Complete amino acid sequence of three reptile lysozymes.

To study the structure and function of reptile lysozymes, we have reported their purification, and in this study we have established the amino acid sequence of three egg white lysozymes in soft-shelled turtle eggs (SSTL A and SSTL B from Trionyx sinensis, ASTL from Amyda cartilaginea) by using the rapid peptide mapping method. The established amino acid sequence of SSTL A, SSTL B, and ASTL showed substitutions of 43, 42, and 44 residues respectively when compared with the HEWL (hen egg white lysozyme) sequence. In these reptile lysozymes, SSTL A had one substitution compared with SSTL B (Gly126Asp) and had an N-terminal extra Gly and 11 substitutions compared with ASTL. SSTL B had an N-terminal extra Gly and 10 residues different from ASTL. The sequence of SSTL B was identical to soft-shelled turtle lysozyme from STL (Trionyx sinensis japonicus). The Ile residue at position 93 of ASTL is the first report in all C-type lysozymes. Furthermore, amino acid substitutions (Phe34His, Arg45Tyr, Thr47Arg, and Arg114Tyr) were also found at subsites E and F when compared with HEWL. The time course using N-acetylglucosamine pentamer as a substrate exhibited a reduction of the rate constant of glycosidic cleavage and increase of binding free energy for subsites E and F, which proved the contribution for amino acids mentioned above for substrate binding at subsites E and F. Interestingly, the variable binding free energy values occurred on ASTL, may be contributed from substitutions at outside of subsites E and F.

New variant of quail egg white lysozyme identified by peptide mapping.

Two lysozymes were purified from quail egg white by cation exchange column chromatography and analyzed for amino acid sequence. The enzymes showed the same pH optimum profile for lytic activity with broad pH optima (pH 5.0-8.0) but had difference in mobility on native-PAGE. The native-PAGE immunoblot showed one or two lysozymes present in individual egg whites. The established amino acid sequence of quail egg white lysozyme A (QEWL A) was the same as quail lysozyme reported by Kaneda et al. [Kaneda, M., Kato, I., Tominaga, N., Titani, K., Narita, K., 1969. The amino acid sequence of quail lysozyme. J. Biochem. (Tokyo). 66, 747-749] and had six amino acid substitutions at position 3 (Phe to Tyr), 19 (Asn to Lys), 21 (Arg to Gln), 102 (Gly to Val) 103 (Asn to His) and 121 (Gln to Asn) compared to hen egg white lysozyme. QEWL A and QEWL B showed one substitution, at the position 21, Gln replaced by Lys, plus an insertion of Leu between position 20 and 21, being the first report that QEWL B had 130 amino acids. The amino acid differences between two lysozymes did not seem to affect antigenic determinants detected by polyclonal anti-hen egg white lysozyme, but caused them to separate well from each other by ion exchange chromatography.

Purification, characterization and comparison of reptile lysozymes.

Cation exchange column chromatography and gel filtration chromatography were used to purify four reptile lysozymes from egg white: SSTL A and SSTL B from soft shelled turtle (Trionyx sinensis), ASTL from Asiatic soft shelled turtle (Amyda cartilagenea) and GSTL from green sea turtle (Chelonia mydas). The molecular masses of the purified reptile lysozymes were estimated to be 14 kDa by SDS-PAGE. Enzyme activity of the four lysozymes could be confirmed by gel zymograms and showed charge differences on native-PAGE. SSTL A, SSTL B and ASTL had sharp pH optima of about pH 6.0, which contrasts with that of GSTL, which showed dual pH optima at about pH 6.0 and pH 8.0. The activities of the reptile lysozymes rapidly decreased within 30 min of incubation at 90 degrees C except for ASTL, which was more stable. Partial N-terminal amino acid sequencing and peptide mapping strongly suggested that the enzymes were C-type lysozymes. Interestingly, the mature SSTL lysozymes show an extra Gly residue at the N-terminus, which was previously found in soft-shelled turtle lysozyme. The reptile lysozymes showed lytic activity against several species of bacteria, such as Micrococcus luteus and Vibrio cholerae, but showed only weak activity to Pseudomonas aeruginosa and lacked activity towards Aeromonas hydrophila.