Electroblotting onto activated glass. High efficiency preparation of proteins from analytical sodium dodecyl sulfate-polyacrylamide gels for direct sequence analysis

We have developed a new method for the isolation of proteins for microsequencing. It consists of electrophoretic transfer (electroblotting) of proteins or their cleavage fragments onto activated glass filter paper sheets immediately after separation by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The proteins are immobilized on the glass fiber sheets by ionic interactions or by covalent attachment. A wide range of proteins can be prepared in this fashion with no apparent restriction due to solubility, size, charge, or other intrinsic properties of the proteins. As little as 50 ng of the transferred proteins can be detected using Coomassie Blue or fluorescent dye staining procedures and even smaller amounts of radiolabeled proteins by autoradiography. After detection, the protein-containing bands or spots are cut out and inserted directly into a gas-phase sequenator. The piece of glass fiber sheet acts as a support for the protein during the sequencing. Amounts of protein in the 5- to 150-pmol range can be sequenced, and extended runs can be obtained from the blotted samples because of improved stepwise yields and lower backgrounds. The method has been successfully applied to the sequencing of a variety of proteins and peptides isolated from one-dimensional and two-dimensional polyacrylamide gels.     

A facile method for the isolation and preparation of proteins and peptides for sequence analysis in the picomolar range

We report a new and facile extraction method of proteins and polypeptides in the range of 100 to 1 kDa previously separated by high-resolution SDS/polyacrylamide-gel electrophoresis. Proteins and polypeptides obtained by chemical or proteolytic cleavage of proteins can directly be applied to high-sensitivity N-terminal amino-acid sequence analysis by gas-phase sequencing. The Coomassie Blue-stained protein bands are eluted from the gel slices with 0.1 M sodium acetate buffer, pH 8.5, 0.1% SDS in high yield and directly applied to the filter disc of the gas-phase sequencer. The superior efficiency for the isolation of proteins and polypeptides from polyacrylamide gels for microsequencing has been documented by a quantitative comparison of the procedure described here and the favoured electroblot-transfer method using 14C-labeled marker proteins. This highly efficient isolation has been successfully reproduced and applied to the analysis of a variety of proteins and peptides with rather divergent physical properties, particularly to hydrophobic peptides isolated from SDS/polyacrylamide gels. The electrophoretic transfer onto activated glass filters. Immobilon membranes (polyvinylidene-difluoride membranes), siliconized or chemically activated glass fiber supports can be omitted. The method considerably simplifies and speeds up the isolation, and improves the sensitivity as compared to the electroblotting procedures due to the reproducibly high recoveries.     

High-sensitivity sequence analysis of peptides and proteins by 4-NN-dimethylaminoazobenzene 4''-isothiocyanate.

A manual high-sensitivity sequencing method is described, in which 4-NN-dimethylaminoazobenzene 4'-isothiocyanate is used for the stepwise degradation of amino acid residues from the peptides. The 4-NN-dimethylaminoazobenzene 4'-thiazolinones of amino acids that were released, after conversion into their thiohydantoin derivatives, were identified by t.l.c. on polyamide sheets. This new method is simple and sensitive, and requires only 2-10nmol of peptides or proteins for extended sequence analysis. The method was tested on the sequence analysis of a hexapeptide (Leu-Trp-Met-Arg-Phe-Ala), bradykinin, glucagon and native lysozyme. Results show that the proposed procedure is a sensitive method for the sequence determination of short peptides as well as for the partial sequence determination of intact proteins.     

Covalent immobilization of proteins for high-sensitivity sequence analysis: electroblotting onto chemically activated glass from sodium dodecyl sulfate-polyacrylamide gels

We report a new method for the preparation of proteins in a form suitable for high-sensitivity N-terminal amino acid sequence analysis. Proteins separated by polyacrylamide gel electrophoresis were electrophoretically transferred onto glass fiber filter paper chemically activated by the introduction of phenyl isothiocyanate functional groups. The proteins became covalently coupled to the matrix during the electrotransfer process. Bands containing transferred proteins were detected by fluorescent staining or autoradiography, cut out from the glass fiber filter, and directly loaded into the cartridge of a gas-phase sequenator. The covalent nature of the interactions between protein and glass fiber support permitted the use of more vigorous solid-phase sequencing protocols and of alternative sequencing reagents. This high-efficiency isolation and covalent coupling method provides the essential first step toward enhanced-sensitivity protein sequence analysis. The method has been successfully applied to the isolation of a wide variety of proteins from SDS-polyacrylamide gels, and was shown to be compatible with both the standard Edman reagent phenyl isothiocyanate and alternative sequencing reagents such as 4-(N,N'-dimethylamino)azobenzene-4'-isothiocyanate (DABITC).     

C-terminal sequence analysis of peptides using triphenylgermanyl isothiocyanate

The Schlack-Kumpf degradation, also called the isothiocyanate method, is thought to be a promising approach to chemical C-terminal sequencing of peptides and proteins. The derivatizing reagent is most crucial to this method. A new derivatizing reagent, triphenylgermanyl isothiocyanate (TPG-ITC), has been synthesized and applied to C-terminal peptide sequencing. The chemistry involves activation with acetic anhydride, derivatization with TPG-ITC, and cleavage of the derivatized C-terminal amino acid thiohydantoin with sodium hydroxide. A series of reaction conditions, including activation reagent volume, activation time, and derivatization temperature and time, have been investigated using a model peptide covalently attached to 1,4-phenylene diisothiocyanate (DITC)-glass beads. This procedure has been successfully used to sequence eight C-terminal residues of a model peptide at low nanomole levels. TPG-ITC is a white solid with relatively long shelf-life. According to our previous article (B. Mo, J. Li, and S. P. Liang, 1997, Anal. Biochem. 252, 169-176), TPG-ITC is a type II derivatizing reagent. Compared with acetyl isothiocyanate and trimethylsilyl isothiocyanate, TPG-ITC is much more stable and efficient for use in peptide C-terminal sequencing.     

Micro quantitative Edman manual sequencing

A manual Edman technique is described which allows sequential quantitative determination of from 3 to 10 amino terminal residues on quantities of peptides or proteins down to one nanomole. This is achieved by a fast, efficient method of obtaining the anilinothiazolinone or phenylthiohydantoin amino acid, and quantitating by either back hydrolysis and amino acid analysis or by a new, rapid, high resolution, quasi-isocratic, high-pressure liquid chromatographic procedure. The overall method has been extensively tested successfully on both peptides and proteins of known and unknown amino-terminal sequence and the results included here. In addition, a wide variety of applications relevant to primary structure analysis such as sequencing blocked polypeptides, use of denaturing agents as coupling buffers, reduction of protein or peptide losses on consecutive sequencing and peptide mixture analysis are all incorporated in the methodology outlined.     

Sequencing cyclic peptides by multistage mass spectrometry

Some of the most effective antibiotics (e.g. Vancomycin and Daptomycin) are cyclic peptides produced by non-ribosomal biosynthetic pathways. While hundreds of biomedically important cyclic peptides have been sequenced, the computational techniques for sequencing cyclic peptides are still in their infancy. Previous methods for sequencing peptide antibiotics and other cyclic peptides are based on Nuclear Magnetic Resonance spectroscopy, and require large amount (miligrams) of purified materials that, for most compounds, are not possible to obtain. Recently, development of MS-based methods has provided some hope for accurate sequencing of cyclic peptides using picograms of materials. In this paper we develop a method for sequencing of cyclic peptides by multistage MS, and show its advantages over single-stage MS. The method is tested on known and new cyclic peptides from Bacillus brevis, Dianthus superbus and Streptomyces griseus, as well as a new family of cyclic peptides produced by marine bacteria.     

Mass spectrometry of peptides and proteins

This tutorial article introduces mass spectrometry (MS) for peptide fragmentation and protein identification. The current approaches being used for protein identification include top-down and bottom-up sequencing. Top-down sequencing, a relatively new approach that involves fragmenting intact proteins directly, is briefly introduced. Bottom-up sequencing, a traditional approach that fragments peptides in the gas phase after protein digestion, is discussed in more detail. The most widely used ion activation and dissociation process, gas-phase collision-activated dissociation (CAD), is discussed from a practical point of view. Infrared multiphoton dissociation (IRMPD) and electron capture dissociation (ECD) are introduced as two alternative dissociation methods. For spectral interpretation, the common fragment ion types in peptide fragmentation and their structures are introduced; the influence of instrumental methods on the fragmentation pathways and final spectra are discussed. A discussion is also provided on the complications in sample preparation for MS analysis. The final section of this article provides a brief review of recent research efforts on different algorithmic approaches being developed to improve protein identification searches.     

Detection of amino-terminal tryptophan in peptides and proteins using dansyl chloride

A sensitive method is described for the detection of amino-terminal tryptophan in peptides and proteins as the dansyl derivative. The use of the method is illustrated with a tetrapeptide and with the enzyme phospholipase C from Bacillus cereus. The method may also be applicable when internal tryptophanyl residues are encountered during dansyl-Edman manual sequencing of peptides and proteins.     

Solid-phase sequence analysis of polypeptides eluted from polyacrylamide gels. An aid to interpretation of DNA sequences exemplified by the Escherichia coli unc operon and bacteriophage lambda

An approach to sequencing proteins by the solid-phase method combined with isolation of proteins and polypeptides by gel electrophoresis is described. Mixtures of proteins or polypeptides resulting from digests are fractionated in the presence of dodecylsulphate in polyacrylamide gels. They are detected with Coomassie blue, eluted, selectively reacted with porous glass derivatives and sequenced in their amino-terminal regions with the aid of a new microsequencer. Alternatively they can be analysed or digested with enzymes and fingerprinted. It is a relatively rapid method of purifying proteins for sequence analysis which we have used to provide partial protein sequence data to complement DNA sequences. Nine genes, four from the unc operon of Escherichia coli encoding the alpha, beta, gamma and epsilon subunits of ATP synthase and five for capsid proteins of bacteriophage lambda, have been identified by this method.     

Sensitization of amino acid derivatives obtained from Edman degradation with radioactively-labeled iodohistamine

The minimum amount of proteins and peptides required for sequencing is constantly decreasing as more sensitive microsequencing methods are developed. The sensitization of and Edman degradation product is one such method. We took the 2-anilino 5-thiazolinone amino acid intermediates obtained from Edman degradation by conventional sequencing procedures, and quantitatively reacted them with a primary amine. The amine used was radioactive [125I]iodohistamine, which affords highly sensitive detection. The labeled amino acid derivatives were separated by thin layer chromatography. Ten femtomoles of a labeled derivative can be detected by autoradiography.     

Covalent immobilization of proteins and peptides for solid-phase sequencing using prepacked capillary columns

The use of prepacked capillary columns for immobilizing proteins and peptides for solid-phase Edman degradation is described. Capillary tubes with an internal volume of about 30 microliters are filled with glass beads bearing isothiocyanato groups (DITC-glass), aminophenyl groups (AP-glass), or aminoethylaminopropyl groups (AEAP-glass) and are sealed with porous plugs. Proteins or peptides in appropriate buffers are introduced into the columns by capillary action and are covalently coupled to the glass beads, either by reaction of lysine side-chain amino groups with DITC-glass, by carbodi-imide-mediated reaction of carboxyl groups with AP-glass, or by reaction of homoserine lactone groups with AEAP-glass. Optimization of attachment conditions is described. The capillary columns are loaded into the sequencer and, when sequencing has been completed, are discarded. This technique greatly simplifies polypeptide immobilization and is suitable for microsequencing (less than 50-1000 pmol) or macrosequencing (1-50 nmol).     

蛋白质及多肽的C端分析

本文采用（异）硫氰酸化学法,以乙酸酐为活化试剂,四丁铵硫氰酸为偶联试剂,溴甲基萘为烷化试剂,将蛋白质或多肽的Ｃ端依次转化并裂解为ＡＴＨ－氨基酸,在２５４ｎｍ进行检测。分析了若干种天然的、基因工程表达的蛋白质或多肽,测定了不同长度的Ｃ端序列,并确证了Ｃ端的修饰及突变情况。为蛋白质和多肽的完整性、均一性,基因工程产品及合成多肽的质控提供了重要的Ｃ端信息。目前,可在１￣２ｎｍｏｌ水平上测定了３￣５个Ｃ端     

Straightforward ladder sequencing of peptides using a Lys-N metalloendopeptidase

We introduce a method for sequencing peptides by mass spectrometry using a metalloendopeptidase that cleaves proteins at the amino side of lysine (Lys-N). When analyzed by electron transfer dissociation (ETD)-based mass spectrometric sequencing, Lys-N-digested peptides that contain a single lysine residue produce spectra dominated by c-type fragment ions, providing simple ladders for sequence determination. This method should be a valuable strategy for de novo sequencing and the analysis of post-translational modifications.     

Shotgun protein sequencing: assembly of peptide tandem mass spectra from mixtures of modified proteins

Despite significant advances in the identification of known proteins, the analysis of unknown proteins by MS/MS still remains a challenging open problem. Although Klaus Biemann recognized the potential of MS/MS for sequencing of unknown proteins in the 1980s, low throughput Edman degradation followed by cloning still remains the main method to sequence unknown proteins. The automated interpretation of MS/MS spectra has been limited by a focus on individual spectra and has not capitalized on the information contained in spectra of overlapping peptides. Indeed the powerful shotgun DNA sequencing strategies have not been extended to automated protein sequencing. We demonstrate, for the first time, the feasibility of automated shotgun protein sequencing of protein mixtures by utilizing MS/MS spectra of overlapping and possibly modified peptides generated via multiple proteases of different specificities. We validate this approach by generating highly accurate de novo reconstructions of multiple regions of various proteins in western diamondback rattlesnake venom. We further argue that shotgun protein sequencing has the potential to overcome the limitations of current protein sequencing approaches and thus catalyze the otherwise impractical applications of proteomics methodologies in studies of unknown proteins.     

A simple and highly successful C-terminal sequence analysis of proteins by mass spectrometry

A simple and efficient method for C-terminal sequencing of proteins has long been pursued because it would provide substantial information for identifying the covalent structure, including post-translational modifications. However, there are still significant impediments to both direct sequencing from C termini of proteins and specific isolation of C-terminal peptides from proteins. We describe here a highly successful, de novo C-terminal sequencing method of proteins by employing succinimidyloxycarbonylmethyl tris (2,4,6-trimethoxyphenyl) phosphonium bromide and mass spectrometry.     

A rapid method of sequencing long synthetic peptide sequences by laser power variation in MALDI-ToF, using polyglutamine model peptides

Matrix assisted laser desorption ionization-time of flight (MALDI-ToF) has evolved into a powerful method for structural analysis of biomolecules. The paper reports a very simple and efficient method of sequencing of long peptides using long polyglutamine stretches with and without interruptions as model peptides, using MALDI-ToF in a linear mode. The method does not require any enzymatic or proteolytic digestions and very long synthetic polyglutamine sequences can be sequenced efficiently just by incremental variation of laser power. The data also reveal whenever there is any interruption within a stretch of glutamines it undergoes a very prompt cleavage at that site. Thus, this method provides an alternative tool for validating long polyglutamine stretches which are very often used as models for studying the structure and conformation of proteins associated with a number of neurodegenerative disorders.     

Accurate mass tag retention time database for urine proteome analysis by chromatography-mass spectrometry

Information about peptides and proteins in urine can be used to search for biomarkers of early stages of various diseases. The main technology currently used for identification of peptides and proteins is tandem mass spectrometry, in which peptides are identified by mass spectra of their fragmentation products. However, the presence of the fragmentation stage decreases sensitivity of analysis and increases its duration. We have developed a method for identification of human urinary proteins and peptides. This method based on the accurate mass and time tag (AMT) method does not use tandem mass spectrometry. The database of AMT tags containing more than 1381 AMT tags of peptides has been constructed. The software for database filling with AMT tags, normalizing the chromatograms, database application for identification of proteins and peptides, and their quantitative estimation has been developed. The new procedures for peptide identification by tandem mass spectra and the AMT tag database are proposed. The paper also lists novel proteins that have been identified in human urine for the first time.     

Sequencing of peptides and proteins from the carboxy terminus.

A new chemical method for carboxy-terminal (C-terminal) protein sequencing has been developed. This approach has been successfully used to sequence 5 residues of standard proteins and 5 to 10 residues of synthetic peptides at low nanomole levels. The sequencing procedure consists of converting the C-terminal amino acid into a thiohydantoin (TH) derivative, followed by transformation of the TH into a good leaving group by alkylation. Next, the alkylated TH is cleaved mildly and efficiently with (N = C V S)- anion, which simultaneously forms a TH on the newly truncated protein or peptide. Thus, after the initial TH derivatization, there is no return to a free carboxyl group at the C-terminus. An additional benefit of this method is that the alkylating moiety can be chosen with a variety of properties allowing for variation in the detection method. This chemistry has been adapted to automated protein sequencers with a cycle time of about 1 h.     

Stability of tyrosine sulfate in acidic solutions

Tyrosine O-sulfation is a posttranslational modification of secretory and membrane proteins transported through the Golgi apparatus, which is widespread among higher eukaryotes. O-Sulfated tyrosines are not immediately identified during sequencing of peptides and proteins, because the sulfate ester is acid labile and rapidly hydrolyses to tyrosine in strong acidic solutions. Little is known about the hydrolysis at mildly acidic solutions, which are used during several protein purification and analysis procedures. We have examined the stability of tyrosine sulfate using sulfated gastrin-17, caerulein, and drosulfokinin as models for tyrosine O-sulfated peptides. The peptides were incubated in acidic solutions in a pH range of 1 to 3 at different temperatures and time spans. Only marginal hydrolysis of gastrin-17 was observed in triflouroacetic acid at room temperature or below. Comparison of the acid hydrolysis of the three peptides showed that hydrolysis rate depends mainly on the primary amino acid composition of the peptide. The activation energy (E(a)) for the hydrolysis of sulfated gastrin-17 was found to be E(a)=98.7+/-5 kJ mol(-1). This study serves as a general reference for handling tyrosine sulfated peptides in aqueous acidic solutions. We conclude that tyrosine sulfate is more stable under normal protein purification conditions than previously assumed.