Quantification of human lithostathine by high performance liquid chromatography.

Pancreatic stones of patients with chronic calcifying pancreatitis (CCP) are mostly made up of CaCO3 crystals. Formation and growth of such crystals is inhibited in vitro by lithostathine, a protein present in normal pancreatic juice. Decreased lithostathine activity was therefore suspected in patients with CCP, but comparison by immunoassay of lithostathine concentrations in the pancreatic juices of patients and controls led to conflicting results. This study shows that these discrepancies might have been caused in part by a remarkably high susceptibility of the protein to trypsin like cleavage, resulting in important structural changes and concomitant modifications of the epitopes. A novel lithostathine assay in juice was developed, based on separation of secretory proteins by high performance liquid chromatography. The chromatographic separation of lithostathine was based on hydrophobic interactions at pH 5.0 using a Phenyl-TSK column. This study showed with this assay that lithostathine concentrations (microgram/mg of total protein) were similar in CCP patients with alcoholic aetiology (mean (SD) 6.3 (2.7)) and other aetiologies (7.2 (3.7)), but one third of those estimated in patients without pancreatic disease (16.7 (4.3)). Similar concentrations were found, however, in chronic alcoholic patients without CCP (6.6 (3.3)) and in patients with CCP. It was concluded that decreased lithostathine concentration is associated with CCP, although such a decrease is not sufficient by itself for the disease to occur.

Analysis of the soluble organic matrix of five morphologically different kidney stones. Evidence for a specific role of albumin in the constitution of the stone protein matrix.

Our aims were to analyze the protein composition of the organic matrix of urinary stones and to investigate the role of albumin in its constitution. Five different morphological types of stones were studied. Proteins extracted from the stone were submitted to sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) and analyzed by immunoblotting with antibodies to 13 urinary proteins. Nine of the 13 proteins were found in all types of stone: human serum albumin (HSA), alpha 1-acid glycoprotein (alpha 1-GP), alpha 1-microglobulin (alpha 1-M), immunoglobulins (Igs), apolipoprotein A1 (apo-A1), transferrin (Tr), alpha 1-antitrypsin (alpha 1-T), retinol-binding protein (RBP) and renal lithostathine (RL). The beta 2-microglobulin (beta 2-M) was present only in calcium oxalate and uric acid stones. In contrast, ceruloplasmin, haptoglobin and Tamm-Horsfall protein (THP) were detected in none of them. Because HSA appeared as the major protein component in all stones, we wondered whether it might play a specific role in the constitution of the stone matrix. Association of HSA with urinary proteins that were present in stones was demonstrated by showing that proteins present in the matrix comigrated with HSA on gel filtration, whereas proteins that were absent did not. Moreover, HSA induced the binding of stone matrix proteins to an albumin-specific affinity column. Finally, we evidenced HSA binding to calcium oxalate monohydrate (COM) crystals in a solution similar to urine.(ABSTRACT TRUNCATED AT 250 WORDS)

Reductive alkylation of lysine residues in subtilisin DY.

Only lysine epsilon-amino groups (and the N-terminal alpha-amino group) in native subtilisin DY were reductively alkylated by glyceraldehyde in the presence of sodium cyanoborohydride. The modified protein molecule was cleaved by TosPheCH2Cl-trypsin or cyanogen bromide and the two sets of peptides obtained were fractionated and purified by gel filtration and HPLC. For determination of the degree of modification of each lysine residue, selected peptides were subjected to sequence analysis combined with quantitative estimation of the containing PTH-Lys and PTH-epsilon-DHP-Lys. The data obtained showed that the lysine residues in positions 12, 15, 27, 43, 136, 141, 265 were entirely modified, those in positions 170, 184, 237 were partially modified, and Lys22 and Lys94 were unaccessible for the reagent. The caseinolytic activity decreased by 23% when the maximum number of lysine residues (8.6 of the total 12 residues) in subtilisin DY were modified. The CD-spectra of native and modified enzyme showed only slight differences. Both these experiments suggest that the lysine residues do not take part directly in the catalytic reaction but are responsible for maintaining the native three-dimensional enzyme structure. The data obtained for the accessibility of the different lysine residues in subtilisin DY correlated very well with the positions of these residues in a video model of the structure of subtilisin Carlsberg, thus suggesting that the spatial structures of these two enzymes are very similar.

Preparation and characterization of N epsilon-(2,3-dihydroxypropyl)-L-lysine and its phenylthiohydantoin derivative.

Convenient methods for preparative synthesis of N epsilon-(2,3-dihydroxypropyl)-L-lysine and its phenylthiohydantoin derivative are described. The former compound was characterized by elemental analysis, melting point, and ion-exchange chromatography and the latter by elemental analysis, melting point, UV-spectrum, HPLC and thin-layer chromatography. This study was performed for investigations of lysine residues in proteins.

Factors limiting the hydrolysis of casein by subtilisin DY.

It was shown that during the subtilisin DY-induced hydrolysis of casein relatively stable polypeptide structures are formed. In their interior these structures contain peptide bonds which are susceptible to the enzyme used. Heating (up to 100 degrees C) and/or application of ultrasound (25 kHz, 60 W) results in their unfolding. Data are provided, which show that under the enzyme-substrate complex formation does not lead to an enzyme conformation more susceptible to autolysis. Taking into account the described phenomena a higher degree of hydrolysis was attained in comparison to those obtained by standard enzymatic hydrolysis.

Methionine residue accessibility in native subtilisin DY.

The three methionine residues of subtilisin DY were specifically modified into methionine sulfoxide using increasing amounts of chloramine T. By means of subsequent treatment with cyanogen bromide, gel chromatography, Edman degradation of the obtained peptides and the known structure of subtilisin DY it was established that Met222 is exposed to the surrounding solution, Met124 is partially exposed and Met199 is buried. The data obtained were confirmed on a computer graphics space movable model of subtilisin Carlsberg where Met222 was seen to be on the surface of the molecule and Met199 shielded by Tyr262, Ala179 and Leu196. Upon oxidation of Met222 of subtilisin DY by chloramine T, 25% of its caseinolytic activity was lost. This can be explained by the immediate adjacency to the active-site Ser221. An additional 5% loss of activity was observed at each subsequent methionine modification.

Preparation and characterization of 5-(4-hydroxy-3-nitrobenzyl)-3-phenyl-2-thiohydantoin, the phenylthiohydantoin derivative of 3-nitrotyrosine.

The phenylthiocarbamoyl derivative of 3-nitrotyrosine was synthesized according to the known Edman method and then converted to its phenylthiohydantoin derivative [5-(4-hydroxy-3-nitrobenzyl)-3-phenyl-2-thiohydantion] by incubation in 0.5M HCl for 24 h at room temperature. After drying over P2O5 the chromatographically pure substance could be obtained by double recrystallization from hot acetic acid. It could be established that a shorter incubation time leads to an incomplete conversion and higher temperatures cause polymerization of the product. The compounds could be characterized by thin-layer and high-performance liquid chromatography, melting point, elemental analysis as well as NMR- and absorption spectroscopy.

Topography of all tyrosine residues in subtilisin DY.

The extracellular alkaline proteinase subtilisin DY was nitrated with increasing amounts of tetranitromethane. At 2-fold molar excess of the reagent with respect to the tyrosine residues in the enzyme, when 1.3 residues were modified, a peak of the caseinolytic activity (13% increase) was observed. Evidence is provided that the diminishing of the pK of the phenolic hydroxyl group in Tyr(3NO2)104 causes this phenomenon. The products obtained after nitration of the enzyme with 5-fold and 200-fold molar excess of tetranitromethane were cleaved by trypsin and cyanogen bromide and the peptides obtained were studied by analysis with respect to the tyrosine and 3-nitrotyrosine residues. Their degree of substitution was established. Tyrosine-104 was the first modified residue, then follow the residues with numbers 57, 143, 206, 262 and somewhat later 21, 209, 263, all fully modified by 200-fold molar excess of the reagent. Partial modification was observed at numbers 91, 167, 214, 238 and no modification at numbers 6 and 171. It has been established that the nonmodified residues are buried inside the molecule and the partially modified residues are screened by the side chains of lysine, valine, leucine, and tryptophan as seen on a working video three-dimensional model of subtilisin Carlsberg. The approach for characterization of tyrosyl groups in proteins based on peptide sequencing and HPLC quantitation of the phenylthiohydantoin derivatives of tyrosine and 3-nitrotyrosine was further developed with respect to the quantitation of the HPLC-separated peptides using fragments of the protein studied.