Recovery of tryptophan in peptides and proteins by high-temperature and short-term acid hydrolysis in the presence of phenol

The addition of 3% (w/v) phenol to 6 M HCl largely prevented the destruction of tryptophan during rapid hydrolysis of peptides and proteins at 166 degrees C for 25 min or at 145 degrees C for 4 h. This hydrolysis procedure was advantageous for amino acid microanalysis using conventional high-performance liquid chromatography with a precolumn derivatization technique. The recovery of tryptophan from proteins was at least 80%. The addition of phenol also improved the recovery of methionine and carboxymethylcysteine. The amount of tryptophan in proteins electroblotted onto a polyvinylidene difluoride membrane was determined by this method.     

A new acid hydrolysis method for determining tryptophan in peptides and proteins

Three different methods for hydrolysis and determination of amino acid composition of peptides and proteins were compared. We found, that the method of Matsubara and Sasaki (using 6N HCl and thioglycolic acid) gives comparatively low recoveries for tryptophan, while Liu and Chang's method, using p-toluenesulfonic acid and tryptamine, is more suitable. To eliminate the difficulties of the latter method, we used mercaptoethane-sulfonic acid, which, in the concentration used, results in total hydrolysis of peptide bonds within 22 hr and gives very high tryptophan recoveries. Both sulfonic acid methods were used for hydrolysis of the pentapeptide “pentagastrine” as well as of the proteins lysozyme, cytochrome c, and chymotrypsine. Their amino acid composition was determined using an automatic amino acid analyzer. Similarly to the p-toluenesulfonic acid method, the results of our method are totally reliable only for pure peptides and proteins, though the results obtained with our method using samples containing carbohydrates are better than those of all earlier methods.     

Further study on gas phase acid hydrolysis of protein: improvement of recoveries for tryptophan, tyrosine, and methionine

A novel method for vapor phase acid hydrolysis of protein suitable for quantitative analysis of tryptophan is presented. The hydrolysis is carried out in vapor of a mixture made of 7 M HCl, 10% trifluoroacetic acid, and 20% thioglycolic acid in the presence of indole. Reasonably good recoveries of common amino acids, including tryptophan (above 75%), were achieved.     

High-performance liquid chromatography with fluorescence detection for quantitation of tryptophan and tyrosine in a shrimp waste protein concentrate

A new, simple, and reproducible isocratic high-performance liquid chromatography (HPLC) method has been developed for the determination of free and total tyrosine and tryptophan in a protein concentrate. To determine total amino acids, the method involves alkaline hydrolysis of the proteins with sodium hydroxide at 120 degrees C for 4h in the absence of air. Best results were achieved with a SS Exil ODS column 5microm (25cmx0.46cm i.d.), with an eluent of methanol: 40mM sodium acetate buffer (adjusted to pH 4.5 with acetic acid; 20:80, v/v), a flow rate of 0.80mL/min at 26 degrees C, and with programmable fluorescence detection. Under optimum conditions excellent linearity was obtained, and the overall recovery was 90.5, and 95.9% for total tryptophan and tyrosine, respectively. The precision results showed that the relative standard deviation of the repeatability and reproducibility were < or =4.78 and < or =4.65, respectively. This method was used to quantify the cited analytes in the protein concentrate obtained during the lactic acid fermentation of shrimp waste.     

Tryptophan micro-scale determinations by rapid hydrolysis

A rapid acid-hydrolysis micro method was developed for the accurate determination of the tryptophan contents of proteins. Sample protein (5 micrograms) was hydrolysed in 30 microliters of 3M mercaptoethanesulfonic acid at 166 degrees C for 25 min, resulting in total hydrolysis of the peptide bonds. The subjection of the hydrolysate to an amino-acid analyser revealed the amino-acid composition, including the content of tryptophan with a high recovery of 92%.     

Elimination of insulin-like activity present in certain batches of crude bovine serum albumin by trypsin treatment

A comparative study was carried out in order to determine which of the most commonly used alkalies for protein hydrolysis in tryptophan determination gave the best results. Hydrolyses were performed with 2.5 and 4 n Ba (OH)₂, 4 and 10 n NaOH, 5 n NaOH containing 5% SnCl₂, and with 4 n LiOH, not previously reported for use. The effect of temperature and hydrolysis time on the measured tryptophan content was also determined. Based on results obtained with lysozyme and with seven high protein preparations 4 n LiOH gave the best results. A temperature of 145°C was selected as the most convenient temperature since maximum tryptophan values were obtained with 4–8 h. The hydrolysis time required was inversely related to the protein content of the preparation. Lysozyme, casein, bovine plasma protein, and dehydrated whole egg gave maximum tryptophan content after 4 h hydrolysis while skimmed milk powder, rice flour, wheat flour, and wild legume flour required 8 h hydrolysis.     

Development of an acid hydrolysis method with high recoveries of tryptophan and cysteine for microquantities of protein.

High recoveries of tryptophan and cysteine were achieved by 12.5 min of hydrolysis with mercaptoethanesulfonic acid vapor. Proteins (1-100 micrograms) were modified by vapor-phase S-pyridylethylation before hydrolysis. The modified proteins were hydrolyzed with the vapor of 2.5 M mercaptoethanesulfonic acid at 176 degrees C. This method promoted efficient hydrolysis of the peptide bonds in proteins and resulted in high recoveries of both tryptophan and cysteine, of 90% or greater, in addition to the other amino acids.     

Conformation, enzymic activity, and immunochemistry of a lysozyme derivative modified at tryptophan 123 by reaction with 2,3-dioxo-5-indolinesulfonic acid.

Reaction of hen egg-white lysozyme with 2,3-dioxo-5-indolinesulfonic acid (DISA) yielded a homogeneous derivative which was modified at a single tryptophan residue. The modification was located at Trp-123. The absorption spectrum of the derivative showed a new peak in the visible range with lambdamax at 365 nm. In addition, the absorption maximum in the ultraviolet which appears in lysozyme at 280 nm was shifted to 270 nm in the derivative and appreciably enhanced. In ORD measurements, the rotatory behaviors of lysozyme and its derivative were identical at the 233 nm negative minimum and the 199 nm positive extremum. CD measurements gave equal [theta] values for lysozyme and derivative at the two negative ellipticity bands at 208 and 220 nm. Although no conformational differences between lysozyme and derivative were observed by ORD and CD measurements, some changes were detectable by chemical methods. Accessibility to tryptic hydrolysis and susceptibility of the disulfide bonds to reduction were increased in the derivative relative to lysozyme. The lytic activity of the derivative, which retained the same pH optimum as native lysozyme, was greatly (50%) decreased, probably as a result of the slight conformational change. With several antisera to lysozyme, the native protein and its derivative had equal antigenic reactivities. The findings were instrumental in further delineation of an antigenic reactive site in lysozyme.     

Peptide synthesis on a phenolic resin support

Protected peptides assembled on a phenolic resin support were cleared by peroxide-catalysed hydrolysis. In genenal peptide phenyl ester resins were more labile to nucleophiles than were corresponding Merrifield resin derivatives; transesterification with dimethylaminoethanol providing on alternative cleavage method for peroxide-sensitive peptides. Losses of radiolabelled peptide from both Merrifield and phenolic resins were determined during acid deprotection, base wash and coupling steps in the synthesis of a tetrapeptide. Using 40% (v/v) trifluoroacetic acid in dichloromethane for Boc-deprotection the phenolic resin gave improved results compared to the Merrifield resin. The merits of the procedure for the preparation of protected peptide acids suitable for subsequent condensation reactions were exemplified by the synthesis of an octapeptide sequence of a modified lysozyme.     

A new double-labelling procedure for determination of amino acid composition: application to bacteriorhodopsin

A new double-labelling procedure for amino acid analysis which requires only routine chromatographic equipment is described. When 1-fluoro-2,4-dinitro[3H]benzene is reacted with a mixture of 14C-labelled amino acids followed by reaction with the same 14C-labelled amino acid mixture diluted with an unlabelled sample of amino acids, the 3H:14C ratio in the resulting 2,4-dinitrophenyl (DNP) amino acid derivatives of the diluted sample will be increased in proportion to the quantity of unlabelled amino acid in the diluted sample. This procedure gave reliable results when applied to the known proteins insulin and lysozyme. The procedure is most advantageous when applied to amino acids which are unstable during acid hydrolysis or present in low molar fractions. When applied to the analysis of the bacteriorhodopsin in Halobacterium cutirubrum, this procedure showed the presence of one histidine residue and four tryptophan residues per mole protein but no cystine or cysteine; in general, the analyses obtained were consistent with those originally reported by Oesterhelt, D. and Stoeckenius, W. (1971) (Nature (London) New Biol. 233, 149-152) for bacteriorhodopsin of H. halobium.     

Peptidoglycan of Legionella pneumophila: apparent resistance to lysozyme hydrolysis correlates with a high degree of peptide cross-linking.

Peptidoglycan (PG) from Legionella pneumophila was composed of muramic acid, glucosamine, glutamic acid, alanine, and meso-diaminopimelic acid in a molar ratio of 0.8:0.8:1.1:1.7:1. Partially purified PG contained trypsin-insensitive proteins which were extracted by 1 N NaOH hydrolysis without apparent dissolution of the PG. Lysozyme hydrolysis of purified PG or cell walls caused an increase in reducing groups which correlated with roughly 70 to 100% digestion of disaccharides. However, there was no significant decrease in turbidity during lysozyme hydrolysis of purified PG or cell wall. Additionally, 80 to 90% of the meso-diaminopimelic acid epsilon-amino groups were not susceptible to dinitrophenylation. Collectively, the PG of L. pneumophila was sensitive to lysozyme hydrolysis and insensitive to alkali dissolution, and 80 to 90% of the NH2 groups of meso-diaminopimelic acid were apparently involved in cross-linkages between peptides.     

Enrichment of enzyme activity on deformylation of 1-NFK-lysozyme.

The formamide linkage of an inactive lysozyme derivative (1-NFK-lysozyme), formed by selective ozonization of tryptophan 62 in hen egg-white lysozyme [EC 3.2.1.17] was hydrolyzed with dilute acid faster in the frozen state at about --10 degrees than at 20 degrees. On hydrolysis of 1-NFK-lysozyme the low lytic activity increased to approximately 80% of that of native lysozyme. It is suggested that the binding ability associated with kynurenine 62 in the lysozyme derivative formed by this hydrolysis may be responsible for increase in enzymatic activity.     

Beta-3-Oxindolylalanine: The main intermediate in tryptophan degradation occurring in acid hydrolysis of protein.

Under hydrolytic conditions using 6 M HCl, tryptophan reacted separately with dithiodiglycolic acid and cystine to give beta-3-oxindolylalanine (beta-[3-(2-indolinone)]alanine) as the main product. A compound, which eluted in the amino acid analyzer at the same position as beta-3-oxindolylalanine, was found in the acid hydrolyzate of lysozyme. The identicalness of these two compounds was established by comparison of their ultraviolet absorption spectra, elution positions on ion exchange chromatograms, etc. The "acid degradation product of tryptophan", which is known to be produced upon acid hydrolysis of tryptophan-containing proteins, must also be the same compound.     

Degradation of starchy substrates by a crude enzyme preparation and utilization of the hydrolysates for lactic fermentation

An enzyme preparation obtained from Aspergillus ustus, possessing cellulase, α-amylase, amyloglucosidase, proteinase and d-xylanase activities, was used along with commercial bacterial α-amylase and amyloglucosidase for the degradation of ragi (Eleusine coracana) flour and wheat (Triticum vulgare) bran. Lactic acid yield from ragi hydrolysate, adjusted to 5% reducing sugars (w/v), was 25% when fermented with Lactobacillus plantarum. The yields increased to 78% and 94% when the ragi hydrolysate was fortified with 20% and 60% (v/v) wheat bran hydrolysate, respectively. When commercial α-amylase and amyloglucosidase were used for the hydrolysis of ragi and wheat bran and L. plantarum was employed to ferment the hydrolysates containing 5% reducing sugars (w/v), lactic acid yields were 10% in ragi hydrolysate and 57% and 90% when the ragi hydrolysate was fortified with 20% and 60% (v/v) of wheat bran hydrolysate, respectively. α-Amylase and amyloglucosidase hydrolysed wheat bran added at 20% (v/v) as the sole source of nutrient to soluble starch hydrolysate (5% reducing sugars) gave 22% yield of lactic acid. The yield increased to 55% by the utilization of A. ustus enzyme preparation in addition to α-amylase and amyloglucosidase for wheat bran hydrolysis.     

Determination of tryptophan as the reduced derivative by acid hydrolysis and chromatography

A new procedure for the analyses of tryptophan and the total amino acid composition of proteins was based on the observations that pyridine borane reduces tryptophan in trifluoroacetic acid, while other amino acids remain intact [M. Kurata, Y. Kikugawa, T. Kuwae, I. Koyama, and T. Takagi (1980) Chem. Pharm. Bull. 28, 2274-2275; W.S.D. Wong, D.T. Osuga, and R.E. Feeney (1984) Anal. Biochem. 139, 58-67]. Concentrated HCl was used instead of trifluoroacetic acid for analytical purposes. The products were stable to hydrolysis in 6 N HCl, and the reduction did not interfere with hydrolysis and subsequent analyses. Quantitative recovery was achieved with most proteins when they were subjected to acid reduction in ice-cooled concentrated HCl with two incremental additions of pyridine borane. The reaction was terminated after 10 min by dilution with an equal volume of H2O, vacuum sealing, and hydrolyzing at 110 degrees C for 22 h. The yields of the expected values for cytochrome c, catalase, bovine serum albumin, subtilisin BPN', trypsin, chymotrypsin, beta-lactoglobulin, lysozyme, and pepsin were obtained. Ovotransferrin and ovalbumin, however, yielded values for tryptophan lower than literature values. With two different ion-exchange methods, the recoveries of all other amino acids were comparable to those obtained by acid hydrolysis with 6 N HCl. Since the same hydrolysate can be analyzed for both tryptophan and all the other amino acids, the procedure is a more convenient method than those requiring separate determinations. Initial results indicate that the method may be applied to high-performance liquid chromatographic procedures with adaptations of the protocols if necessary.     

Acid hydrolysis of protein in a microcapillary tube for the recovery of tryptophan

The acid hydrolysis of proteins was miniaturized and simplified by employing microcapillary tubes (100 microl in volume) with 6 M HCl containing 1% 2-mercaptoethanol and 3% phenol for an amino acid compositional analysis. The method not only eliminated the laborious evacuation step for the hydrolysis tube but also decreased the destruction of tryptophan during hydrolysis. The recovery of tryptophan was 79% by acid hydrolysis at 145 degrees C for 4 h. Since the acid mixture could be removed under vacuum, the hydrolysate was subjected to an amino acid analysis without neutralization or dilution.     

"Hydration memory" of lysozyme: a misinterpretation

The effects of sugars and similar additives on the catalytic activity of lysozyme have been attributed (Laretta-Garde et al., Biochim. Biophys. Res. Commun. 155: 816-822 (1988] to a "hydration memory" of the protein for solution conditions to which it was previously exposed. By measuring catalytic activity versus substrate concentration, tryptophan fluorescence and near ultraviolet circular dichroism all in the presence and absence of 50% (w/v) sucrose, we show that the effects can be explained, instead, on the basis of well known properties of proteins.     

Multiple conformational transitions of hen egg-white lysozyme in aqueous acetic acid solutions

Circular dichroism measurements revealed that hen egg-white lysozyme underwent multiple conformational transitions upon the addition of acetic acid. The transitions were reversible as judged from complete recoveries of enzymatic activity, electrophoretic mobility in SDS-polyacrylamide gel, and of ellipticity. Two transitions, with the mid-concentrations of 26 and 38% (v/v), were observed with the CD spectra in the amide absorption region. The two transitions were essentially athermal in the temperature ranges, 0 to 25 degrees C for the former and -10 to 10 degrees C for the latter. The trough ellipticity for the product of the transition at the higher acetic acid concentration (DII form) very closely approached the value for the synthetic polypeptides in the beta-conformation as the temperature was lowered. Molecular weight measurements by sedimentation equilibrium indicated that the products were both monomeric. Measurements of CD spectra in the aromatic absorption region showed another transition, whose mid-concentration varied with temperature from 26% (v/v) (at about 25 degrees C) to 38% (v/v) (at -10 degrees C). A change in the hydrodynamic volume detectable by exclusion chromatography was associated with this transition only.     

Photooxidative changes of lysozyme with 337.1 nm laser radiation

Summary Initial photoinduced oxidative changes in the protein lysozyme were studied using the 337.1 nm radiation from a pulsed nitrogen laser without exogenous sensitizing compounds. Irradiation of lysozyme and tryptophan in aerated solution results in the temperature and solvent dependent loss of tryptophan absorption and fluorescence, and the appearance of fluorescent daughter products, primarily N-formyl-kynurenine and kynurenine. Exposures that resulted in 15% loss of tryptophan fluorescence produced no measurable loss in enzymatic activity. Fluorescence quenching experiments on irradiated lysozyme at low conversion percentage suggest that an exposed residue (Trp-62) is favored as an initial target of attack.     

Nature of tryptophan photooxidation products in lysozyme in the presence of methylene blue]

One out of six trytophan residues in two lysozyme modification, obtained under lysozyme photooxidation in the presence of methylene blue, is found to be oxidized to N'-formylkinurenine (in one modification) and to kinurenine (in the other modification). The transition of one modification into another via detaching of N'-formyl group by soft acid hydrolysis has shown that one and the same tryptophan residue is oxidized in both products, Possible mechanism of tryptophan oxidation to the products mentioned is discu-sed on the basis of the hypothesis on signlet mechanism of lysozyme photooxidation in the presence of methylene blue.