Fluorescence detection of amino acids in the postcleavage conversions for manual sequencing of a peptide

A modified Edman degradation method where fluorescent derivatives of amino acids were generated from the postcleavage products of a peptide is described. In the method, the target peptide was applied onto double glass fiber membranes in a small filter disk (4 mm i.d.) and then treated with small amounts of reagents for the manual sequencing of the peptide. The anilinothiazolinone (ATZ) of N-terminus amino acid residue after the isolation from the solid-phase membranes was reacted with a primary amine, 4-(1′-cyanoisoindolyl)aniline (CIA), to form a more stable and sensitive fluorescent derivative, phenylthiocarbamoyl-CIA. An average yield of 85% was obtained in neutral pH conditions for the CIA reaction. The ATZ-CIA-amino acids were separated by reversed-phase liquid chromatography and detected by fluorometry. The lower limits of the detection for amino acids after the Edman degradation were 0.16 to 0.52 pmol (signal/noise ratio = 3) on the column. The sensitivity was approximately 10 times higher than ultraviolet absorbance detection of phenylthiohydantoin products in the conventional Edman degradation. The suitability of the method was demonstrated by the sensitive manual sequencing of insulin chain B composed of 30 amino acids.     

A method for the unambiguous identification of tryptophan in automated protein sequence analysis

Some widely used standard protocols for the separation of phenylthiohydantoin amino acid derivatives by reverse-phase gradient HPLC do not provide separation of the phenylthiohydantoin derivative of tryptophan (PTH-Trp) from diphenylurea (DPU), a by-product generated during Edman degradation of proteins in variable amounts. Furthermore, PTH-Trp is usually recovered in low yield under typical experimental conditions used with automated sequencing equipment. These factors may compromise the unambiguous assignment of tryptophan residues in automated protein sequence analysis, especially when sequencing is performed at high sensitivity. We devised a reverse-phase HPLC method which allows the separation of DPU and PTH-Trp and therefore the correct assignment of PTH-Trp. The method is based on a modification of the HPLC gradient used to elute and separate all PTH amino acids of interest. With Applied Biosystems Model 477A protein sequencers with on-line PTH amino acid identification, the correct assignment of tryptophan was consistent and reproducible even when sequencing at very high sensitivity (5 pmol).     

A fast and sensitive micromethod for the manual sequencing of peptides using O-phthalaldehyde as derivatizing reagent

A general procedure for the manual sequencing of peptides using the fluorogenic reagent O-phthalaldehyde (OPA) is described. The method can be applied in two different ways. One of them involves back hydrolysis of the anilinothiazolinones resulting from the Edman degradation of the peptide and subsequent detection of the free amino acids as OPA derivatives. The other is a subtractive analysis in which the amino acid composition of the remaining peptide is determined after each degradation cycle. The direct procedure can be coupled to the subtractive one in order to assure the accuracy of the sequence analysis. The method is fast and simple, and allows determination of 10 pmol of amino acid per cycle using standard reagents and instrumentation. Sensitivity can be greatly enhanced provided that ultrapure chemicals are employed. Small peptides (8-10 residues) were sequenced from 200 pmol sample, using a high-performance liquid chromatography assembly coupled to a fluorescence detector.     

Solid-phase sequencing on the gas-phase sequencer

Automated Edman degradation has been successfully used for determining the primary structure of numerous peptides and proteins. Quantitative solid-phase Edman degradation has great potential use for amino acid sequence analysis of synthetic peptides assembled on resin support by the Merrifield procedure. We report here the combined use of a modified gas-phase sequencer program and our improved reversed-phase HPLC analysis for PTH-amino acids to carry out the sequence analysis on synthesized peptide resins. This approach is far more sensitive than using glass beads on the conventional solid-phase sequencer. The peptide was assembled on copoly (styrene-1% divinylbenzene) resin beads at an initial substitution of 0.54 mmol/g. On a routine basis, 10-15 resin beads are used, and a repetitive yield of 94% is obtained: as few as 4 beads can be successfully sequenced. The HPLC PTH-amino acid analysis is sensitive down to subpicomole quantities. This procedure offers a sensitive and rapid analytical tool for checking the purity of peptides as they are being assembled on solid support.     

High-sensitivity sequencing of large proteins: partial structure of the rapamycin-FKBP12 target.

We report on studies leading to refinements of various steps of the protein internal sequencing process. Specifically, the developments comprise (1) higher-sensitivity chemical sequencing through background reduction; (2) improved peptide recovery from rapid in situ digests of nanogram amount, nitrocellulose-bound proteins; and (3) accurate UV spectroscopic identification of Trp- and Cys-containing peptides. In addition, we describe strategies for 2-dimensional liquid chromatographic peptide isolation from complex mixtures and a multi-analytical approach to peptide sequence analysis (Edman sequencing, matrix-assisted laser desorption mass spectrometry, and UV spectroscopy). Both strategies were applied in tandem to the primary structural analysis of a gel-purified, 250-kDa protein (mammalian target of rapamycin-FKBP12 complex), available in low picomolar quantities only. More than 300-amino acids worth of sequence was obtained in mostly uninterrupted stretches, several containing Trp, Cys, His, and Ser. That information has allowed the matching of a biological function of a mammalian protein to a yeast gene product with a well-characterized mutant phenotype. The results also demonstrate that extended chemical sequencing analysis (e.g., 26 successive amino acids) is now feasible, starting with initial yields well below 1 pmol.     

Separation of dimethylaminoazobenzenethiohydantoin amino acids by high-performance liquid chromatography at low picomole concentrations

The separation of all common dimethylaminoazobenzenethiohydantoin (DABTH) amino acids derived from modified Edman sequencing can be achieved by using high-performance liquid chromatography. All derivatives, including DABTH-Ile and DABTH-Leu, can be readily separated in a solvent mixture of sodium acetate buffer and 1% ethylene dichloride in acetonitrile. The high absorbance of the DABTH amino acids at 436 nm makes possible the quantitative determination of these derivatives at picomole concentrations in a relatively short time (30–40 min).     

Design, synthesis, and characterization of a protein sequencing reagent yielding amino acid derivatives with enhanced detectability by mass spectrometry.

We report the design, chemical synthesis, and structural and functional characterization of a novel reagent for protein sequence analysis by the Edman degradation, yielding amino acid derivatives rapidly detectable at high sensitivity by ion-evaporation mass spectrometry. We demonstrate that the reagent 3-[4'(ethylene-N,N,N-trimethylamino)phenyl]-2-isothiocyanate is chemically stable and shows coupling and cyclization/cleavage yields comparable to phenylisothiocyanate, the standard reagent in chemical sequence analysis, under conditions typically encountered in manual or automated sequence analysis. Amino acid derivatives generated with this reagent were detectable by ion-evaporation mass spectrometry at the subfemtomole sensitivity level at a pace of one sample per minute. Furthermore, derivatives were identified by their mass, thus permitting the rapid and highly sensitive determination of the molecular nature of modified amino acids. Derivatives of amino acids with acidic, basic, polar, or hydrophobic side chains were reproducibly detectable at comparable sensitivities. The polar nature of the reagent required covalent immobilization of polypeptides prior to automated sequence analysis. This reagent, used in automated sequence analysis, has the potential for overcoming the limitations in sensitivity, speed, and the ability to characterize modified amino acid residues inherent in the chemical sequencing methods that are currently used.     

Microsequence analysis of peptides and proteins. IX. Manual gas-phase microsequencing of multiple samples

A novel apparatus for performing manual gas-phase Edman chemistry on protein and peptide samples is described. Edman chemistry is performed in 6 to 10 Teflon continuous flow reactors (CFR), previously described by J.E. Shively et al. (1987) Anal. Biochem. 163, 517-529). The CFRs are packed with 10-15 mg of Polybrene-coated spherical silica (Porasil B, Waters Associates). The gas-phase coupling reagent and cleavage reagent are 5% aqueous triethylamine and anhydrous trifluoroacetic acid, respectively, delivered by a stream of argon gas. The delivery of the gas-phase reagents is manually controlled with Hamilton 3-way valves and 2-way valves, and that of the solvents, ethyl acetate and butyl chloride, by syringe pipetting. The average cycle time is 15-20 min for 6 to 10 samples run simultaneously. Conversion of the anilinothiazolinone to phenylthiohydantoin (PTH) amino acid derivatives is accomplished manually with 25% aqueous trifluoroacetic acid. The PTH amino acids are analyzed by reversed-phase HPLC using an autosampler for handling multiple samples. Excellent results were obtained in the 100-200 pmol range. Protein samples can be sequenced from 15-20 cycles, and peptide samples usually to the COOH terminus. Initial yields ranged from 30 to 60% and repetitive yields ranged from 90 to 96%. The sample washout and size of background peaks are significantly reduced, compared to older methods of manual sequence analysis. The yields and background signal to noise are comparable to automated gas-phase Edman chemistry. The improved manual Edman described represents a low cost alternative to automated sequence analysis, and has the advantage being able to process multiple samples simultaneously.     

Analysis of phenylthiohydantoin amino acid mixtures for sequencing by thermospray liquid chromatography/mass spectrometry

Phenylthiohydantoin (PTH) amino acids, the derivatives of amino acids liberated in the course of automated N-terminal sequence analysis of peptides and proteins, are most commonly identified by high-performance liquid chromatography. This communication describes an extension to the methodology for PTH amino acid identification which exploits thermospray liquid chromatography/mass spectrometry for use in the confirmation of PTH amino acid identifications previously made solely on the basis of retention times. Thermospray mass spectra of the 19 synthetic PTH amino acids corresponding to the residues commonly observed during N-terminal sequencing have been acquired. These spectra show strong signals for the protonated molecular ion, accompanied in several cases by ions produced by limited fragmentation of the amino acid side chain and/or the PTH ring system. A reverse-phase separation protocol has been adapted for use with thermospray. The method permits recognition of the protonated molecular ions of all the standard PTH amino acids at the 150-pmol level on the basis of signal-to-noise ratios of 10:1 or better with full scanning. The method has been tested on the N-terminal amino acid sequence analysis of 200 pmol of the standard protein beta-lactoglobulin A, and has been found useful in the study of selected side-products of the sequencing chemistry.     

cDNA cloning of an mRNA encoding a sulfur-rich 10 kDa prolamin polypeptide in rice seeds

Using a rice maturing seed pUC9 expression library, we isolated a cDNA clone corresponding to 10 kDa sulfurrich prolamin by immunoscreening. A longer cDNA clone was obtained from a gtll library by plaque hybridization using this ³²P-labeled cDNA as a probe. A polypeptide sequence composed of 134 amino acids was deduced from the nucleotide sequence. A 24 amino acid signal peptide was assigned by computer calculation for the membrane spanning region and Edman sequencing of the purified mature polypeptide. Remarkably, 20% of methionine and 10% of cysteine were found in the mature polypeptide as well as high contents of glutamine, and hydrophobic amino acids. Part of the amino acid sequence was homologous with a conserved cysteine-rich region found in other plant prolamins. Two repeats of amino acid sequence were found in the polypeptide.     

ABRF ESRG 2005 study: identification of seven modified amino acids by Edman sequencing.

Identification of modified amino acids can be a challenging part for Edman degradation sequence analysis, largely because they are not included among the commonly used phenylthiohydantion amino acid standards. Yet many can have unique retention times and can be assigned by an experienced researcher or through the use of a guide showing their typical chromatography characteristics. The Edman Sequencing Research Group (ESRG) 2005 study is a continuation of the 2004 study, in which the participating laboratories were provided a synthetic peptide and asked to identify the modified amino acids present in the sequence. The study sample provided an opportunity to sequence a peptide containing a variety of modified amino acids and note their retention times relative to the common amino acids. It also allowed the ESRG to compile the chromatographic properties and intensities from multiple instruments and tabulate an average elution position for these modified amino acids on commonly used instruments. Participating laboratories were given 2000 pmoles of a synthetic peptide, 18 amino acids long, containing the following modified amino acids: dimethyl- and trimethyl-lysine, 3-methyl-histidine, N-carbamyl-lysine, cystine, N-methyl-alanine, and isoaspartic acid. The modified amino acids were interspersed with standard amino acids to help in the assessment of initial and repetitive yields. In addition to filling in an assignment sheet, which included retention times and peak areas, participants were asked to provide specific details about the parameters used for the sequencing run. References for some of the modified amino acid elution characteristics were provided and the participants had the option of viewing a list of the modified amino acids present in the peptide at the ESRG Web site. The ABRF ESRG 2005 sample is the seventeenth in a series of studies designed to aid laboratories in evaluating their abilities to obtain and interpret amino acid sequence data.     

Detection of DBD-carbamoyl amino acids in amino acid sequence and D/L configuration determination of peptides with fluorogenic Edman reagent 7-[(N,N-dimethylamino)sulfonyl]-2,1,3-benzoxadiazol-4-yl isothiocyanate.

A method for amino acid sequence and D/L configuration identification of peptides by using fluorogenic Edman reagent 7-[(N, N-dimethylamino)sulfonyl]-2,1,3-benzoxadiazol-4-yl isothiocyanate (DBD-NCS) has been developed. This method was based on the Edman degradation principle with some modifications. A peptide or protein was coupled with DBD-NCS under basic conditions and then cyclized/cleaved to produce DBD-thiazolinone (TZ) derivative by BF3, a Lewis acid, which could significantly suppress the amino acid racemization. The liberated DBD-TZ amino acid was hydrolyzed to DBD-thiocarbamoyl (TC) amino acid under a weakly acidic condition and then oxidized by NaNO2/H+ to DBD-carbamoyl (CA) amino acid which was a stable and had a strong fluorescence intensity. The individual DBD-CA amino acids were separated on a reversed-phase high-performance liquid chromatography (RP-HPLC) for amino acid sequencing and their enantiomers were resolved on a chiral stationary-phase HPLC for identifying their D/L configurations. Combination of the two HPLC systems, the amino acid sequence and D/L configuration of peptides could be determined. This method will be useful for searching D-amino-acid-containing peptides in animals.     

EDMAN SEQUENCING RESEARCH GROUP 2004 STUDY: MODIFIED AMINO ACIDS IN EDMAN SEQUENCING

Edman degradation sequencing relies on comparing high-performance liquid chromatography retention times of the sample phenylthiohydantoin amino acids with phenylthiohydantoin amino acid standards. The elution characteristics of the twenty common amino acids have been well characterized, which aids in making confident assignments. Modified amino acids may present more of a challenge since they are not part of the commonly used standards and because the protein sequencer analyst may not have experience with them. Laboratories requesting a sample were sent a tube containing approximately 775 pmoles of a 20-amino-acid synthetic peptide composed of several modified amino acids that may be found in proteins or are generated during sample preparation. In addition to filling in an assignment sheet, which included retention times and peak areas, participants were asked to provide specific details about the parameters used for the sequencing run. References for some of the modified amino acid elution characteristics were provided and the participants had the option of viewing a list of the modified amino acids present in the peptide at the Edman Sequencing Research Group website (ESRG). The goal of the study consisted of two parts: assessment of the ability to correctly assign all the amino acids in the peptide, including the modified amino acids; and the collection and compiling of elution time characteristics of modified amino acids for instruments used in the study. The resulting compilation of the modified amino acid elution times and running conditions will be accessible at the Association of Biomolecular Resource Facilities (ABRF) ESRG website for future reference. The ABRF ESRG 2004 sample is the 16th in a series of studies designed to aid laboratories in evaluating their abilities to obtain and interpret amino acid sequence data.     

Micro-analysis of amino acids

An automated amino acid analyzer has been developed for the analysis of amino acids with the sensitivity at the 10–100 pmol level except for proline which requires >50 pmol. o-Phthalaldehyde, in the presence of 2-mercaptoethanol, is used for the fluorometric detection of amino groups (Roth, M. (1971) Anal. Chem. 43, 880–882). A post-column reaction of the amino acid with sodium hypochlorite (Bohlen, P. and Mellet, M. (1979) Anal. Biochem. 94, 313–321) gives oxidation products amenable to detection with o-phthalaldehyde. The instrument uses high-performance liquid chromatographic pumps capable of micro-flow rates with a minimum pulsation. The method is suitable for routine analyses of amino acids at picomole levels with reproducibility and accuracy comparable to the ninhydrin-based amino acid analysis.     

Computer-aided design of a catalyst for Edman degradation utilizing substrate-assisted catalysis

Molecular biology has been revolutionized by the miniaturization and parallelization of DNA sequencing assays previously performed on bulk samples. Many of these technologies rely on biomolecular reagents to facilitate detection, synthesis, or labeling of samples. To aid in the construction of analogous experimental approaches for proteins and peptides, we have used computer-aided design to engineer an enzyme capable of catalyzing the cleavage step of the Edman degradation. We exploit the similarity between the sulfur nucleophile on the Edman reagent and the catalytic cysteine in a naturally occurring protease to adopt a substrate-assisted mechanism for achieving controlled, step-wise removal of N-terminal amino acids. The ability to expose amino acids iteratively at the N-terminus of peptides is a central requirement for protein sequencing techniques that utilize processive degradation of the peptide chain. While this can be easily accomplished using the chemical Edman degradation, achieving this activity enzymatically in aqueous solution removes the requirement for harsh acid catalysis, improving compatibility with low adsorption detection surfaces, such as those used in single molecule assays.     

Determination of Phosphorylation Sites in Peptides and Proteins Employing a Volatile Edman Reagent

A manual Edman degradation protocol has been developed that allows the identification of phosphorylation sites in ³²P-labeled peptides at the subpicomole level. By using both a volatile reagent, trifluoroethyl isothiocyanate, and volatile buffers, extraction steps are rendered unnecessary and cycle times can be reduced to 45 min. The protocol was employed to identify the site of phosphorylation in phosphoserine- and phosphotyrosine-containing peptides.     

Structural characterization of En-1, a cold-adapted protein pheromone isolated from the Antarctic ciliate Euplotes nobilii

The second of two diffusible cell signal proteins (pheromones) purified from a wild-type strain of the Antarctic ciliate, Euplotes nobilii, has been determined by automated Edman degradation of the whole molecule and peptides generated by its chymotryptic digestion. The proposed sequence of 52 amino acids of this new pheromone, designated En-1, is: NPEDWFTPDT(10)CAYGDSNTAW(20)TTCTTPGQTC(30)YTCCSSCFDV(40)VGEQACQMSA(50)QC. In common with the previously determined 60-amino-acid sequence of the other pheromone, En-2, it bears eight cysteines in conserved positions (presumably linked into four conserved intrachain disulfide bonds), and physicochemical features of potential significance for cold adaptation, such as a reduced hydrophobicity, an increased solvent accessibility, and an improved local backbone flexibility. However, En-1 diverges from En-2 for having evolved a threonine cluster in the place of a glycine cluster to apparently make more flexible a region that is likely functionally important.     

HPLC analysis of free amino acids and amino acids of total proteins in cultured cells: an application to the study of rat Sertoli cell protein metabolism.

A simple, rapid and, sensitive HPLC method, coupled with fluorometric detection, has been worked out and employed to determine the intracellular free amino acid concentrations and the amino acid composition of total proteins in rat Sertoli cell primary culture. Sertoli cells were isolated enzymatically from testes of 20- and 28-day-old rats and cultured at 32 degrees C in Eagle's minimum essential medium. On the second day of culture, cell monolayers were quickly rinsed with ice-cold saline, immediately frozen in liquid nitrogen, accurately harvested, and homogenized in 10% trichloroacetic acid. Tissue free amino acids were determined in the acidic soluble fraction following neutralization, while the precipitate was hydrolyzed for the evaluation of the fractional content of amino acids into total proteins. Amino acid samples were derivatized with o-phthaldialdehyde/3-mercaptopropionic acid and resolved by a linear one-step acetonitrile gradient in 12.5 mM sodium phosphate buffer, pH 7.2, employing a 5-microns particle size reversed-phase column. Fluorescence was monitored with excitation at 330 nm and emission at 450 nm. Under these conditions all major physiological amino acids could be satisfactory separated, identified, and subsequently quantified with the aid of standards. The run time was about 50 min; the linearity was excellent over a large range of concentrations (1-800 pmol) and the lower limit of sensitivity appeared to be 0.5 pmol. This method permits us to demonstrate age-dependent modifications in the intracellular amino acid pool and to adequately evaluate the process of protein synthesis in cultured Sertoli cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Primary structure of the lambda repressor

The complete covalent structure of the bacteriophage lambda repressor has been determined by sequential Edman degradation, gas chromatographic-mass spectrometric peptide sequencing, and DNA sequencing of the repressor gene cI. The repressor is a single-chain, acidic protein containing 236 amino acids. The amino terminal 40 residues are highly polar and basic. Lysines and arginines in the sequence tend to be clustered.     

Human plasma prekallikrein, a zymogen to a serine protease that contains four tandem repeats

The amino acid sequence of human plasma prekallikrein was determined by a combination of automated Edman degradation and cDNA sequencing techniques. Human plasma prekallikrein was fragmented with cyanogen bromide, and 13 homogeneous peptides were isolated and sequenced. Cyanogen bromide peptides containing carbohydrate were further digested with trypsin, and the peptides containing carbohydrate were isolated and sequenced. Five asparagine-linked carbohydrate attachment sites were identified. The sequence determined by Edman degradation was aligned with the amino acid sequence predicted from cDNAs isolated from a lambda gt11 expression library. This library contained cDNA inserts prepared from human liver poly(A) RNA. Analysis of the cDNA indicated that human plasma prekallikrein is synthesized as a precursor with a signal peptide of 19 amino acids. The mature form of the protein that circulates in blood is a single-chain polypeptide of 619 amino acids. Plasma prekallikrein is converted to plasma kallikrein by factor XIIa by the cleavage of an internal Arg-Ile bond. Plasma kallikrein is composed of a heavy chain (371 amino acids) and a light chain (248 amino acids), and these 2 chains are held together by a disulfide bond. The heavy chain of plasma kallikrein originates from the amino-terminal end of the zymogen and is composed of 4 tandem repeats that are 90 or 91 amino acid residues in length. These repeat sequences are also homologous to those in human factor XI. The light chain of plasma kallikrein contains the catalytic portion of the enzyme and is homologous to the trypsin family of serine proteases.