Biochemical characterization of lysozymes present in egg white of selected species of anatid birds

The isolation of lysozyme from the egg white of several representative species of waterfowl is described. The purified lysozymes were analyzed to determine the type and molecular weight of each enzyme. All enzymes found in duck egg whites were found to be of the c-type. In contrast all true geese, and the mute swan species as well as the northern blackneck screamer contain lysozyme g in their egg white.     

Heterogeneity of serum, egg amylase and egg lysozyme in the interspecific hybrids of ducks

Polymorphism of serum and egg amylase by means of horizontal agarose gel electrophoresis and egg lysozyme by means of horizontal starch gel electrophoresis in Pekin, Muscovy ducks and their interspecific hybrids was studied. In the interspecific hybrids of ducks the codominant type of heredity of serum, egg yolk and egg white amylase isozymes, as well as egg white lysozyme, were found.     

Enhancement in the lysozyme activity of the hen egg white foam matrix by cross-linking in the presence of N-acetyl glucosamine.

Lysozyme naturally present in raw hen egg white was immobilized by cross-linking the egg white foam with glutaraldehyde. Inclusion of N-acetyl glucosamine, a competitive inhibitor of lysozyme, was found to enhance the yield of lysozyme activity by fivefold.     

A New Method for the Analysis of Fatty Acid Mixtures by Gas Chromatography

Deamidation of lysozyme was observed during storage in a buffer solution and in egg white. The peak corresponding to native lysozyme from Bio-Rex 70 column chromatography was gradually decreased, while the peaks corresponding to deamidated lysozyme were increased during storage in 0.1 m carbonate buffer at pH 9.5. A similar change was observed during storage in egg white, but the change in egg white was larger than that in the buffer solution. A detailed analysis of the elution peaks from the Bio-Rex 70 column suggested that one to three residues of amide in lysozyme were mainly deamidated during storage in the buffer solution, and that more than three residues in lysozyme were deamidated during storage in egg white. There were significant differences in lysozyme activity between native and deamidated lysozyme, the activity being decreased in proportion to the degree of deamidation.     

Separation of lysozyme using superparamagnetic carboxymethyl chitosan nanoparticles

Functionalized Fe(3)O(4) nanoparticles conjugated with polyethylene glycol (PEG) and carboxymethyl chitosan (CM-CTS) were developed and used as a novel magnetic absorbing carrier for the separation and purification of lysozyme from the aqueous solution and chicken egg white, respectively. The morphology of magnetic CM-CTS nanoparticles was observed by transmission electron microscope (TEM). It was found that the diameter of superparamagnetic carboxymethyl chitosan nanoparticles (Fe(3)O(4) (PEG+CM-CTS)) was about 15 nm, and could easily aggregate by a magnet when suspending in the aqueous solution. The adsorption capacity of lysozyme onto the superparamagnetic Fe(3)O(4) (PEG+CM-CTS) nanoparticles was determined by changing the medium pH, temperature, ionic strength and the concentration of lysozyme. The maximum adsorption loading reached 256.4 mg/g. Due to the small diameter, the adsorption equilibrium of lysozyme onto the nanoparticles reached very quickly within 20 min. The adsorption equilibrium of lysozyme onto the superparamagnetic nanoparticles fitted well with the Langmuir model. The nanoparticles were stable when subjected to six repeated adsorption-elution cycles. Separation and purification were monitored by determining the lysozyme activity using Micrococcus lysodeikticus as substrate. The lysozyme was purified from chicken egg white in a single step had higher purity, as determined by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). Considering that the superparamagnetic nanoparticles possess the advantages of high efficiency, cost-effectiveness and excellent binding of a larger amount of lysozyme and easier separation from the reaction system, thus this type of superparamagnetic nanoparticles would bring advantages to the conventional separation techniques of lysozyme from chicken egg white.     

Identification of a Component of Crystalline Egg Albumin Bactericidal for Thermophilic Aerobic Sporeformers

During an investigation of the effect of basic and acidic proteins on the growth of thermophilic aerobic sporeformers, crystalline egg albumin was found to be strongly bactericidal. This finding was uncharacteristic of acidic proteins. The bactericidal fraction was heat sensitive and separated from the non-bactericidal albumin fraction during gel filtration on Sephadex G-75. Cells of Micrococcus lysodeikticus and Bacillus stearothermophilus were lysed rapidly by the bactericidal component, leading to its tentative identification as lysozyme. The bactericidal substance possessed an electrophoretic mobility on polyacrylamide gel containing sodium dodecyl sulfate identical to that of crystalline egg white lysozyme. Users of crystalline egg albumin are cautioned that commerical preparations may be contaminated with lysozyme. Destruction of the thermophilic aerobes by lysozyme should be considered when performing counts on egg products.     

Purification of camel milk lysozyme and its lytic effect on Escherichia coli and Micrococcus lysodeikticus

1. Camel milk lysozyme was purified using heparin-Sepharose 4B, Sephadex G-75 and hydroxyapatite chromatography. By this procedure lysozyme was separated from lactoferrin and a low molecular weight protein. 2. The lytic effect of camel milk lysozyme was assayed using Escherichia coli and Micrococcus lysodeikticus and its activity was compared with that of lysozyme from human milk and egg white. 3. The specific activity of camel milk lysozyme was found to be lower than that of lysozyme from human milk or from egg white. 4. Camel milk lactoferrin did not show a lytic effect on bacteria, while the low molecular weight protein showed lytic activity.     

Enhanced C-type lysozyme content of wood duck (Aix sponsa) egg white: an adaptation to cavity nesting?

Abstract Wild waterfowl species often nest in conditions where high humidity and microbial contamination may influence egg survival and quality. Albumen is traditionally regarded as the major impediment to microbial contamination of eggs, and its composition and activity may be selected by environmental pressures. Egg white protein from the eggs of wood duck (Aix sponsa), hooded merganser (Lophodytes cucullatus), Canada goose (Branta canadensis), and mute swan (Cygnus olor) was evaluated in order to compare the antimicrobial defenses of these species. Ovotransferrin and ovalbumin were identified in all species, but c-type lysozyme was present only in wood duck and hooded merganser egg white samples. Wood duck egg white showed the greatest bacterial activity as well as the highest lysozyme content. Egg white from wood duck and hooded merganser possessed greater lysozyme activity under acidic conditions, suggesting a c-type lysozyme with a pH optimum lower than that of Gallus gallus c-type lysozyme or the presence of g-type lysozyme. Ovotransferrin bacteriostatic activity appeared to be similar across the species investigated. The results suggest that lysozyme and ovotransferrin play a role in the antimicrobial defense of the avian egg. High levels of the broad-acting c-type lysozyme appear to have evolved in the albumen of the wood duck in order to ensure proper development of the embryo in the humid conditions of the cavity nest.     

Three-dimensional structure of goose-type lysozyme from the egg white of the Australian black swan, Cygnus atratus

The egg white of C. atratus contains two forms of lysozyme, a 'chick-type' which is similar to that found in the egg white of the domestic hen, and a 'goose-type' similar to that found in the egg white of the Embden goose. The molecular structure of the goose-type lysozyme has been determined at a resolution of a 2.8 A by X-ray crystallographic analysis. The structure consists of two domains linked by a long stretch of alpha-helix. In all, there are seven helical segments in the structure. While there is no amino acid sequence homology with either hen egg-white or bacteriophage T4 lysozymes, there are portions of the structure where the folding of the main chain is similar to that found in portions of either hen egg-white lysozyme or T4 lysozyme or both. In particular, there is a consistency of structure in the arrangement of acid groups in the catalytic site. G-o plots calculated for this structure and for the bacteriophage T4 lysozyme structure show that both have similar 'modules' of structure with boundaries occurring at structurally equivalent positions. Three of the common boundaries are equivalent structurally to three of the four module boundaries observed in G-o plots of hen egg-white lysozyme. The variation in the position of the remaining boundary may be related to differences in substrate binding.     

Pilot-scale separation of lysozyme from hen egg white by integrating aqueous two-phase partitioning and membrane separation processes

A novel, cost-effective method of lysozyme separation from hen egg white was studied. This method integrates aqueous two-phase partitioning in the system EO₅₀PO₅₀/phosphates with membrane separation processes. The experiments were carried out in a pilot-scale on crude hen egg white.Initially, by forming an aqueous two-phase system, lysozyme was selectively extracted to the upper, polymer-rich phase while the other egg white proteins partitioned to the lower, phosphate-rich phase. Then, in order to recover lysozyme, thermoseparation of polymer-rich phase was applied. A novel approach for the simultaneous thermoseparation of the polymer-rich phase as well as for the recovery of the lysozyme was proposed, using a cross-flow microfiltration. Additionally, recovery of proteins by ultrafiltration from lower, phosphate-rich phase was also investigated.Lysozyme could be obtained after the thermal phase separation by means of microfiltration at a total recovery over the extraction steps of 47.5 and the purification factor of 10.5. The specific activity of lysozyme preparations was 34 188 U/mg of protein. Using cross-flow membrane techniques, it was found that the recovery of the polymer by microfiltration from the top phase was 83.9.     

Linear correlation between thermal stability and folding kinetics of lysozyme

We have studied the refolding and thermal denaturation of hen egg white lysozyme in a wide range of pH values (from 1.5 to 9.4) using stopped-flow circular dichroism (CD) and differential scanning calorimetry (DSC). A linear correlation was found between the thermal denaturation temperature (T(m)) and the logarithm of the refolding rate of the slow folding phase of hen egg white lysozyme (lnk(2)).     

Purification and Properties of Lysozyme Produced by Staphylococcus aureus

A method based on cold ethyl alcohol fractionation at different pH levels and ionic strengths and on gel filtration on a Sephadex G-200 column was used to concentrate and purify lysozyme from the culture supernatant fluid of Staphylococcus aureus strain 524. The final, nondialyzable product exhibited a 163-fold rise in specific activity over that of the starting material. Staphylococcal lysozyme is a glycosidase which splits N-acetylamino sugars from the susceptible substrate. Staphylococcal lysozyme was shown to be similar to egg white lysozyme in its optimal temperature for reaction, optimal pH, activation by NaCl and Ca(++) ions, inhibition by sodium citrate and ethylenediaminetetraacetate, and inactivation by Cu(++) ions and sodium dodecyl sulfate. It differs from the egg white lysozyme in its temperature susceptibility range (staphylococcal lysozyme is inactivated at 56 C). It acts on whole cells and cell walls of Micrococcus lysodeikticus, murein from S. aureus 524, and cell walls of S. epidermidis Zak. The last substrate was not susceptible to the action of egg white lysozyme in the test system used. The mechanism of action of staphylococcal lysozyme seems to be analogous to that of egg white lysozyme; however, the biological specificity of the two enzymes may be different.     

General Properties of Endo-N-acetylmuramidase of Bacillus subtilis YT-25

The enzymatic behaviour, amino acid composition and some physical properties of a new endo-N-acetylmuramidase (B-enzyme) of Bacillus subtilis YT–25 were determined and compared with hen’s egg white lysozyme. The molecular weight was estimated to be about 13000 by the sedimentation equilibrium method. The isoelectric point was pH 9.8. The amino acid composition indicates that the enzyme is rich in basic amino acids, especially lysin. Maximal activity on the lysis of cell walls of M. lysodeikticus occurred at pH 6.2. The enzyme was stable at pH 3.5 ~ 6.0. The specific activity for the lysis of cell walls of M. lysodeikticus was less than fourth part of that of hen’s egg white lysozyme. Digest of cell walls of M. lysodeikticus with B-enzyme consisted greater numbers of high molecular products than digest with egg white lysozyme. Substrate specificity of B-enzyme seemed to be different from that of egg white lysozyme.     

Redesign of the substrate-binding site of hen egg white lysozyme based on the molecular evolution of C-type lysozymes.

On the basis of the molecular evolution of hen egg white, human, and turkey lysozymes, three replacements (Trp62 with Tyr, Asn37 with Gly, and Asp101 with Gly) were introduced into the active-site cleft of hen egg white lysozyme by site-directed mutagenesis. The replacement of Trp62 with Tyr led to enhanced bacteriolytic activity at pH 6.2 and a lower binding constant for chitotriose. The fluorescence spectral properties of this mutant hen egg white lysozyme were found to be similar to those of human lysozyme, which contains Tyr at position 62. The replacement of Asn37 with Gly had little effect on the enzymatic activity and binding constant for chitotriose. However, the combination of Asn37----Gly (N37G) replacement with Asp101----Gly (D101G) and Trp62----Tyr (W62Y) conversions enhanced bacteriolytic activity much more than each single mutation and restored hydrolytic activity toward glycol chitin. Consequently, the mutant lysozyme containing triple replacements (N37G, W62Y, and D101G) showed about 3-fold higher bacteriolytic activity than the wild-type hen lysozyme at pH 6.2, which is close to the optimum pH of the wild-type enzyme.     

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.     

The calcium-binding property of equine lysozyme

It was found that equine lysozyme binds one Ca2+. It was eluted with equimolar Ca2+ from a Bio-Gel P-4 column. Human lysozyme did not behave similarly. Equine lysozyme is concluded to be a calcium metallo-protein like alpha-lactalbumin, which is a homologue of hen egg white lysozyme.     

Purification of the basic protein avidin using Gradiflow technology

The Gradiflow, a preparative electrophoresis instrument, which separates proteins on the basis of charge or size, was used to purify the basic protein avidin, pI 10, from chicken egg white. Using a charge based separation at pH 9.0, the high pI of avidin and lysozyme (pI 10.7) allows them to be easily separated from remaining egg white proteins, as these are the only positively charged proteins. In a second step at pH 10.2, the negatively charged avidin is separated from the positively charged lysozyme. This sequential two-step protocol was complete within 4.5h. Enzyme immunoassay of avidin fractions obtained indicated recoveries of 60-65% from one egg white with minimal lysozyme activity detected.     

Disulfide content of reduced hen egg white and human milk lysozymes during the folding process

In order to obtain a better understanding of the possible influence of the primary sequence of a protein on its folding pathway, renaturation of reduced human milk lysozyme was compared to that of reduced hen egg white lysozyme. Following disulfide bond formation, under identical conditions, similar products were found during the folding of both lysozymes, but the kinetics of appearance and disappearance of these intermediates as well as the appearance of the native conformation were different.     

Isolation of lysozyme on chitosan.

Lysozyme has been immobilized on chitosan, a polyaminosaccharide, without using any intermediate reagent. The best pH conditions for operating the chitosan columns have been determined and the best eluting agent was found to be a 2% solution of propylamine. The lysozyme activity was determined after reacting lysozyme with the product of glycolchitin and Remazol Brilliant Blue R. The recovery of lysozyme from chicken egg white yields lysozyme with 55% activity.