Internal amino acid sequencing of proteins by in situ cyanogen bromide cleavage in polyacrylamide gels

Nitrate reductases in Hydrogenobacter thermophilus with evolutionarily ancient features: distinctive localization and electron transfer

Dissimilatory nitrate reductase (NAR) and assimilatory nitrate reductase (NAS) serve as key enzymes for nitrogen catabolism and anabolism in many organisms. We purified NAR and NAS from H. thermophilus, a hydrogen-oxidizing chemolithoautotroph belonging to the phylogenetically deepest branch in the Bacteria domain. Physiological contribution of these enzymes to nitrate respiration and assimilation was clarified by transcriptomic analysis and gene disruption experiments. These enzymes showed several features unreported in bacteria, such as the periplasmic orientation of NAR anchored with a putative transmembrane subunit and the specific electron transfer from a [4Fe-4S]-type ferredoxin to NAS. While some of their enzymatic properties are shared with NARs from archaea and with NASs from phototrophs, phylogenetic analysis indicated that H. thermophilus NAR and NAS have deep evolutionary origins that cannot be explained by a recent horizontal gene transfer event from archaea and phototrophs. These findings revealed the diversity of NAR and NAS in nonphotosynthetic bacteria, and they also implied that the outward orientation of NAR and the ferredoxin-dependent electron transfer of NAS are evolutionarily ancient features preserved in H. thermophilus.

Database-independent Protein Sequencing (DiPS) Enables Full-length de Novo Protein and Antibody Sequence Determination

Traditional "bottom-up" proteomic approaches use proteolytic digestion, LC-MS/MS, and database searching to elucidate peptide identities and their parent proteins. Protein sequences absent from the database cannot be identified, and even if present in the database, complete sequence coverage is rarely achieved even for the most abundant proteins in the sample. Thus, sequencing of unknown proteins such as antibodies or constituents of metaproteomes remains a challenging problem. To date, there is no available method for full-length protein sequencing, independent of a reference database, in high throughput. Here, we present Database-independent Protein Sequencing, a method for unambiguous, rapid, database-independent, full-length protein sequencing. The method is a novel combination of non-enzymatic, semi-random cleavage of the protein, LC-MS/MS analysis, peptide de novo sequencing, extraction of peptide tags, and their assembly into a consensus sequence using an algorithm named "Peptide Tag Assembler." As proof-of-concept, the method was applied to samples of three known proteins representing three size classes and to a previously un-sequenced, clinically relevant monoclonal antibody. Excluding leucine/isoleucine and glutamic acid/deamidated glutamine ambiguities, end-to-end full-length de novo sequencing was achieved with 99-100% accuracy for all benchmarking proteins and the antibody light chain. Accuracy of the sequenced antibody heavy chain, including the entire variable region, was also 100%, but there was a 23-residue gap in the constant region sequence.

Enzymatic digestion of proteins in gels for mass spectrometric identification and structural analysis

Enzymatic digestion of proteins is a key technique used in protein identification. By combining the digestion with mass spectrometric detection, proteins at very low femtomole levels, and in some cases subfemtomole levels, can be identified. Typically, one- or two-dimensional SDS-PAGE is used to isolate the proteins of interest, followed by staining with Coomassie blue, digestion-compatible silver stain, or Sypro Ruby for detection. Two-dimensional (2-D) fluorescence difference gel electrophoresis (DIGE), which uses Cy3 and Cy5 dyes for detection, allows comparison of two different sample states in order to locate proteins that are up- or down-regulated. In each case, an in-gel digestion, usually tryptic, is used with mass spectrometry to identify these proteins of interest. For large numbers of gel spots, robotic digestion can save time and money.

Separation and characterization of basic barley seed proteins

Basic proteins in barley starchy endosperm from developing seeds were separated by two-dimensional (2-D) nonequilibrium pH gel electrophoresis. Total as well as partial extracts were analyzed. Edman degradation sequencing and immunological detection were performed after transfer of separated proteins onto membranes. Only one protein could be analyzed by N-terminal sequencing of blotted and separated proteins from the total extract. Fractionation of extracts was done using cation exchange chromatography, concanavalin A and heparin affinity chromatography. Internal sequences were determined after in-gel cleavage of proteins using trypsin or cyanogen bromide and separation of the fragments by reversed-phase chromatography or in a gel electrophoresis system for peptide separation. This resulted in a new protocol for obtaining internal sequences from proteins separated by 2-D electrophoresis. A total of 16 sequences, including nine internal sequences, were analyzed, permitting the identification of ten proteins, including five that appeared to have a blocked N-terminus. An additional protein was identified using immunological detection. Three protein sequences remained unidentified. Separated proteins were also analyzed with a glycan detection method.

Capsaicin-responsive NADH oxidase activities from urine of cancer patients

NADH oxidases of low specific activities from urine of cancer patients were found to be inhibited or stimulated by the vanilloid capsaicin (8-methyl-N-vanillyl-6-noneamide). Similar activities, inhibited or stimulated by capsaicin, were reported previously for sera of cancer patients but not for sera of normal volunteers or for patients with disorders other than cancer. Like those from sera, the activities from urine were resistant to heat and to digestion with proteinase K. Two different fractions with capsaicin-responsive NADH oxidase activities were obtained by FPLC. One fraction in which the 33-kDa band was the major component exhibited NADH oxidase activity stimulated by capsaicin. Another fraction in which 66-kDa and 45-kDa bands were major components exhibited NADH oxidase activities inhibited by capsaicin. A monoclonal antibody generated to a ca 34-kDa form of the NADH oxidase from sera reacted with a urine protein of a ca 33-kDa band in the capsaicin-stimulated fraction. The 33-kDa protein was of low abundance and was estimated to be present in amounts between 5 and 100 microgram/L, depending on the particular patient.

AP30, a differential protein marker for perilymph and cerebrospinal fluid in middle ear fluid, has been purified and identified as human apolipoprotein D

Using two-dimensional (2-D) gel electrophoresis, human perilymph and cerebrospinal fluid have been shown to be highly enriched for an acidic protein with MR 30,000, we designated it as AP30. The protein exhibits charge heterogeneity, with at least eight isoforms visible between pI 4.5 to 5.5 on 2-D gels. Purification of the protein was carried out by ammonium sulfate precipitation, polybuffer exchanger column chromatofocusing, and acetone fractional precipitation. The resulting preparation also contains eight spots in the acidic area of 2-D gels, and one broad band located at Mr 30,000 by SDS-PAGE. Digestion of AP30 with neuraminidase causes the isoforms to shift to a more basic position and to consolidate into two primary spots, indicating that AP30 is a variably sialylated glycoprotein. Amino acid analysis of AP30 revealed an amino acid content very similar to that of human apolipoprotein D. Attempts to determine the amino acid sequence demonstrated that the N-terminus is blocked. Edman sequencing of two peptide fragments, generated by cyanogen bromide cleavage of AP30, both revealed sequences having 100% identity to human apolipoprotein D. Western blot analysis of AP30 with the antibody against authentic human apolipoprotein D demonstrated a high degree of cross-reactivity. These studies indicate that AP30 from human perilymph and cerebrospinal fluid is a member of the apolipoprotein D family.

Sensitivity and mass accuracy for proteins analyzed directly from polyacrylamide gels: implications for proteome mapping

Matrix-assisted laser desorption ionization (MALDI) mass spectra have been obtained directly from thin-layer isoelectric focusing (IEF) gels with as little as 700 femtomoles of alpha- and beta-chain bovine hemoglobin and bovine carbonic anhydrase, and 2 picomoles of bovine trypsinogen, soybean trypsin inhibitor, and bovine serum albumin all loaded onto a single lane. By soaking the gel in a matrix solution, matrix was deposited over the entire gel surface, allowing MALDI scanning down complete lanes of the one-dimensional gel. As long as matrix crystals were deposited finely on the surface of the gel, time-lag focusing techniques were capable of ameliorating some of the mass accuracy limitations inherent in desorbing from uneven insulator surfaces with external calibration. Eleven measurements on the 5 kDa alpha-subunit proteins of lentil lectin measured over the course of 1 h and referenced to a single calibration yielded a standard deviation of 0.025%. Colloidal gold staining was found to be compatible with desorption directly from IEF and sodium dodecyl sulfate (SDS)-polyacrylamide gels. This direct approach simplifies the interface between gel electrophoresis and mass spectrometry dramatically, making the process more amenable to automation.

S-pyridylethylation of intact polyacrylamide gels and in situ digestion of electrophoretically separated proteins: a rapid mass spectrometric method for identifying cysteine-containing peptides

In-gel proteolytic digestion of acrylamide-gel separated proteins is a method widely used for generating peptide fragments for the purpose of identifying proteins by Edman degratation, tandem mass spectrometry, and peptide-mass fingerprinting. However, it is well recognised for disulfide-bonded proteins electrophoresed under reducing conditions that if no precautions are taken to minimise disulfide bond formation during protein digestion or peptide isolation, complex peptide maps can result. Here, we describe an improved method for in-gel protein digestion. It consists of first reducing and S-pyridylethylating Coomassie Brilliant Blue R-250-stained proteins immobilised in the whole gel slab with dithiothreitol and 4-vinylpyridine, excising the individual stained and alkylated proteins, and then digesting them in situ in the gel matrix with trypsin or Achromobacter lyticus protease I. Peptide fragments generated in this manner are extracted from the gel piece and purified to homogeneity by a rapid (< or = 12 min) reversed-phase high performance liquid chromatography (HPLC) procedure, based upon conventional silica supports. Recoveries of peptides are increased by S-pyridylethylation of acrylamide-immobilised proteins prior to in-gel digestion. Further, the levels of gel-related contaminants, which otherwise result in suppression of sample signals during electrosprayionisation mass spectrometry, are greatly reduced by the reduction/alkylation step. Additionally, we demonstrate that S-beta-(4-pyridylethyl)-cysteine containing peptides can be readily identified during reversed-phase HPLC by absorbance at 254 nm, and during electrospray ionisation tandem mass spectrometry by the appearance of a characteristic-pyridylethyl fragment ion of 106 Da. The position of cysteine residues in a sequence can be determined as phenylthiohydantoin S-beta-(4-pyridylethyl)-cysteine during Edman degradation, and by tandem mass spectrometry.

Two-dimensional electrophoresis of proteins: an updated protocol and implications for a functional analysis of the genome

The two-dimensional electrophoresis (2-DE) technique developed by Klose in 1975 (Humangenetik 1975, 26, 211-234), independently of the technique developed by O'Farrell (J. Biol. Chem. 1975, 250, 4007-4021), has been revised in our laboratory and an updated protocol is presented. This protocol is the result of our experience in using this method since its introduction. Many modifications and suggestions found in the literature were also tested and then integrated into our original method if advantageous. Gel and buffer composition, size of gels, use of stacking gels or not, necessity of isoelectric focusing (IEF) gel incubation, freezing of IEF gels or immediate use, carrier ampholytes versus Immobilines, regulation of electric current, conditions for staining and drying the gels - these and other problems were the subject of our concern. Among the technical details and special equipment which constitute our 2-DE method presented here, a few features are of particular significance: (i) sample loading onto the acid side of the IEF gel with the result that both acidic and basic proteins are well resolved in the same gel; (ii) use of large (46 x 30 cm) gels to achieve high resolution, but without the need of unusually large, flat gel equipment; (iii) preparation of ready-made gel solutions which can be stored frozen, a prerequisite, among others, for high reproducibility. Using the 2-DE method described we demonstrate that protein patterns revealing more than 10 000 polypeptide spots can be obtained from mouse tissues. This is by far the highest resolution so far reported in the literature for 2-DE of complex protein mixtures. The 2-DE patterns were of high quality with regard to spot shape and background. The reproducibility of the protein patterns is demonstrated and shown to be thoroughly satisfactory. An example is given to show how effectively 2-DE of high resolution and reproducibility can be used to study the genetic variability of proteins in an interspecific mouse backcross (Mus musculus x Mus spretus) established by the European Backcross Collaborative Group for mapping the mouse genome. We outline our opinion that the structural analysis of the human genome, currently pursued most intensively on a worldwide scale, should be accompanied by a functional analysis of the genome that starts from the proteins of the organism.

Characterization of FP21, a cytosolic glycoprotein from Dictyostelium

FP21 is a glycoprotein which, when tracked by radioactivity in its fucosyl moiety, was previously detected in the cytosol of Dictyostelium cells after cell fractionation. This compartmentalization is confirmed by SDS-polyacrylamide gel electrophoresis/Western blotting of cell fractions using three different antibodies. Although a substantial fraction of FP21 is also detected in the particulate fraction using these new antibodies, particulate FP21 is released by disrupting protein-protein interactions, but not membrane disruption. Since purified FP21 is susceptible to aggregation, and purified nuclei do not contain FP21, particulate FP21 is also part of the cytosol. Additional compositional and structural information provides strong evidence that FP21 does not at any time traverse the rough endoplasmic reticulum. First, cDNAs spanning the entire coding region of the FP21 gene predict no hydrophobic motifs expected to promote membrane insertion, but do predict an NH2-terminal coiled coil domain which could explain aggregation. Second, monosaccharide composition analysis of the predominant glycoform of FP21 yields 2 mol of galactose, 1 mol of xylose, and 1 mol of fucose/mol of polypeptide; FP21 from a fucosylation-defective mutant contains 1 additional mol of xylose in place of fucose. Thus the N-glycosylation sequon present in FP21 is not utilized by oligosaccharyl transferase, which resides in the rough endoplasmic reticulum. These findings indicate that nascent FP21 remains in the cytosol after synthesis and is therefore glycosylated by unusual cytosolic xylosyl-, galactosyl-, and fucosyltransferases.

A preparative method for sequencing proteins and peptides: in situ gel staining with subsequent passive elution onto polyvinylidine difluoride membranes

A preparative method for obtaining both N-terminal and internal peptide amino acid sequences from purified proteins is reported. The methodology reliably yields high fidelity signal from between 14 to 30 residues per purified protein or peptide, with low backgrounds on amino acid analysis. The procedure relies on the use of in situ staining of proteins during preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), and the utilisation of microconcentrators to repeatedly concentrate small amounts of proteins onto a small polyvinylidene difluoride (PVDF) disc until sufficient amounts have been adsorbed so as to give a strong sequencing signal. The protein elution and subsequent adsorption can be monitored visually with a dye and the final product, a PVDF disc with the adsorbed protein or peptide, can be directly inserted into the automated amino acid sequencer.

Ubiquitin C-terminal hydrolase as a putative factor involved in sex differentiation of fish (temperate wrasse, Halichoeres poecilopterus)

Temperate wrasse (Halichoeres poecilopterus) is known to undergo sex transition from female to male (protogyny). In order to detect factors related to male sex differentiation which appear during sex transition, we compared protein constituents between transitional and mature gonads by two-dimensional gel electrophoresis. Eight proteins were found to increase in amount considerably in the transitional gonads in comparison with the counterparts in ovaries. Five of the eight proteins were also found in mature testes. One of the proteins shared by testes and transitional gonads had an isoelectric point at pH 5.3 and an apparent molecular weight of 26 kDa. Thus we termed the protein p 26. It was abundant in degenerating ovary, transitional gonad, and mature testis and less abundant in mature ovary and brain. Therefore, the expression of p 26 seemed to start during sex transition and continue during maturation of the testis. Amino acid sequence analysis revealed high homology of p 26 to ubiquitin C-terminal hydrolase, which is supposed to cleave ubiquitin associated with nuclear proteins and a transcriptional repressor. Therefore, p 26 was supposed to regulate gene expression through the mediation of ubiquitin. Proteins which seemed to be counterparts of p 26 were detected in testes of two other fish species by an antiserum against p 26. These results suggest that p 26 is a possible candidate for the factor which is related to sex differentiation.

Strategies for internal amino acid sequence analysis of proteins separated by polyacrylamide gel electrophoresis

An evaluation has been made of various strategies for obtaining internal amino acid sequence data from electrophoretically separated proteins. Electroblotting, in situ proteolysis and extraction, and direct electroelution are compared. Electroblotting of protein or peptides from gels resulted in poor yields (typically, 1-7%). However, higher yields (3-67%) were achieved by in situ enzymatic cleavage followed by acid extraction of the peptides from the gel. Peptides extracted from the gel were separated by reversed-phase high-performance liquid chromatography (RP-HPLC), on short, small-bore columns (100 x 2.1 mm I.D.), to enable recovery of peptides in small volumes (ca. 50 microliters) suitable for microsequence analysis. Capillary zone electrophoresis under acidic conditions (pH 2.5) was used to assess peptide purity before sequence analysis. Cysteine residues were identified in unmodified proteins or peptides by a characteristic phenylthiohydantoin (PTH)-amino acid derivative during sequence analysis. This derivative does not co-chromatograph with any known PTH-amino acid. Direct electrophoretic elution of protein from gels yielded between 45-50% of applied protein. Proteins recovered from gels by electrophoretic elution required further purification by inverse-gradient RP-HPLC [R. J. Simpson, R. L. Moritz, E. C. Nice and B. Grego, Eur. J. Biochem., 165 (1987) 21] to remove sodium dodecylsulphate and acrylamide-related contaminants for sequence analysis.

Development of a database of amino acid sequences for human colon carcinoma proteins separated by two-dimensional polyacrylamide gel electrophoresis

The tandem use of preparative two-dimensional polyacrylamide gel electrophoresis (2-DE) and electroblotting onto polyvinylidene difluoride membranes has been employed to rapidly isolate a number of proteins from a crude cell extract of a human colon carcinoma cell line (LIM 1863). The immobilized proteins were located by staining with Coomassie Brilliant Blue R-250, and selected protein spots were excised and subjected to Edman degradation. Our results demonstrate that overall sequence yields in the 3-20 pmol range can be achieved on protein spots from four identical 2-DE gels; approximately 150-200 micrograms of total protein was applied to a single 2-DE gel. An approximate two-fold increase in sensitivity of phenylthiohydantoin-amino acid detection (subpicomole range) was achieved by fitting our commercial sequencers with a simple sample transfer device which permitted the analysis of the total phenylthiohydantoin-amino acid derivative. N-Terminal amino acid sequence data was obtained for thirteen electroblotted proteins. All of these sequences positively matched those of proteins of known structure listed in the available protein sequence databases. Approximately 40% of the electroblotted proteins did not yield N-terminal sequence information, presumably because they had blocked N-termini (either naturally or artifactually). Internal amino acid sequence information was obtained from three proteins isolated by preparative 2-DE. This was achieved by in situ digestion of the proteins in the gel matrix with Staphylococcus aureus V8 protease, electrophoresis of the generated peptides in a one-dimensional gel, electrotransfer of the peptides to a polyvinylidene difluoride membrane and microsequence analysis of the electroblotted peptides.

Combination of two-dimensional gel electrophoresis with microsequencing and amino acid composition analysis: improvement of speed and sensitivity in protein characterization

High-resolution two-dimensional polyacrylamide electrophoresis (2-DE) is commonly used as an analytical approach to resolve and detect most of the numerous protein species of an organism. However, the isolation of microgram amounts of protein in a 2-DE spot in a form suitable for microsequence analysis and amino acid composition analysis is a key step in the chemical characterization of these proteins. With the development of chemically inert membranes it is now possible to retain proteins present in low quantities from the polyacrylamide matrix with high yields. The immobilized proteins are suitable for direct sequence analysis and amino acid composition analysis. The combination of protein chemical and electrophoretic techniques makes it possible to obtain chemical information from subpicomole quantities of protein, resulting in the availability of a new set of biologically important proteins for structural analysis. This paper summarizes the methods and strategies for the chemical protein analysis of 2-DE spots in our laboratory.