Microsequence analysis of peptides and proteins. V. Design and performance of a novel gas-liquid-solid phase instrument

We describe the construction and performance of a novel, automated, Edman chemistry-based microsequencer. The reagent and solvent delivery system, the reaction cartridge for coupling and cleavage, and the conversion flask are all constructed from chemically inert perfluoroelastomers. The delivery valves are of a new design incorporating the use of electromagnetically actuated solenoids and zero-dead-volume construction, and may be connected in a modular fashion resulting in multiple inputs with a single output line which can be flushed with inert gas. The bottle closures are of a new design based on an all-Teflon compression fitting. The reaction cartridge and conversion flask are thermostated by solid-state heaters in an aluminum block. The overall size of the instrument is 25 X 34 X 14 in. The chemistry utilizes 2% aqueous triethylamine as the coupling base which is delivered to the reaction cartridge via a stream of nitrogen. The "gas-phase" delivery of the coupling base and the cleavage acid (trifluoroacetic acid) is modeled after the method described by R. M. Hewick et al. (J. Biol. Chem. 256, 7990-7997,1981). The instrument has performed well over a period of 3 years in terms of low background peaks, sensitivity in the picomole range, and reliability of operation. The use of economical components, ease of construction and operation, and sensitive analytical capability make this instrument a useful tool for microsequence analysis of peptides and proteins.     

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.     

Effect of prolonged 100 degrees C heat treatment in sodium dodecyl sulfate upon peptide bond cleavage.

Using photographic detection and high resolution, the potential of field desorption mass spectrometry for mixture analysis is exemplified by means of synthetic mixtures of up to 15 amino acid phenylthiohydantoins (PTH amino acids). The high molecular ion intensities, low fragmentation, and relatively small intermolecular interaction allow the easy discrimination of individual components of these mixtures. The sensitivity and selectivity of the field desorption method is tested on PTH amino acids obtained from automated Edman sequenator degradations of a ribosomal protein. The field desorption spectra show the molecular ions and significant fragment ions of the PTH derivatives of all 10 degradation steps investigated. Even in cases where conventional electron impact mass spectrometry fails to show the molecular ions and only characteristic fragment ions are found, the field desorption method gives rise to the molecular ions in high yields (e.g., PTH-arginine and PTH-(?-PTC)-lysine). Therefore the use of the method as a complementary technique for the confirmation of PTH amino acids released in the Edman sequenator appears to be advantageous.     

Comparative gas phase and pulsed liquid phase sequencing on a modified Applied Biosystems 477A sequencer

A simple and inexpensive modification of the Applied Biosystems 477A sequencer, to run in the pulsed liquid-phase and in the gas-phase mode of the Edman chemistry, is described. This modification is especially useful for sequencing samples on polyvinylidene difluoride (PVDF) membranes. Additional carriers are required if a sample on a PVDF membrane is sequenced with the pulsed liquid-phase degradation program of the 477A. In the gas-phase mode no such carriers are needed. This eliminates time-consuming preconditioning sequencer cycles and reduces the sequencer background. In addition, initial coupling yields in the gas-phase mode exceeded those in the pulsed liquid-phase mode, whereas the average repetitive yields were similar. Samples spotted onto glass fiber filters pretreated with polybrene and samples spotted or electroblotted onto PVDF membranes were examined. A number of advantages of the gas-phase mode are presented.     

Detection of peptidyl-3,4-dihydroxyphenylalanine by amino acid analysis and microsequencing techniques

3,4-Dihydroxyphenylalanine (DOPA) is an amino acid that occurs naturally in the primary sequence of many proteins and peptides. Detection of peptidyl-DOPA, however, can be elusive. This is due (i) to its coelution with leucine on most of the ion exchangers used in amino acid analysis and (ii) to the coelution of phenylthiohydantoin (PTH)-DOPA with PTH-alanine during routine C18 reversed-phase HPLC following automated Edman degradation. By application of appropriately timed temperature and/or gradient modifications during chromatography, DOPA and its PTH derivative can be adequately resolved for detection by both amino acid analysis and gas-phase sequencing.     

Manual gas-phase isothiocyanate degradation

We describe a manual gas-phase isothiocyanate degradation procedure for the primary structure determination of proteins and peptides. The proteins and peptides are applied to a polybrene-coated glass fiber filter wedged into a small glass column. The phenylisothiocyanate is directly pipetted onto the filter disk. The coupling and cleavage reactions are performed in small desiccators containing trimethylamine and trifluoroacetic acid vapors, respectively. The wash and extraction steps are performed by allowing the suitable solvents to percolate through the filter disk. The extracted anilinothiazolinone is then converted to the phenylthiohydantoin and identified by any one of a number of described methods. Our results show that this method is very sensitive and that the reactions proceed faster than those of the published automated procedure. No expensive equipment is required and the manual degradation can be performed by a laboratory assistant. A large number of samples can be simultaneously subjected to the degradation under identical conditions, making this an ideal method for physicochemical investigations into the isothiocyanate degradation. We also use this method to screen HPLC fractions after enzymatic protein fragmentation. Manually sequenced glass filters can be transferred to the automated instrument for more extended degradations.     

Rapid manual sequencing of multiple peptide samples in a nitrogen chamber.

Automatic protein sequenators are very expensive. Most laboratories must rely on slower manual methods. This paper describes an inexpensive nitrogen chamber in which multiple peptide samples may be sequenced manually and yet rapidly. The nitrogen environment keeps samples free from oxygen, water vapor, and dust. A complete, simple procedure for degrading peptides is also included. From six to twelve peptide samples may be degraded through one cycle of Edman degradation in a single morning. Several pieces of new equipment and procedures are described which simplify the manipulations involved in protein sequencing.     

High-performance liquid chromatography of side-chain-protected amino acid phenylthiohydantoins

Eighteen side-chain-protected amino acids, routinely employed in solid-phase peptide synthesis, were derivatized to their phenylthiohydantoins (PTH) by one cycle of the Edman degradation. All of these side-chain-protected PTH amino acids elute, with almost-baseline resolution, in less than 18 min by high-performance liquid chromatography, utilizing a biphasic gradient of acetonitrile in 0.01 n sodium acetate, pH 4.5, or a linear gradient of 0 to 100% acetonitrile with the exception of the coelution of a O-benzyl-threonine and carbobenzoxy-lysine phenylthiohydantoin amino acids. The derivatized amino acids were subjected to reverse-phase chromatography on a Zorbax ODS column and monitored at 254 nm. None of the PTH amino acids coelute with side-chain-protected PTH amino acid counterparts, although PTH-tosyl-histidine undergoes deprotection to PTH-histidine in the Edman degradation. A protected decapeptide attached to a chloromethylated polystyrene resin was degraded on a solid-phase sequencer in 16 h. The PTH amino acids resulting from the automated Edman degradation on the decapeptide were fully resolved and quantified in less than 3 h demonstrating that automated high-performance liquid chromatography can keep pace with both the automated sequencer and synthesizer which requires minimally 2–3 h for attachment of each residue to the growing peptide chain.     

Detection of methylated asparagine and glutamine residues in polypeptides

A residue of gamma-N-methylasparagine (gamma-NMA) is found at position beta-72 of many phycobiliproteins. delta-N-Methylglutamine is present in some bacterial ribosomal proteins. gamma-NMA was synthesized by reacting the omega-methyl ester of aspartate with methylamine and delta-N-methylglutamine by reaction of pyroglutamate with methylamine. These derivatives and the omega-methyl esters of aspartate and glutamate were characterized by melting point, by thin-layer chromatography, by amino acid analysis, by NMR spectroscopy, and after conversion to the phenylthiohydantoin (PTH) derivative. The gamma-NMA residues in peptides from allophycocyanin, C-phycocyanin, and B-phycoerythrin were stable under the conditions of automated sequential gas-liquid phase Edman degradation. On HPLC, PTH-gamma-NMA co-eluted with PTH-serine and was accompanied by a minor component eluting just prior to dimethylphenylthiourea. Similar results were obtained on manual derivatization of synthetic gamma-NMA to prepare the PTH derivative. The PTH-delta-N-methylglutamine standard eluted near the position of dimethylphenylthiourea under the usual conditions employed for the identification of PTH-amino acid derivatives in automated protein sequencing.     

ABRF-ESRG’03: Analysis of a PVDF-Bound Known Protein with a Homogeneous Amino-Terminus

The Association of Biomolecular Resource Facilities 2003 Edman Sequencing Research Group (ABRF-ESRG’03) sample is the 15th in a series of studies designed to allow participating members to evaluate their abilities to analyze the N-terminus of a protein or peptide using automated Edman degradation chemistry. It is a follow-up study to the ESRG’02 sample, which was a single protein with a heterogeneous N-terminus. Both the 2002 and 2003 samples were obtained from the same protein complex and were resolved by SDS-PAGE followed by electrophoretic transfer to PVDF membrane. The ABRF-ESRG’03 sample had an apparent molecular weight of 49 kDa and a single N-terminus, with initial yields of approximately 2 pmol. Participants were asked to sequence 25 residues and return their results to the ESRG for analysis along with two completed surveys and an area/pmol table for repetitive and initial yield calculations. Data for 46 responses are presented which include initial yields, repetitive yields, sequencer performance, and ability to identify the protein.     

Accelerated high-sensitivity microsequencing of proteins and peptides using a miniature reaction cartridge.

Greatly reduced automated protein sequencing degradation times of less than 25 min with concurrent on-line phenylthiohydantoin (PTH) derivative analysis times of less than 16 min have been achieved by using a miniaturized reaction cartridge with optimized chemical and analytical cycles. Using this method a wide range of standard and novel peptides and proteins have been sequenced with reproducibly high initial and repetitive cycle yields. In these accelerated analyses the recovery of the more labile PTH derivatives was markedly improved by using elevated pressure during cleavage steps and temperature programming throughout the Edman cycle.     

Sensitization of Edman amino acid derivatives using the fluorescent reagent, 4-aminofluorescein

The ability to analyze amino acid derivatives at the femtomole level is one of the most interesting challenges in the field of protein microsequencing. 2-Anilino-5-thiazolinone amino acids, obtained by Edman degradation, were quantitatively derivatized with fluorescent primary amines. The most fluorescent reagent tested was 4-aminofluorescein. The amino acid derivatives sensitized with this reagent were separated using reversed-phase high-performance liquid chromatography and identified at the 100 attomole level. Incorporation of this method into the operation of a conventional automated sequencer is also described.     

D-L amino acid analysis using automated precolumn derivatization with 1-fluoro-2,4-dinitrophenyl-5-alanine amide

Summary An automated procedure for the precolumn derivatization of enantiomeric amino acid mixtures with 1-fluoro-2,4-dinitrophenyl-5-alanine amide and a liquid chromatographic method for the separation of the derivatives with UV detection are reported. The system described allows to perform routine analyses using microbore columns with a sensitivity at the picomol level. Improvements for the use of this reagent in the protocol of a subtractive Edman degradation procedure of peptides to determine the sequence position of amino acid residues with concomitant identification of their chirality are also described.     

The N, O-diacetylmuramidase of Chalaropsis species. V. The complete amino acid sequence.

The complete amino acid sequence of lysozyme Ch has been established by a combination of automated and manual Edman degradation and carboxypeptidase digestion.(see article)There is a single disulfide bond in the center of the molecule. The enzyme has 211 residues with a calculated molecular weight of 22,415. Lysozyme Ch has an amino acid sequence that is totally different from all other lysozymes whose sequences are known.     

Microsequence analysis of peptides and proteins : III. Artifacts and the effects of impurities on analysis

Levels of contaminants in the parts-per-billion range can adversely affect amino acid microsequence analysis (low-nanomole to subnanomole range) in two ways; (a) contaminants in solvents used in the purification of proteins and peptides can derivatize reactive amino acids to form unusual products or react with free α-NH₂ groups to effectively prevent sequence analysis, and (b) contaminants in the reagents and solvents used in Edman chemistry can give spurious peaks on HPLC analysis of amino acid phenythiohydantoin derivatives or react with the phenylthiocarbamylpeptidyl derivatives to give lower initial and repetitive yields of the subsequent phenylthiohydantoin derivatives. Practical examples of these problems and their solutions are described. With proper care in the preparation of solvents and reagents for sample purification and Edman chemistry, microsequence analysis in the low-nanomole to subnanomole range can be made routine.     

A comparison of sulfonated phenylisothiocyanates for reducing losses of lysine-containing peptides during automated sequencing

A simple procedure has been devised to couple lysine-containing peptides with 3-sulfophenylisothiocyanate or with 4-sulfophenylisothiocyanate and then to subject them to automated Edman degradation. The better repetitive yields in all cases were obtained with the 3-sulfophenylisothiocyanate. The reasons for these observations are explained and an improved method of synthesis of the reagent is given.     

Sequence analysis of phosphoserine-containing peptides. Modification for picomolar sensitivity

Sequencing of phosphoserine-containing peptides yields normally no identifiable PTH-derivatives at those positions where phosphoserine is located. Here a new method is described which allows identification of the position of phosphoserine by chemical modification just before sequence analysis. In a one-step microbatch reaction, phosphoserine present in the intact peptide can be transformed quantitatively into stable derivatives such as beta-methylaminoalanine (MAA), S-ethanolcysteine or S-ethylcysteine. These derivatives are detectable during microsequencing with less than 100 pmol peptide using an Applied Biosystems gas-phase sequencer equipped with an on-line PTH amino acid analyzer.     

The application of 0.1 M quadrol to the microsequence of proteins and the sequence of tryptic peptides.

In an effort to extend automated Edman degradation to nanomole quantities of protein, the method of sequenator analysis described by Edman and Begg (Edman, P., and Begg, G. (1967), Eur. J. Biochem. 1, 80) was modified to permit long degradations in the absence of carrier proteins. By using an aqueous 0.1 M Quadrol program with limited, combined benezene-ethyl acetate solvent extractions, as well as a change in the delivery system for heptafluorobutyric acid, it was possible to recover and identify the first 30 amino acid residues from a sequenator run on 7 nmol of myoglobin. For 3 nmol of myoglobin, 20 steps could be identified. PTH-amino acids were identified by gas-liquid chromatography and thin-layer chromatography on polyamide sheets. Without using a carrier protein the cup to prevent mechanical losses (Niall, H. D., Jacobs, J. W., Van Rietshoten, J., and Tregear, G. W. (1974), FEBS Lett. 41, 62), the repetitive yield using this program was 93-96%. The same program has been applied successfully to peptides of 14 or more residues with or without modification by Braunitzer's reagent and to a number of larger peptides and proteins including a 216 residue segment of rabbit antibody heavy chain in which a sequence of 35 steps was accomplished on 25 nmol.     

Isolation and partial sequencing of a pancreatic polypeptide-like neuropeptide from the liver fluke, Fasciola hepatica.

1. A pancreatic polypeptide (PP)-immunoreactive neuropeptide has been isolated and partially sequenced from the liver fluke, Fasciola hepatica. 2. Gel permeation chromatography of an acid ethanol extract of cattle flukes showed that the peptide is similar in size to mammalian (bovine) PP. 3. The Fasciola peptide was purified to homogeneity by means of reverse-phase HPLC, employing different column chemistries. 4. The purified peptide was sequenced using automated gas-phase Edman degradation and the first 24 amino acid residues determined.     

A method for the rapid,automated filtration of protein hydrolyzates

A method for the automated filtration of protein hydrolyzates prior to amino acid analysis is described. Minor modification of a Technicon Sampler II enables it to function simultaneously as a sampler and a filtrate collector. Samples are drawn from cups in the sampler tray and are forced through a Teflon filter (pore size, 0.2 μm) in a Millipore Swinnex filter holder by a variable-speed Technicon proportioning pump. The filtrates are collected in cups in the sampler tray opposite those containing unfiltered hydrolyzates. Using this technique, 12 hydrolyzates can be filtered in 25 min compared to the approximately 2 h of technician time required for their manual filtration. Aliquots from each of 48 samples representing different proteins and hydrolysis conditions are filtered manually and by the automated technique. Analysis of variance of the resulting recoveries of each amino acid indicate little likelihood of effects due to filtration method.