Dynamics of hydration in hen egg white lysozyme

We investigate the hydration dynamics of a small globular protein, hen egg-white lysozyme. Extensive simulations (two trajectories of 9 ns each) were carried out to identify the time-scales and mechanism of water attachment to this protein. The location of the surface and integral water molecules in lysozyme was also investigated. Three peculiar temporal scales of the hydration dynamics can be discerned: two among these, with sub-nanosecond mean residence time, tau(w), are characteristic of surface hydration water; the slower time-scale (tau(w) approximately 2/3 ns) is associated with buried water molecules in hydrophilic pores and in superficial clefts. The computed tau(w) values in the two independent runs fall in a similar range and are consistent with each other, thus adding extra weight to our result. The tau(w) of surface water obtained from the two independent trajectories is 20 and 24 ps. In both simulations only three water molecules are bound to lysozyme for the entire length of the trajectories, in agreement with nuclear magnetic relaxation dispersion estimates. Locations other than those identified in the protein crystal are found to be possible for these long-residing water molecules. The dynamics of the hydration water molecules observed in our simulations implies that each water molecule visits a multitude of residues during the lifetime of its bound with the protein. The number of residues seen by a single water molecule increases with the time-scale of its residence time and, on average, is equal to one only for the water molecules with shorter residence time. Thus, tau(w) values obtained from inelastic neutron scattering and based on jump-diffusion models are likely not to account for the contribution of water molecules with longer residence time.     

The stability curve of hen egg white lysozyme

The physiological stability curve--a plot of the free energy of unfolding versus temperature--is calculated for hen egg white lysozyme from a combination of extrapolated unfolding thermodynamic data from reversible conditions and isothermal titrations with guanidine hydrochloride. The shape of the curve suggests the existence of only one folded conformation.     

Organic cosolvents and hen egg white lysozyme folding

Studies on the influence of organic cosolvents on lysozyme folding have been reported. As most of the researches are confined to a few specific molecules and focus on equilibrium states, less is known about the effect on folding dynamics. We have studied the influence of six soluble organic cosolvents on hen egg white lysozyme heat induced denaturation and refolding dynamics. It was found that trifluoroethanol (TFE) can change the folding pathway significantly. With the presence of TFE, the overshot phenomenon generally observed in lysozyme folding at 222 nm disappears. The common mechanism of how organic cosolvents influence folding is analyzed. The heat induced denaturation temperature was found to have a quantitative relationship with the slow phase rate constant during folding. We discuss this finding and hypothesize that it is due to the similar influence of organic cosolvent on the transition state of heat denaturation and refolding.     

Construction of a lactococcal expression vector: expression of hen egg white lysozyme in Lactococcus lactis subsp. lactis

A pair of vectors for expression of heterologous genes in Lactococcus lactis was constructed. In addition to an origin of replication that has a broad host range, these vectors contain a multiple cloning site flanked by gene expression signals originating from L. lactis subsp. cremoris Wg2. The two vectors, about 3.7 kilobase pairs in size, differ only in the type of antibiotic resistance they confer to their hosts. pMG36 carries a kanamycin resistance marker, which was replaced by an erythromycin resistance marker in pMG36e. As an example of the use of these vectors, the hen egg white lysozyme-coding sequence was inserted. A fusion protein of the expected size was detected in a transformed L. lactis subsp. lactis strain by using Western blotting (immunoblotting).     

Formation of amyloid fibrils from fully reduced hen egg white lysozyme

The fully reduced hen egg white lysozyme (HEWL), which is a good model of random coil structure, has been converted to highly organized amyloid fibrils at low pH by adding ethanol. In the presence of 90% (v/v) ethanol, the fully reduced HEWL adopts beta-sheet secondary structure at pH 4.5 and 5.0, and an alpha-to-beta transition is observed at pH 4.0. A red shift of the Congo red absorption spectrum caused by the precipitation of the fully reduced HEWL in the presence of 90% (v/v) ethanol is typical of the presence of amyloid aggregation. EM reveals unbranched fibrils with a diameter of 2-5 nm and as long as 1-2 microm. The pH dependence of the initial structure of the fully reduced HEWL in the presence of 90% (v/v) ethanol suggests that Asp and His residues may play an important role.     

Molecular dynamics simulation of thionated hen egg white lysozyme

Understanding of the driving forces of protein folding is a complex challenge because different types of interactions play a varying role. To investigate the role of hydrogen bonding involving the backbone, the effect of thio substitutions in a protein, hen egg white lysozyme (HEWL), was investigated through molecular dynamics simulations of native as well as partly (only residues in loops) and fully thionated HEWL using the GROMOS 54A7 force field. The results of the three simulations show that the structural properties of fully thionated HEWL clearly differ from those of the native protein, while for partly thionated HEWL they only changed slightly compared with native HEWL. The analysis of the torsional-angle distributions and hydrogen bonds in the backbone suggests that the α-helical segments of native HEWL tend to show a propensity to convert to 3(10)-helical geometry in fully thionated HEWL. A comparison of the simulated quantities with experimental NMR data such as nuclear overhauser effect (NOE) atom-atom distance bounds and (3)J((H)(N)(H)(α))-couplings measured for native HEWL illustrates that the information content of these quantities with respect to the structural changes induced by thionation of the protein backbone is rather limited.     

Thermally induced fibrillar aggregation of hen egg white lysozyme

We study the effect of pH and temperature on fibril formation from hen egg white lysozyme. Fibril formation is promoted by low pH and temperatures close to the midpoint temperature for protein unfolding (detected using far-ultraviolet circular dichroism). At the optimal conditions for fibril formation (pH 2.0, T = 57 degrees C), on-line static light-scattering shows the formation of fibrils after a concentration-independent lag time of approximately 48 h. Nucleation presumably involves a change in the conformation of individual lysozyme molecules. Indeed, long-term circular dichroism measurements at pH 2.0, T = 57 degrees C show a marked change of the secondary structure of lysozyme molecules after approximately 48 h of heating. From atomic force microscopy we find that most of the fibrils have a thickness of approximately 4 nm. These fibrils have a coiled structure with a periodicity of approximately 30 nm and show characteristic defects after every four or five turns.     

Construction of a lactococcal expression vector: expression of hen egg white lysozyme in Lactococcus lactis subsp. lactis.

A pair of vectors for expression of heterologous genes in Lactococcus lactis was constructed. In addition to an origin of replication that has a broad host range, these vectors contain a multiple cloning site flanked by gene expression signals originating from L. lactis subsp. cremoris Wg2. The two vectors, about 3.7 kilobase pairs in size, differ only in the type of antibiotic resistance they confer to their hosts. pMG36 carries a kanamycin resistance marker, which was replaced by an erythromycin resistance marker in pMG36e. As an example of the use of these vectors, the hen egg white lysozyme-coding sequence was inserted. A fusion protein of the expected size was detected in a transformed L. lactis subsp. lactis strain by using Western blotting (immunoblotting).     

Recovery of lysozyme from hen egg white by selective magnetic cake filtration

A new concept for the improvement of the downstream processing and purification is the so‐called magnetic separation. By using surface functionalized magnetic substrate particles, which selectively adsorb the target product, it can be directly separated out of a crude bioprocess stream. These methods are already used for analytical purposes, where only small amounts of functionalized particles are necessary. To apply the same concept at a larger scale, effective and economical procedures have to be provided. First, suitable process equipment has to be developed. Second, the magnetic particles have to be manufactured with a stable surface functionalization and long‐term stability for their reuse. Up to now mainly high‐gradient magnetic separation filter devices are applied for selective magnetic separation. They consist of a magnetic matrix in which the magnetic particles are trapped. In this work, a new magnetic filter is introduced that overcomes the capacity limitations of the current high‐gradient magnetic separation technology. The principle is demonstrated by selective recovery of lysozyme from hen egg white. Prior to the separation experiments magnetic beads with a strong acid cation‐exchange surface functionalization are synthesized. The separation procedure is implemented in only one unit operation. With the implementation of the displacement elution sequence lysozyme can be separated out of a hen egg white solution with a purification factor of PF=36 and a purity P=0.83.     

Anti-inflammatory effect of lysozyme from hen egg white on mouse peritoneal macrophages

Lysozyme from hen egg has been reported to possess an anti-inflammatory effect. However, little is known about its detailed mechanism. The mechanism of anti-inflammatory effect of lysozyme was examined in this study. When mouse macrophage-like cell line RAW264.7 cells and mouse peritoneal macrophages were activated with lipopolysaccharide (LPS) and then treated with lysozyme, the production of tumor necrosis factor-α and interleukin-6 was significantly suppressed. The effect was induced by suppressing the gene expression levels of both cytokines. Phagocytosis activity of peritoneal macrophages was not altered by the treatment with lysozyme, suggesting that lysozyme shows the anti-inflammatory effect without inhibiting the phagocytotic response of macrophages. In addition, lysozyme inhibited phosphorylation of c-jun N-terminal kinase (JNK) and was taken up by macrophages within 1 h after treatment of the cells with lysozyme. Overall results suggest that lysozyme is taken up intracellularly and suppresses LPS-induced inflammatory responses by inhibiting JNK phosphorylation.     

Stabilization of hen egg white lysozyme by a cavity-filling mutation

Stabilization of a protein using cavity-filling strategy has hardly been successful because of unfavorable van der Waals contacts. We succeeded in stabilizing lysozymes by cavity-filling mutations. The mutations were checked by a simple energy minimization in advance. It was shown clearly that the sum of free energy change caused by the hydrophobicity and the cavity size was correlated very well with protein stability. We also considered the aromatic-aromatic interaction. It is reconfirmed that the cavity-filling mutation in a hydrophobic core is a very useful method to stabilize a protein when the mutation candidate is selected carefully.     

Production of15N-labelled hen egg white lysozyme usingAspergillus niger

Summary Aspergillus niger has been used as a host organism for the production of¹⁵N-labelled hen egg white lysozyme (HEWL). In order to achieve maximum incorporation of label, strains expressing the HEWL gene were grown in medium containing ammonium¹⁵N chloride as sole nitrogen source. Yields of HEWL protein were reduced relative to those obtained on more complex media. Gains in yield using complex media were offset by reduction in¹⁵N incorporation. No differences in either yield or kinetics of production were observed when ammonium¹⁵N chloride was replaced by unlabelled ammonium chloride as sole nitrogen source. Yields of¹⁵N-HEWL produced in this way are adequate for, and offer considerable advantages to, NMR studies of structure and folding of mutant and wild-type lysozymes.     

Heat denaturation enhanced immunoglobulin production stimulating activity of lysozyme from hen egg white

Lysozyme from hen egg white was identified as an immunoglobulin production stimulating factor (IPSF) that enhances immunoglobulin production by hybridomas and lymphocytes. The IPSF activity of lysozyme was facilitated by heat treatment. The heat treatment of lysozyme at 83 degrees C for 30 min activated its specific IPSF effect 30.0-fold compared with that of native lysozyme. The IPSF activity of lysozyme heat-treated at 83 degrees C in 4 M urea solution was enhanced 8.4-fold than that of native lysozyme. However, lysozyme that was not heated in 4 M urea solution completely lost its IPSF activity. This means that the IPSF activity of this enzyme in 4 M urea was reactivated by thermal treatment. Moreover, coexistence of 0.5 mM 2-mercaptoethanol (2-ME) during heating in 4 M urea solution extremely enhanced the IPSF activity up to 77.8-fold. The uptake of lysozyme by hybridoma cells was enhanced by heat denaturation in 4 M urea. The hydrophobicity of lysozyme was extremely increased by heat-treatment in 2-ME containing urea solution. It is expected from these findings that the increase in the hydrophobicity caused the enhancement of incorporation of lysozyme into target cells, and resulted in the acceleration of IgM production.     

Crystalline monoclonal antibody Fabs complexed to hen egg white lysozyme

The Fab of a monoclonal anti-lysozyme antibody (HyHEL-10) has been crystallized as the free Fab and as the Fab-antigen complex. Crystals have also been grown of the antigen complex of the Fab of another monoclonal anti-lysozyme antibody (HyHEL-9), which recognizes a different binding surface of lysozyme. All three crystals diffract to at least 3 A resolution and are suitable for X-ray diffraction studies.     

Type I collagen prevents amyloid aggregation of hen egg white lysozyme

Both collagen and amyloidogenic proteins have an inherent ability to undergo a self-assembly process leading to formation of supramolecular structures. Though our understanding of collagen–amyloid link is very poor, a few experimental evidences have indicated the protective nature of collagen against amyloid fibril formation. To further our understanding of collagen–amyloid relationship, we have explored the role of type I collagen on amyloid-aggregation of lysozyme. Thioflavin-T assay data indicated strong inhibition of both spontaneous and seeded aggregation of lysozyme by collagen. Both chemical and thermal denaturation experiments have showed increased lysozyme stability in the presence of collagen. However, the presence of collagen did not alter lysozyme activity. These findings confirm that type I collagen is capable of blocking or interfering with the amyloid aggregation of lysozyme, and the results may have significant implications for the design of collagen based therapeutics against aggregation of disease linked amyloidogenic proteins.     

Pressure effect on denaturant-induced unfolding of hen egg white lysozyme.

The influence of hydrostatic pressure (< or =100 MPa) on denaturant-induced unfolding of hen egg white lysozyme was investigated by means of ultraviolet spectroscopy at various temperatures. Assuming a two-state transition model, the dependence of Gibbs free-energy change of unfolding on the denaturant concentration was calculated. Under applied hydrostatic pressure, these data were interpreted as suggesting that a two-state model is not applicable in a restricted temperature range; the dominant effect of hydrostatic pressure is to affect the cooperativity in protein unfolding due to a chemical equilibrium shift in the direction of the reduction in the system volume. The deviation from the two-state transition model appears to be rationalized by assuming that applied pressure induces an intermediate conformation between the native and unfolded states of the protein. The implication of the thermodynamic stability of protein under pressure was discussed.     

Mixed macromolecular crowding inhibits amyloid formation of hen egg white lysozyme

The effects of two single macromolecular crowding agents, Ficoll 70 and bovine serum albumin (BSA), and one mixed macromolecular crowding agent containing both BSA and Ficoll 70, on amyloid formation of hen egg white lysozyme have been examined by thioflavin T binding, Congo red binding, transmission electron microscopy, and activity assay, as a function of crowder concentration and composition. Both the mixed crowding agent and the protein crowding agent BSA at 100 g/l almost completely inhibit amyloid formation of lysozyme and stabilize lysozyme activity on the investigated time scale, but Ficoll 70 at the same concentration neither impedes amyloid formation of lysozyme effectively nor stabilizes lysozyme activity. Further kinetic and isothermal titration calorimetry analyses indicate that a mixture of 5 g/l BSA and 95 g/l Ficoll 70 inhibits amyloid formation of lysozyme and maintains lysozyme activity via mixed macromolecular crowding as well as weak, nonspecific interactions between BSA and nonnative lysozyme. Our data demonstrate that BSA and Ficoll 70 cooperatively contribute to both the inhibitory effect and the stabilization effect of the mixed crowding agent, suggesting that mixed macromolecular crowding inside the cell may play a role in posttranslational quality control mechanism.     

Secretion of Hen Egg White Lysozyme from Kluyveromyces lactis

Hen egg white (HEW) lysozyme was correctly processed and efficiently secreted from an alternative yeast, Kluyveromyces lactis. We constructed secretion vectors using PHO5, PGK, and LAC4 promoters, and found that the highest secretion was obtained under the direction of the PGK promoter in non-selective rich medium. K. lactis secreted HEW lysozyme with two-fold higher efficiency than S. cerevisiae, estimated by using a K. lactis-S. cerevisiae shuttle vector.     

1H-NMR study on the structure of lysozyme from guinea hen egg white.

The structure of lysozyme from guinea hen egg white (GEWL), which differs from hen egg white lysozyme (HEWL) by ten amino acid substitutions, was investigated by nuclear magnetic resonance (NMR) spectroscopy. GEWL and HEWL were very similar to each other in their tertiary structure as judged from the profile of 1H-NMR spectra, pH titration, and an N-acetylglucosamine trisaccharide [(GlcNAc)3 binding experiment. However, we have noticed several characteristics which distinguish GEWL from HEWL. The signal of Trp 108 indole N1H of GEWL was shifted upfield by about 0.3 ppm when compared with that of HEWL, and its hydrogen exchange was faster than that of HEWL. The pKa values of Glu 35 estimated from the pH titration curve of Trp 108 indole N1H were different between GEWL and HEWL. From a careful examination of spectral changes caused by (GlcNAc)3 binding, the changes in the chemical shift values of Trp 28 C5H and Asn 59 alpha CH of GEWL were found to be slightly larger than those of HEWL. Ile 55 of HEWL is replaced by valine in GEWL. Such a replacement may affect the neighboring hydrogen bonding between the main chain C = O of Leu 56 and Trp 108 indole N1H, resulting in a change in the microenvironment of the substrate-binding site near Trp 108.     

The effect of demulsifiers on lysozyme extraction from hen egg white using reverse micelles

The liquid–liquid extraction of protein from buffered aqueous phases using reverse micelles (RM) has been extensively researched from a fundamental point of view. However, very little effort has been expended at scaling up this process for the extraction of real fermentation broth. When real broths are used with reverse micellar phases there are major problems with emulsion formation. In this study the effect of a variety of demulsifiers on lysozyme extraction was evaluated in terms of their influence on the separating properties of the emulsion, water content (W _o ), and, extraction yield and kinetics from both buffer and hen egg white. In addition, the use of a low shear contactor (a Graesser or `raining bucket') was assessed in terms of its suitability as a RM contactor. It was found that most of the demulsifiers reduced the settling time of the emulsion, and enhanced the yield and kinetics of lysozyme extraction from hen egg white. It was hypothesised that this was due to the demulsifier displacing the lysozyme from the interface and preventing the protein unfolding and precipitating. This effect was found to depend on both the generic type of demulsifier, and its concentration.