Cloning and expression analysis of c-type and g-type lysozymes in yellow catfish (<Emphasis Type="Italic">Pelteobagrus fulvidraco</Emphasis>)

Lysozymes have important roles in innate immune system. Here, a c-type and a g-type lysozyme were identified from yellow catfish (Pelteobagrus fulvidraco). The deduced amino acid sequences of both lysozymes were conserved in catalytic sites and structural features as compared to their counterparts from other species. It was interesting that the g-type lysozyme possessed a signal peptide. The c-type and g-type lysozymes had the highest identity 89.4 and 76.2 % with that from channel catfish respectively. Phylogenetic analysis showed that the two lysozymes had a closely relationship with that from channel catfish and Astyanax mexicanus. Lysozymes from one order could form more than one clade in the phylogenetic tree, which indicated the gene duplications in evolution. Expression analysis with real time quantitative PCR revealed that the two lysozyme genes were constitutively expressed in all the tested tissues. The highest expression of c-type lysozyme was observed in liver, followed by spleen, head kidney, and trunk kidney, while the g-type lysozyme had highest expression in intestine, followed by spleen, head kidney, and trunk kidney. The mRNA levels of both genes were all up-regulated after challenging with Aeromonas hydrophila. However, there were differences in tissues and time points when the mRNA levels reached its peak between the two lysozymes. It indicated the diversity in regulation mechanisms and detailed functions among lysozymes. Taking together, these results will benefit the understanding of yellow catfish lysozymes.     

Structural evidence for lack of inhibition of fish goose-type lysozymes by a bacterial inhibitor of lysozyme

It is known that bacteria contain inhibitors of lysozyme activity. The recently discovered Escherichia coli inhibitor of vertebrate lysozyme (Ivy) and its potential interactions with several goose-type (g-type) lysozymes from fish were studied using functional enzyme assays, comparative homology modelling, protein–protein docking, and molecular dynamics simulations. Enzyme assays carried out on salmon g-type lysozyme revealed a lack of inhibition by Ivy. Detailed analysis of the complexes formed between Ivy and both hen egg white lysozyme (HEWL) and goose egg white lysozyme (GEWL) suggests that electrostatic interactions make a dominant contribution to inhibition. Comparison of three dimensional models of aquatic g-type lysozymes revealed important insertions in the β domain, and specific sequence substitutions yielding altered electrostatic surface properties and surface curvature at the protein–protein interface. Thus, based on structural homology models, we propose that Ivy is not effective against any of the known fish g-type lysozymes. Docking studies suggest a weaker binding mode between Ivy and GEWL compared to that with HEWL, and our models explain the mechanistic necessity for conservation of a set of residues in g-type lysozymes as a prerequisite for inhibition by Ivy.     

Detection of chitinase activity after polyacrylamide gel electrophoresis

Commercial Streptomyces griseus and Serratia marcescens chitinases and purified wheat germ W1A and hen egg white lysozymes were subjected to polyacrylamide gel electrophoresis under native conditions at pH 4.3. After electrophoresis, an overlay gel containing 0.01% (W/V) glycol chitin as substrate was incubated in contact with the separation gel. Lytic zones were revealed by uv illumination with a transilluminator after staining for 5 min with 0.01% (W/V) Calcofluor white M2R. As low as 500 ng of purified hen egg lysozyme could be detected after 1 h incubation at 37 degrees C. One band was observed with W1A lysozyme and several bands with the commercial microbial chitinases. The same system was also used with native polyacrylamide gel electrophoresis at pH 8.9. Several bands were detected with the microbial chitinases. The same enzymes were also subjected to denaturing polyacrylamide gel electrophoresis in gradient gels containing 0.01% (W/V) glycol chitin. After electrophoresis, enzymes were renatured in buffered 1% (V/V) purified Triton X-100. Lytic zones were revealed by uv after staining with Calcofluor white M2R as for native gels. The molecular weights of chitinolytic enzymes could thus be directly estimated. In denaturing gels, as low as 10 ng of purified hen egg white lysozyme could be detected after 2 h incubation at 37 degrees C. Estimated molecular weights of St. griseus and Se. marcescens were between 24,000 and 72,000 and between 40,500 and 73,000, respectively. Some microbial chitinases were only resistant to denaturation with sodium dodecyl sulfate while others were resistant to sodium dodecyl sulfate and beta-mercaptoethanol.     

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.     

Frog lysozyme. V. Isolation and some physical and immunochemical properties of lysozyme isozymes of the leopard frog, Rana pipiens.

Frog Lysozyme has been purified by sequential application of acid extraction, salt fractionation, CM-cellulose chromatography, heat treatment, and gel filtration. Eight isozymes of purified lysozyme were found to be stable during prolonged storage. Isozymes were separated by preparative polyacrylamide gel electrophoresis, Ninety percent of the lytic activity of frog ovarian egg was represented by forms 7 and 8, the most highly charged isozymes. Seventy-eight percent of frog liver lysozyme activity was that of form 4. Forms 7 and 8 differed from form 4 by being larger (apparent molecular weight of 18,000 vs. 16,000), by remaining active in more acidic environment, and by exhibiting a dependency upon NaCl for activity. Antiserum prepared against frog form 4 did not react with frog forms 7 and 8 and antiserum to chicken egg-white lysozyme did not react with any frog lysozymes. All frog lysozymes showed identical reversible binding to deaminated chitin. Apparent size differences and lack of immunological cross-reactivity suggest that at least some of the isozymes are non-allelic.     

Heterogeneity of mammalian DNA ligase detected on activity and DNA sequencing gels.

A new method to detect DNA ligase activity in situ after NaDodSO4 polyacrylamide gel electrophoresis has been developed. After renaturation of active polypeptides the ligase reaction occurs in situ by incubating the intact gel in the presence of Mg++ and ATP. Further treatment with alkaline phosphatase removes the unligated 5'-32P-end of oligo (dT) used as a substrate and active polypeptides having ligase activity are identified by autoradiography. Analysis on DNA sequencing gels of the oligo (dT) reaction products present in the activity bands ensures that the radioactive material detected in activity gels or in standard in vitro ligase assays corresponds unambiguously to a ligase activity. Using these methods, we have analysed the purified phage T4 DNA ligase, and the activities present in crude extracts and in purified fractions from monkey kidney (CV1-P) cells. The purified T4 enzyme yields one or two active peptides with Mr values of 60,000 and 70,000. Crude extracts from CV1-P cells contain several polypeptides having DNA ligase activity. Partial purification of these extracts shows that DNA ligase I isolated from hydroxylapatite column is enriched in polypeptides with Mr 200,000, 150,000 and 120,000, while DNA ligase II is enriched in those with Mr 60,000 and 70,000.     

七鳃鳗g型溶菌酶的分子特征和抗菌活性

溶菌酶是先天免疫系统中对抗细菌病原体感染的一种关键蛋白．本研究从七鳃鳗中克隆g型溶菌酶基因. 其酶基因cDNA为701 bp（GenBank 序列号KP204854）,开放阅读框为555 bp,编码由184个氨基酸组成的多肽,理论分子质量为20.24 kD,等电点为5.48,含有1个半胱氨酸残基,无信号肽．实时荧光定量PCR分析表明,七鳃鳗g型溶菌酶基因在各组织中广泛表达,其中在肠中表达量最高．脂多糖（LPS）体内刺激七鳃鳗后发现,溶菌酶在口腔腺和头肾表达量显著升高．以溶壁微球菌和哈维弧菌为底物检测重组g型溶菌酶的活性时,均表现出抗菌活性,最适pH为7.5,最适温度为35℃．扫描电镜分析表明,重组酶能够使溶壁微球菌破裂．以上结果均表明,g型溶菌酶在七鳃鳗的先天免疫系统防御病菌感染中起到重要作用．     

Egg white lysozyme is the major protein of the hen's egg vitelline membrane

Lysozyme accounts for 37% of the proteins of the hen's egg vitelline membrane. It can be extracted by salt solutions and purified by gel filtration on Sephadex G-50. There are no differences between the chemical and enzymic properties of egg white and vitelline membrane lysozymes. Vitelline membranes of ovarian eggs do not contain lysozyme. It is thus concluded that lysozyme is localized in the outer layer. Vitelline membranes from fertilized and unfertilized eggs contain the same amount of lysozyme; its percentage decreases after two days of incubation.     

Crystal structures of K33 mutant hen lysozymes with enhanced activities

Using random mutagenesis, we previously obtained K33N mutant lysozyme that showed a large lytic halo on the plate coating Micrococcus luteus. In order to examine the effects of mutation of K33N on enzyme activity, we prepared K33N and K33A mutant lysozymes from yeast. It was found that the activities of both the mutant lysozymes were higher than those of the wild-type lysozyme based on the results of the activity measurements against M. luteus (lytic activity) and glycol chitin. Moreover, 3D structures of K33N and K33A mutant lysozyme were solved by X-ray crystallographic analyses. The side chain of K33 in the wild-type lysozyme hydrogen bonded with N37 involved in the substrate-binding region, and the orientation of the side chain of N37 in K33 mutant lysozymes were different in the wild-type lysozyme. These results suggest that the enhancement of activity in K33N mutant lysozyme was due to an alteration in the orientation of the side chain of N37. On the other hand, K33N lysozyme was less stable than the wild-type lysozyme. Lysozyme may sacrifice its enzyme activity to acquire the conformational stability at position 33.     

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, amino acid sequence, and some properties of rabbit kidney lysozyme

The lysozyme (rabbit kidney lysozyme) from the homogenate of rabbit kidney (Japanese white) was purified by repeated cation-exchange chromatography on Bio-Rex 70. The amino acid sequence was determined by automated gas-phase Edman degradation of the peptides obtained from the digestion of reduced and S-carboxymethylated rabbit lysozyme with Achromobacter protease I (lysyl endopeptidase). The sequence thus determined was KIYERCELARTLKKLGLDGYKGVSLANWMCLAKWESSYNTRATNYNPGDKSTDYGIFQ INSRYWCNDGKTPRAVNACHIPCSDLLKDDITQAVACAKRVVSDPQGIRAWVAWRNHCQ NQDLTPYIRGCGV, indicating 25 amino acid substitutions from human lysozyme. The lytic activity of rabbit lysozyme against Micrococcus lysodeikticus at pH 7, ionic strength of 0.1, and 30 degrees C was found to be 190 and 60% of those of hen and human lysozymes, respectively. The lytic activity-pH profile of rabbit lysozyme was slightly different from those of hen and human lysozymes. While hen and human lysozymes had wide optimum activities at around pH 5.5-8.5, the optimum activity of rabbit lysozyme was at around pH 5.5-7.0. The high proline content (five residues per molecule compared with two prolines per molecule in hen or human lysozyme) is one of the interesting features of rabbit lysozyme. The transition temperatures for the unfolding of rabbit, human, and hen lysozymes in 3 M guanidine hydrochloride at pH 5.5 were 51.2, 45.5, and 45.4 degrees C, respectively, indicating that rabbit lysozyme is stabler than the other two lysozymes. The high proline content may be responsible for the increased stability of rabbit lysozyme.     

Characterization of lysozyme synthesized by differentiated mouse myeloid leukemia cells.

Lysozyme was induced by dexamethasone during normal differentiation of cultured mouse myeloid leukemia cells (M1) to macrophages and granulocytes. A large amount of lysozyme was produced by macrophage-like line cells (Mm-1), established from spontaneously differentiated macrophage-like cells from a clonal line of M1 cells. Lysozyme purified from the culture medium of these Mm-1 cells (Mm-1 lysozyme) had a molecular weight of 15,000, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and showed maximal activity at pH 6.6 with an optimal NaCl concentration of 0.04 M. Its mobility on polyacrylamide gel electrophoresis at pH 4.5 was distinctly lower than those of lysozymes from hen egg white and human urine. Rabbit anti-Mm-1 lysozyme serum inhibited the activities of lysozyme preparations from peritoneal macrophages of normal mice and rats and dexamethasone-induced differentiated M1 cells, but not those of preparations from hen egg white and human urine. Lysozyme was also purified from normal mouse lung, which is rich in alveolar macrophages and was found to be similar to lysozyme purified from the culture medium of Mm-1 cells in size and electrophoretic mobility and in its pH optimum, trypsin peptide map, and antigenicity. Thus the molecular structure of the lysozyme induced in differentiated mouse myeloid leukemia cells is similar to that of lysozyme produced by normal cells.     

Purification and characterization of alpha-amylase from rat pancreatic acinar carcinoma. Comparison with pancreatic alpha-amylase.

alpha-Amylase was purified to apparent homogeneity from normal pancreas and a transplantable pancreatic acinar carcinoma of the rat by affinity chromatography on alpha-glucohydrolase inhibitor (alpha-GHI) bound to aminohexyl-Sepharose 4B. Recovery was 95-100% for both pancreas and tumour alpha-amylases. They were monomeric proteins, with Mr approx. 54000 on SDS/polyacrylamide-gel electrophoresis. Isoelectric focusing of both normal and tumour alpha-amylases resolved each into two major isoenzymes, with pI 8.3 and 8.7. Tumour-derived alpha-amylase contained two additional minor isoenzymes, with pI 7.6 and 6.95 respectively. All four tumour isoenzymes demonstrated amylolytic activity when isoelectric-focused gels were treated with starch and stained with iodine. Two-dimensional electrophoresis, on SDS/10-20%-polyacrylamide-gradient gels after isoelectric focusing, separated each major isoenzyme into doublets of similar Mr values. Pancreatic and tumour-derived alpha-amylases had similar Km and Ki (alpha-GHI) values, but the specific activity of the tumour alpha-amylase was approximately two-thirds that of the normal alpha-amylase. Although amino acid analysis and peptide mapping with the use of CNBr, N-chlorosuccinimide or Staphylococcus aureus V8 proteinase gave comparable profiles for the two alpha-amylases, tryptic-digest fingerprint patterns were different. Antibodies raised against the purified pancreatic alpha-amylase and tumour alpha-amylase respectively showed only one positive band on immunoblotting after gel electrophoresis of crude extracts of rat pancreas and carcinoma, at the same position as that of the purified enzyme. More than 95% of the alpha-amylase activity in the pancreas and in the tumour was absorbed by an excess amount of either antibody, indicating that normal and tumour alpha-amylases are immunologically identical. The presence of additional isoenzymes in the carcinoma, and dissimilarity of tryptic-digest patterns, may reflect an alteration in gene expression or in the post-translational modification of this protein in this heterogeneously differentiated transplantable pancreatic acinar carcinoma.     

Structural analysis of an insect lysozyme exhibiting catalytic efficiency at low temperatures

Bombyx mori lysozyme (BmLZ), from the silkworm, is an insect lysozyme. BmLZ has considerable activity at low temperatures and low activation energies compared with those of hen egg white lysozyme (HEWLZ), according to measurements of the temperature dependencies of relative activity (lytic and glycol chitin) and the estimation of activation energies using the Arrhenius equation. Being so active at low temperatures and low activation energies is characteristic of psychrophilic (cold-adapted) enzymes. The three-dimensional structure of BmLZ has been determined by X-ray crystallography at 2.5 A resolution. The core structure of BmLZ is similar to that of c-type lysozymes. However, BmLZ shows some distinct differences in the two exposed loops and the C-terminal region. A detailed comparison of BmLZ and HEWLZ suggests structural rationalizations for the differences in the catalytic efficiency, stability, and mode of activity between these two lysozymes.