric analysis. To test the ALICE method for quantitative protein analysis, two model protein mixtures were fully reduced, alkylated, and digested in solution separately and then Cys-containing peptides covalently captured by either light or heavy ALICE. The reacted light and heavy ALICE were mixed and washed extensively under rigorous conditions and the Cys-containing peptides retrieved by mild acid-catalyzed elution. Finally, the eluted peptides were directly subjected to automated 2D-LC/MS for protein identification and LC/MS for accurate relative quantitation. Our initial study showed that quantitation of protein mixtures using ALICE was accurate. In addition, isolation of Cys-containing peptides by the ALICE method was robust and specific and thus yielded very low background in mass spectrometric studies. Overall, the use of ALICE provides improved dynamic range and sensitivity for quantitative mass spectrometric analysis of peptide or protein mixtures.     

BIA/MS of epitope-tagged peptides directly from E. coli lysate: multiplex detection and protein identification at low-femtomole to subfemtomole levels.

The use of biomolecular interaction analysis mass spectrometry to selectively isolate, detect, and characterize epitope-tagged peptides present in total cell lysates is demonstrated. Epitope-tagged tryptic peptides were captured via affinity interactions with either chelated Ni2+ or monoclonal antibodies and detected using surface plasmon resonance biomolecular interaction analysis (SPR-BIA). After SPR-BIA the tagged peptides were either eluted from the biosensor chips for mass spectrometric analysis or analyzed directly from the biosensor chip using matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF). Protein database searches were performed using the masses of the tagged tryptic peptides, resulting in identification of the protein into which the epitope tag was inserted. Detection limits for both SPR-BIA and MALDI-TOF were at the low-femtomole to subfemtomole level. The approach represents a (multiplexed) high-sensitivity chip-based technique capable of identifying epitope-tagged proteins as they are present in complex mixtures.     

UV fluorescence lifetime imaging microscopy: a label-free method for detection and quantification of protein interactions

Due to the ability to detect multiple parameters simultaneously, protein microarrays have found widespread applications from basic biological research to diagnosis of diseases. Generally, readout of protein microarrays is performed by fluorescence detection using either dye-labeled detector antibodies or direct labeling of the target proteins. We developed a method for the label-free detection and quantification of proteins based on time-gated, wide-field, camera-based UV fluorescence lifetime imaging microscopy to gain lifetime information from each pixel of a sensitive CCD camera. The method relies on differences in the native fluorescence lifetime of proteins and takes advantage of binding-induced lifetime changes for the unequivocal detection and quantification of target proteins. Since fitting of the fluorescence decay for every pixel in an image using a classical exponential decay model is time-consuming and unstable at very low fluorescence intensities, we used a new, very robust and fast alternative method to generate UV fluorescence lifetime images by calculating the average lifetime of the decay for each pixel in the image stack using a model-free average decay time algorithm.To validate the method, we demonstrate the detection and quantification of p53 antibodies, a tumor marker in cancer diagnosis. Using tryptophan-containing capture peptides, we achieved a detection sensitivity for monoclonal antibodies down to the picomolar concentration range. The obtained affinity constant, Ka, of (1.4 +/- 0.6) x 10(9) M(-1), represents a typical value for antigen/antibody binding and is in agreement with values determined by traditional binding assays.     

Identification of protein ubiquitylation by electrospray ionization tandem mass spectrometric analysis of sulfonated tryptic peptides

We report here the application of electrospray ionization tandem mass spectrometry for the characterization of protein ubiquitylation, an important posttranslational modification of cellular proteins. Trypsin digestion of ubiquitin-conjugated proteins produces diglycine branched peptides containing the modification sites. Chemical derivatization by N-terminal sulfonation was carried out on several model peptides for the formation of a characteristic fragmentation pattern in their MS/MS analysis. The fragmentation of derivatized singly charged peptides results in a product ion distribution similar to that already observed by MALDI-TOF MS/MS. Signature fragments distinguished the diglycine branched peptides from other modified and unmodified peptides, while the sequencing product ions reveal the amino acid sequence and the location of the ubiquitylation site. Doubly charged peptide derivatives fragment in a somewhat different manner, but several fragments characteristic to diglycine branched peptides were observed under low collision energy conditions. These signature peaks can also be used to identify peptides containing ubiquitylation sites. In addition, a marker ion corresponding to a glycine-modified lysine residue produced by high-energy fragmentation provides useful information for identity verification. The method is demonstrated by the analysis of three ubiquitin-conjugated proteins using LC/MS/MS.     

Chip-based analysis of protein-protein interactions by fluorescence detection and on-chip immunoprecipitation combined with microLC-MS/MS analysis

A new chip-based method to identify protein-protein interactions was developed using the guanine nucleotide exchange factor GRF2 and two interacting proteins, Ras and calmodulin, as model proteins. A generic immobilization strategy for FLAG-tagged bait proteins on a protein-repellent streptavidin chip surface was implemented by presentation of an oriented anti-FLAG antibody. A flow cell device, integrating different chip surfaces, was developed, and the interaction of immobilized GRF2 with the two analytes was verified by fluorescence assays. On-chip tryptic digest assays were then performed on the capture surface and analyzed by microLC-MS/MS. The interaction of GRF2 with calmodulin and Ras was demonstrated, and the lower limit of detection was determined. We also implemented an on-chip immunoprecipitation assay to identify GRF2-binding partners from complex protein mixtures. Cells overexpressing FLAG-GRF2 were lysed and then incubated with the anti-FLAG chip. In addition to detecting GRF2, we also identified calmodulin, demonstrating that this technique can successfully identify endogenous levels of proteins, bound to recombinant bait proteins. This chip-based method has the advantage that no subsequent gel separations of protein complexes prior to LC-MS analysis are required and is therefore amenable to miniaturized high-throughput determination of protein-protein interactions.     

Direct MALDI-MS/MS of phosphopeptides affinity-bound to immobilized metal ion affinity chromatography beads

Immobilized metal ion affinity chromatography (IMAC) is a useful method to selectively isolate and enrich phosphopeptides from a peptide mixture. Mass spectrometry is a very suitable method for exact molecular weight determination of IMAC-isolated phosphopeptides, due to its inherent high sensitivity. Even exact molecular weight determination, however, is not sufficient for identification of the phosphorylation site if more than one potential phosphorylation site is present on a peptide. The previous method of choice for sequencing the affinity-bound peptides was electrospray tandem mass spectrometry (ESI-MS/MS). This method required elution and salt removal prior to MS analysis of the peptides, which can lead to sample loss. Using a matrix-assisted laser desorption/ionization (MALDI) source coupled to an orthogonal injection quadrupole time-of-flight (QqTOF) mass spectrometer with true MS/MS capabilities, direct sequencing of IMAC-enriched peptides has been performed on IMAC beads applied directly to the MALDI target. The utility of this new method has been demonstrated on a protein with unknown phosphorylation sites, where direct MALDI-MS/MS of the tryptic peptides bound to the IMAC beads resulted in the identification of two novel phosphopeptides. Using this technique, the phosphorylation site determination is unambiguous, even with a peptide containing four potentially phosphorylated residues. Direct analysis of phosphorylated peptides on IMAC beads does not adversely affect the high-mass accuracy of an orthogonal injection QqTOF mass spectrometer, making it a suitable technique for phosphoproteomics.     

Performance of combinatorial peptide libraries in capturing the low-abundance proteome of red blood cells. 1. Behavior of mono- to hexapeptides

For a better understanding of the behavior of solid-phase combinatorial peptide ligands for capturing the red blood cell low-abundance soluble proteome, combinatorial peptides of different lengths from a single amino acid up to a hexapeptide were evaluated. A red blood cell lysate (6 g total protein) was loaded in a cascade fashion to the six columns, which were individually eluted with 8 M urea, 2% 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (v/w), and 50 mM citric acid. Each eluate was analyzed via sodium dodecyl sulfate polyacrylamide gel electrophoresis, two-dimensional maps, and nanoLC-MS/MS. The results: mixed beads with a single amino acid attached showed the capture of a non-negligible portion of the proteome. A progressive increasing of the length of the peptide bait enlarges the pool of captured proteins. Above a length of four amino acids, a plateau is progressively reached, suggesting that not much could be gained with baits longer than six amino acids. Interestingly, whereas the beads laden with a single amino acid seem to be able to capture large-size proteins (>40 kDa), beads with progressively longer peptides capture additional proteins in the smaller size range (10-50 kDa). This suggests that interactions already begin with a single amino acid, but selectivity requires baits of proper length, at least above four amino acids. Plain beads, with a spacer arm carrying a primary amino terminal group for anchoring the baits, are essentially unable to capture proteins, suggesting that the peptide baits do not act by a mechanism of ion exchange but rather via a complex mixed mode, yielding a specific capture.     

Recognition of dengue virus protein using epitope-mediated molecularly imprinted film

Molecularly imprinted film was fabricated in the presence of a pentadecapeptide onto a quartz crystal microbalance (QCM) chip. This 15-mer peptide has been known as the linear epitope of the dengue virus NS1 protein. Imprinting resulted in an increased polymer affinity toward the corresponding templates but also to the virus protein. Direct detection of the dengue virus protein was achieved quantitatively. The QCM chip response to the NS1 protein was obtained using epitope-mediated imprinting demonstrating a comparable frequency shift in chips immobilized with monoclonal antibodies. The binding effect was further enhanced and confirmed using a monoclonal antibody to form a sandwich with the MIP-NS1 protein complex on the chip. No pretreatment was required.     

Multiplexed protein analysis using encoded antibody-conjugated microbeads

We describe a method for multiplexed analysis of proteins using fluorescently encoded microbeads. The sensitivity of our method is comparable to the sensitivity obtained by enzyme-linked immunosorbent assay while only 5 µl sample volumes are needed. Streptavidin-coated, 1 µm beads are encoded with a combination of fluorophores at different intensity levels. As a proof of concept, we demonstrate that 27 microbead populations can be readily encoded by affinity conjugation using three intensity levels for each of three different biotinylated fluorescent dyes. Four populations of encoded microbeads are further conjugated with biotinylated capture antibodies and then combined and immobilized in a microfluidic flow cell for multiplexed protein analysis. Using four uniquely encoded microbead populations, we show that a cancer biomarker and three cytokine proteins can be analysed quantitatively in the picogram per millilitre range by fluorescence microscopy in a single assay. Our method will allow for the fabrication of high density, bead-based antibody arrays for multiplexed protein analysis using integrated microfluidic devices and automated sample processing.     

Measurements of the binding of a large protein using a substrate density-controlled DNA chip

The DNA chip that immobilizes DNA oligonucleotides on a solid plate surface is used for many diagnostic applications. For maximizing the detection sensitivity and accuracy, it is important to control the DNA density on a chip surface and establish a convenient method for optimizing the density. Here, the binding of DNA mismatch-binding protein MutS to the DNA substrate on the chip was investigated, which can be applied for high-throughput single-nucleotide polymorphism analysis in a genome. We prepared the DNA chips where the DNA substrate density was changed simply by using a mixed DNA solution. The binding of MutS was significantly influenced by the amount of DNA substrate on the chip as a consequence of steric crowding, and the moderate density that gave the distance between the DNA substrates greater than the size of the protein was appropriate to obtain accurate kinetic parameters. The substrate density-controlled DNA chip prepared using the mixed DNA solution has distinctive advantages for maximizing the detection capability and kinetic analysis of the binding of MutS and probably also other large proteins.     

Proteomic mapping of 4-hydroxynonenal protein modification sites by solid-phase hydrazide chemistry and mass spectrometry

The modification of proteins by the cytotoxic, reactive aldehyde 4-hydroxynonenal (HNE) is known to alter protein function and impair cellular mechanisms. In order to identify susceptible amino acid sites of HNE modification within complex biological mixtures by microcapillary liquid chromatography and linear ion trap tandem mass spectrometry, we have developed a solid-phase capture and release strategy that utilizes reversible hydrazide chemistry to enrich HNE-modified peptides. To maximize the detection of fragment ions diagnostic of HNE modification, both neutral loss-dependent acquisition of MS/MS/MS spectra and the pulsed Q dissociation operation mode were employed. When the solid-phase hydrazide enrichment strategy was applied to a yeast lysate treated with HNE, 125 distinct amino acid sites of HNE modification were mapped on 67 different proteins. The endogenous susceptibility of many of these proteins to HNE modification was demonstrated by analyzing HNE-treated yeast cell cultures with a complementary biotin hydrazide enrichment strategy. Further analysis revealed that the majority of amino acid sites susceptible to HNE modification were histidine residues, with most of these sites being flanked by basic amino acid residues, and predicted to be solvent exposed. These results demonstrate the effectiveness of this novel strategy as a general platform for proteome-scale identification of amino acid sites susceptible to HNE modification from within complex mixtures.     

Quantitative detection of protein arrays

We introduce a quantitative method that utilizes scanning electron microscopy for the analysis of protein chips (SEMPC). SEMPC is based upon counting target-coated gold particles interacting specifically with ligands or proteins arrayed on a derivative microscope glass slide by utilizing backscattering electron detection. As model systems, we quantified the interactions of biotin and streptavidin and of an antibody with its cognate hapten. Our method gives quantitative molecule-counting capabilities with an excellent signal-to-noise ratio and demonstrates a broad dynamic range while retaining easy sample preparation and realistic automation capability. Increased sensitivity and dynamic range are achieved in comparison to currently used array detection methods such as fluorescence, with no signal bleaching, affording high reproducibility and compatibility with miniaturization. Thus, our approach facilitates the determination of the absolute number of molecules bound to the chip rather than their relative amounts, as well as the use of smaller samples.     

Approach for determining protein ubiquitination sites by MALDI-TOF mass spectrometry

Protein ubiquitination plays an important role in the degradation and other functional regulation of cellular proteins in organisms ranging from yeasts to mammals. Trypsin digestion of ubiquitin conjugated proteins produces diglycine branched peptides in which the C-terminal Gly-Gly fragment of ubiquitin is attached to the epsilon-amino group of a modified lysine residue within the peptide. This provides a platform for mapping ubiquitination sites using mass spectrometry. Here we report the development of a novel strategy for determining posttraslational protein ubiquitination based on the N-terminal sulfonation of diglycine branched peptides. In contrast to conventional tandem MS spectra of native tryptic peptides, MALDI MS/MS analysis of a sulfonated tryptic peptide containing a diglycine branch generates a unique spectrum composed of a signature portion and a sequence portion. The signature portion of the spectrum consists of several intense ions resulting from the elimination of the tags, the N-terminal residues at the peptide and the branch, and their combination. This unique ion distribution pattern can distinguish ubiquitination modificatons from others and can identify the first N-terminal residues of the peptides as well. The sequence portion consists of an exclusive series of y-type ions and y' ions (differing by the loss of one glycine residue from the sulfonated diglycine branch) that can directly reveal the amino acid sequence of the peptide and the precise location of the ubiquitination site. The technique is demonstrated for a series of synthetic peptides and is validated by a model protein, tetraubiquitin. Our results show that the MALDI MS/MS analysis of sulfonated tryptic peptides can provide a highly effective method for the determination of ubiquitination substrates, ubiquitination sites on protein targets, and modification sites on ubiquitins themselves.     

Photoimmobilization of proteins for affinity capture combined with MALDI TOF MS analysis

Affinity capture surfaces can be prepared in a number of ways. A method of obtaining such surfaces through UV-activated immobilization of binding proteins using a benzophenone derivative is reported. Photoimmobilized protein G was used to selectively capture and preconcentrate bovine IgG from a mixture with BSA, and the affinity of photoattached concanavalin A toward ovalbumin was compared with that of commercially available concanavalin A on agarose beads. The results of the capture after tryptic digestion were analyzed by MALDI TOF MS. Immobilized trypsin was also prepared through photoimmobilization and later used to digest hemoglobin. Immobilized enzyme digestion resulted in more partial cleavages than solution-phase digestion. More methionine and tryptophan oxidation was also observed. Photoimmobilization was shown to be a quick and easy way of immobilizing ligands on surfaces.     

Identification and relative quantitation of protein mixtures by enzymatic digestion followed by capillary reversed-phase liquid chromatography-tandem mass spectrometry

In this report, we describe an approach for identification and relative quantitation of individual proteins within mixtures using LC/MS/MS analysis of protein digests. First, the proteins are automatically identified by correlating the tandem mass spectra with peptide sequences from a database. Then, peak areas of identified peptides from one protein are added together to define the total reconstructed peak area of the protein digest. The total reconstructed peak area is further normalized to the peak area of an internal standard protein digest present in the mixture at a constant level. The method was illustrated using digested mixtures of five standard proteins as follows. One protein was gradually diluted while the other four components were present in the mixtures at constant level. This study revealed that relative peak area of the variable protein increased linearly (trend line R2 = 0.9978) with increasing amount from 10 to 1000 fmol, while relative peak areas of four constant proteins remained approximately the same (within 20% relative standard deviation). To further evaluate the applicability of this method for the quantitation of proteins from complex mixtures, human plasma protein digest was spiked with 200 and 400 fmol of myoglobin digest. Total peak area of myoglobin peptides was normalized to the total peak area of apolipoprotein A-I peptides from human plasma, which played the role of an internal standard. The myoglobin/apolipoprotein A-I peak area ratio was 2 times larger for the human plasma digest spiked with a double amount of myoglobin. After several repetitions, the error of the relative peak area measurements remained below 11%, suggesting that the method described here can be used for relative concentration measurements of proteins in the complex biological mixtures. In the presented method, chemical derivatization steps are not needed to create an internal standard, as in isotope-coded affinity tag or similar methods.     

Mass spectrometry evidence for cisplatin as a protein cross-linking reagent

Cisplatin is a potent anticancer drug, which functions by cross-linking adjacent DNA guanine residues. However within 1 day of injection, 65-98% of the platinum in the blood plasma is protein-bound. It is generally accepted that cisplatin binds to methionine and histidine residues, but what is often underappreciated is that platinum from cisplatin has a 2+ charge and can form up to four bonds. Thus, it has the potential to function as a cross-linker. In this report, the cross-linking ability of cisplatin is demonstrated by Fourier transform ion cyclotron resonance (FTICR) mass spectrometry (MS) with the use of standard peptides, the 16.8 kDa protein calmodulin (CaM), but was unsuccessful for the 64 kDa protein hemoglobin. The high resolution and mass accuracy of FTICR MS along with the high degree of fragmentation of large peptides afforded by collisionally activated dissociation (CAD) and electron capture dissociation (ECD) are shown to be a valuable means of characterizing cross-linking sites. Cisplatin is different from current cross-linking reagents by targeting new functional groups, thioethers, and imidazoles groups, which provides complementarity with existing cross-linkers. In addition, platinum(II) inherently has two positive charges which enhance the detection of cross-linked products. Higher charge states not only promote the detection of cross-linking products with less purification but result in more comprehensive MS/MS fragmentation and can assist in the assignment of modification sites. Moreover, the unique isotopic pattern of platinum flags cross-linking products and modification sites by mass spectrometry.     

Size-dependent self-assembly of submicron/nano beads-protein conjugates for construction of a protein nanoarray

A protein nanoarray is created when submicro and nano beads, varying in their size and each conjugated with different proteins, self-assemble to specific locations depending on the diameter matching the surface electron beam patterns created. Protein binding is confirmed from the fluorescence attenuation of the beads upon antigen–antibody binding on the bead surface. This method, called size-dependent self-assembly, allows control of the location of each type of bead, and thus, control of the location of multiple proteins. It provides fast multi-component patterning with a high binding resolution, which can be detected using a fluorescent light microscope. This method is developed to be a simple stand-alone tool for analysis of protein interactions. In addition, it has the potential to be used in conjunction with other protein analysis methods, such as enzyme-linked immunosorbent assay (ELISA) and atomic force microscopy (AFM).     

Engineering functional protein interfaces for immunologically modified field effect transistor (ImmunoFET) by molecular genetic means

The attachment and interactions of analyte receptor biomolecules at solid-liquid interfaces are critical to development of hybrid biological-synthetic sensor devices across all size regimes. We use protein engineering approaches to engineer the sensing interface of biochemically modified field effect transistor sensors (BioFET). To date, we have deposited analyte receptor proteins on FET sensing channels by direct adsorption, used self-assembled monolayers to tether receptor proteins to planar FET SiO2 sensing gates and demonstrated interface biochemical function and electrical function of the corresponding sensors. We have also used phage display to identify short peptides that recognize thermally grown SiO2. Our interest in these peptides is as affinity domains that can be inserted as translational fusions into receptor proteins (antibody fragments or other molecules) to drive oriented interaction with FET sensing surfaces. We have also identified single-chain fragment variables (scFvs, antibody fragments) that recognize an analyte of interest as potential sensor receptors. In addition, we have developed a protein engineering technology (scanning circular permutagenesis) that allows us to alter protein topography to manipulate the position of functional domains of the protein relative to the BioFET sensing surface.