FTDP-17 tau mutations decrease the susceptibility of tau to calpain I digestion

Frontal temporal dementia and Parkinsonism linked to chromosome 17 (FTDP-17) is caused by splice site and missense mutations in the tau gene, and characterized by the accumulation of filamentous tau in cerebral neurons and glia. The missense mutations reduce the ability of tau to promote microtubule assembly and increase the ability of tau to form filaments. In this report we demonstrate that mutants V337M and R406W are less susceptible than mutant P301L or corresponding wild type tau to degradation by calpain I. The differences were at least in part due to changes in accessibility of a cleavage site located about 100 amino acids off the carboxy-terminus. The results suggest that the pathogenesis of some forms of FTDP-17 may involve tau accumulation due to decreased proteolytic degradation.     

Mitogen activated protein (MAP) kinase transforms tau protein into an Alzheimer-like state.

The microtubule-associated protein tau is a major component of the paired helical filaments (PHFs) observed in Alzheimer's disease brains. The pathological tau is distinguished from normal tau by its state of phosphorylation, higher apparent M(r) and reaction with certain antibodies. However, the protein kinase(s) have not been characterized so far. Here we describe a protein kinase from brain which specifically induces the Alzheimer-like state in tau protein. The 42 kDa protein belongs to the family of mitogen activated protein kinases (MAPKs) and is activated by tyrosine phosphorylation. It is capable of phosphorylating Ser-Pro and Thr-Pro motifs in tau protein (approximately 14-16 P1 per tau molecule). By contrast, other proline directed Ser/Thr kinases such as p34(cdc2) combined with cyclin A or B have only minor effects on tau phosphorylation. We propose that MAP kinase is abnormally active in Alzheimer brain tissue, or that the corresponding phosphatases are abnormally passive, due to a breakdown of the normal regulatory mechanisms.     

Voltage dependence of proton pumping by bacteriorhodopsin is regulated by the voltage-sensitive ratio of M1 to M2.

The voltage dependence of light-induced proton pumping was studied with bacteriorhodopsin (bR) from Halobacterium salinarum, expressed in the plasma membrane of oocytes from Xenopus laevis in the range -160 mV to +60 mV at different light intensities. Depending on the applied field, the quenching effect by blue light, which bypasses the normal photo and transport cycle, is drastically increased at inhibiting (negative) potentials, and is diminished at pump current increasing (positive) potentials. At any potential, two processes with different time constants for the M --> bR decay of approximately 5 ms (tau1) and approximately 20 ms (tau2) are obtained. At pump-inhibiting potentials, a third, long-lasting process with tau3 approximately 300 ms at neutral pH is observed. The fast processes (tau1, tau2) can be assigned to the decay of M2 in the normal pump cycle, i.e., to the reprotonation of the Schiff base via the cytoplasmic side, whereas tau3 is due to the decay of M1 without net pumping, i.e., the reprotonation of the Schiff base via the extracellular side. The results are supported by determination of photocurrents induced by bR on planar lipid films. The pH dependence of the slow decay of M1 is fully in agreement with the interpretation that the reprotonation of the Schiff base occurs from the extracellular side. The results give strong evidence that an externally applied electrical field changes the ratio of the M1 and the M2 intermediate. As a consequence, the transport cycle branches into a nontransporting cycle at negative potentials. This interpretation explains the current-voltage behavior of bR on a new basis, but agrees with the isomerisation, switch, transfer model for vectorial transport.     

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.     

Molecularly imprinted polymer-assisted refolding of lysozyme

For production of active proteins using heterologous expression systems, refolding of proteins from inclusion bodies often creates a bottleneck due to its poor yield. In this study, we show that molecularly imprinted polymer (MIP) toward native lysozyme promotes the folding of chemically denatured lysozyme. The MIP, which was prepared with 1 M acrylamide, 1 M methacrylic acid, 1 M 2-(dimethylamino)ethyl methacrylate, and 5 mg/mL lysozyme, successfully promoted the refolding of lysozyme, whereas the non-imprinted polymer did not. The refolding yield of 90% was achieved when 15 mg of the MIP was added to 0.3 mg of the unfolded lysozyme. The parallel relationship between the refolding yield and the binding capacity of the MIP suggests that MIP promotes refolding through shifting the folding equilibrium toward the native form by binding the refolded protein.     

Specific carbodiimide-binding mechanism for the selective modification of the aspartic acid-101 residue of lysozyme in the carbodiimide-amine reaction

A mechanism for the selective modification of Asp-101 in hen egg-white lysozyme with an amine nucleophile catalyzed by 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide hydrochloride (EDC) was investigated using ethanolamine as a nucleophile at pH 5.0 and room temperature. In the presence of N-acetyl-D-glucosamine (NAG) and its oligomers [(NAG)n, n = 2 and 3] under the conditions with which about 90% of lysozyme was calculated to form complexes, the formation of Asp-101 modified lysozyme decreased markedly but to different degrees, that is (NAG)3 was the most and NAG the least effective. When the lysozyme derivative, in which Trp-62 in the active site cleft was oxidized to oxindolealanine (Ox-62 lysozyme), was used in place of native lysozyme, the formation of Asp-101 modified derivative decreased to about half, which was similar to the decrease in the presence of (NAG)2. In the presence of 0.5 M NaCl, on the other hand, the formation of Asp-101 modified lysozyme was considerably enhanced. From these observations, it is concluded that EDC binds to the active site cleft of lysozyme to specifically activate Asp-101. The affinity of EDC to the active site of lysozyme is partly due to the hydrophobic interaction of EDC with the Trp-62 residue at sub-site B of lysozyme. EDC is an activating reagent for carboxyl groups unlike most active site-directed reagents which produce final products directly. Therefore, the active site-directed nature of EDC was very useful because it made it possible to selectively introduce various amines as needed at a particular carboxyl group of lysozyme.     

Conformational changes and bioactivity of lysozyme on binding to and desorption from magnetite nanoparticles

A fundamental understanding of the conformational behaviors of lysozyme during the process of adsorption and desorption has been studied using spectrophotometric techniques, and interpreted in terms of the secondary structures in this work. FTIR data show an increase in α-helix and β-sheet content when lysozyme interaction with magnetite nanoparticles (Fe(3)O(4) (PEG+CM-CTS) NPs) which indicates that the lysozyme would adopt a more compact conformation state. The mechanism of fluorescence quenching of lysozyme by magnetite nanoparticles is due to the formation of lysozyme-nanoparticles complex. High desorption of lysozyme from Fe(3)O(4) (PEG+CM-CTS) NPs were achieved using phosphate buffer solution (PBS) (20 mM, pH 5.0, 0.2 M NaCl), PBS (20 mM, pH 5.0, 0.5 M NaCl) and acetic acid (0.2 M, pH 4.0) as eluents. The alterations of lysozyme secondary structure on desorption from nanoparticles were confirmed by circular dichroism and fluorescence spectroscopy. Lysozymes desorbed by PBS (20mM, pH 5.0, 0.2M NaCl) and PBS (20mM, pH 5.0, 0.5M NaCl) retain high fraction of its native structure with negligible effect on its activity, and about 92.4% and 89.5% activity were retained upon desorption from nanoparticles, however, lysozyme desorbed by acetic acid (0.2 M, pH 4.0) solution showed significant conformational changes. The stability of NPs-conjugated protein and retention of higher activity may find useful applications in biotechnology ranging from enzyme immobilization to protein purification.     

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.     

Effect of temperature and binding with copper ions on the motility of spin-labeled oxy- and methemoglobin subunits

Using the method for separate determination of correlation times of spin-labeled proteins (tau M) and labels (tau R) it has been shown that at temperatures below and about 25 degrees the mobility of oxy Hb subunits is higher than that of met Hb. From 30 degrees on oxy and met Hb show identical flexibility (tau M = 40 ns) in 0.01 M phosphate buffer (pH 7.3) containing 0.15 M NaCl. With a decline in pH from 7.3 to 6.4 the intramolecular mobility of met Hb subunits decreases. In the absence of 0.15 M NaCl at pH 7.3 (5 degrees C) met Hb becomes more flexible (tau M drops from 25 to 16 ns). Complex formation of beta-chains of oxy Hb with one Cu+2 ion at 20 degrees has a negligible bearing on the flexibility of the protein, whereas addition of second ion considerably enhances interaction between the subunits of the tetramer and decreases its flexibility (tau M rises from 17 to 30 ns).     

Study of lysozyme by a spin-label method in the 2-mm range

Two millimeter range ESR-spectroscopy was used to measure the values of magnetic resonance parameters of egg lysozyme samples modified with nitroxyl label 4-(iodine-acetamide)-2,2,6,6-tetramethylpiperidine-1-oxyl by hist-15 residue. It has been shown that in a lyophilic sample the spin label forms a hydrogen bond with the protein group and when the sample is moistened--with water molecules. Temperature changes of the pattern of ESR line are analysed. It is concluded that in the moistened samples within 230-320 K the nitroxyl fragment of the label gets engaged in anisotropic movement with preferable rotation around Z-axis of N-O. fragment with anisotropy coefficient 5 and mean correlation time tau congruent to 5 X 10(-7) divided by 5 X 10(-8) c.     

Alz 50, a monoclonal antibody to Alzheimer's disease antigen, cross-reacts with tau proteins from bovine and normal human brain

Microtubule-associated protein tau from bovine brain reacted on immunoblots and on enzyme-linked immunosorbent assay with a monoclonal antibody, Alz 50, which has previously been found to bind to an Alzheimer disease-specific antigen. The apparent affinity of binding of Alz 50 to tau was 2.1 X 10(-9) M on competitive enzyme-linked immunosorbent assay, and it was in the same range as for Tau-1 (0.5 X 10(-9) M), an antibody raised against purified bovine tau proteins. Immunoblotting of trypsin-digested tau revealed differences between Alz 50 and Tau-1 binding sites. The binding of both antibodies to tau was not affected by prior treatment with phosphatase, indicating that the cross-reactivity of Alz 50 with tau is due to the presence of phosphate-independent epitope. This epitope then differs from phosphate-dependent tau epitopes often shared with other cytoskeletal proteins. Alz 50 and Tau-1 binding sites were present in all isoelectric (pI 6-8) and molecular weight variants of tau. In contrast, phosphate-dependent epitopes recognized by another tau-reactive antibody (NP14) were found mostly in acidic tau variants. Similarly to tau proteins from bovine brain, tau-enriched preparations from normal human brain contained Alz 50 and Tau-1 reactive sites in all isoelectric (pI 6.5-8.5) and molecular weight variants. Our observation of Alz 50 cross-reactivity with tau suggests a relationship between tau and the novel protein identified recently in Alzheimer brains.     

Binding of microtubule-associated protein 2 and tau to the intermediate filament reassembled from neurofilament 70-kDa subunit protein. Its regulation by calmodulin

Two major brain microtubule-associated proteins (MAPs), MAP2 and tau, were found to bind to the intermediate filaments reassembled from neurofilament 70-kDa subunit protein (= 70-kDa filaments). The binding was saturable. The apparent dissociation constant (KD) for the binding of MAP2 to the 70-kDa filaments was estimated to be 4.8 X 10(-7) M, and the maximum binding reached 1 mol of MAP2/approximately 30 mol of 70-kDa protein. The apparent KD for the tau binding was 1.6 X 10(-6) M, and the maximum binding was 1 mol of tau/approximately 3 mol of 70-kDa protein. It was also found that MAP2 and tau did not compete with each other for binding to the 70-kDa filaments. Most interestingly, calmodulin, a ubiquitous Ca2+-binding protein in eukaryotic cells, was found to inhibit the binding of MAP2 and tau to the 70-kDa filaments. The inhibition by calmodulin was regulated by changes in Ca2+ concentration around 10(-6) M, and was canceled by trifluoperazine, a calmodulin inhibitor.     

Calcium-binding lysozymes

It was found that pigeon lysozyme binds one calcium ion, as does equine lysozyme. The protein was eluted with equimolar calcium ions from a Bio-Gel P-60 column. The binding constants of equine and pigeon lysozymes were determined to be 2 x 10(6) and 1.6 x 10(7) M-1, respectively, in 0.1 M KCl at pH 7.1 and 20 degrees C. During evolution the gene of calcium-binding lysozyme is deduced to be separated from that of non-calcium-binding lysozyme by gene duplication before splitting of avian and mammalian lineages, from their amino-acid sequences. It is assumed that the alpha-lactalbumin might have evolved from calcium-binding lysozyme.     

Modeling the dual pacemaker system of the tau mutant hamster

Circadian pacemakers in many animals are compound. In rodents, a two-oscillator model of the pacemaker composed of an evening (E) and a morning (M) oscillator has been proposed based on the phenomenon of "splitting" and bimodal activity peaks. The authors describe computer simulations of the pacemaker in tau mutant hamsters viewed as a system of mutually coupled E and M oscillators. These mutant animals exhibit normal type 1 PRCs when released into DD but make a transition to a type 0 PRC when held for many weeks in DD. The two-oscillator model describes particularly well some recent behavioral experiments on these hamsters. The authors sought to determine the relationships between oscillator amplitude, period, PRC, and activity duration through computer simulations. Two complementary approaches proved useful for analyzing weakly coupled oscillator systems. The authors adopted a "distinct oscillators" view when considering the component E and M oscillators and a "system" view when considering the system as a whole. For strongly coupled systems, only the system view is appropriate. The simulations lead the authors to two primary conjectures: (1) the total amplitude of the pacemaker system in tau mutant hamsters is less than in the wild-type animals, and (2) the coupling between the unit E and M oscillators is weakened during continuous exposure of hamsters to DD. As coupling strength decreases, activity duration (alpha) increases due to a greater phase difference between E and M. At the same time, the total amplitude of the system decreases, causing an increase in observable PRC amplitudes. Reduced coupling also increases the relative autonomy of the unit oscillators. The relatively autonomous phase shifts of E and M oscillators can account for both immediate compression and expansion of activity bands in tau mutant and wild-type hamsters subjected to light pulses.     

Vectorial and nonvectorial transphosphorylation catalyzed by enzymes II of the bacterial phosphotransferase system

The plasmolytic response of Bacillus licheniformis 749/C cells to the increasing osmolarity of the surrounding medium was quantitated with stereological techniques. Plasmolysis was defined as the area (in square micrometers) of the inside surface of the bacterial wall not in association with bacterial membrane per unit volume (in cubic micrometers) of bacteria. This plasmolyzed surface area was zero when the cells were suspended in a concentration of sucrose solution lower than 0.5 M, but increased linearly when the sucrose molarity rose above 0.5 M, reaching a plateau value of 3.61 micrometers2/micrometers3 in 2 M sucrose. In contrast, when the bacterial cells were treated with lysozyme plasmolysis increased abruptly from 0.06 micrometers2/micrometers3 in 0.75 M sucrose to 4.09 micrometers2/micrometers3 in 1 M sucrose. When the time of exposure was prolonged, the degree of plasmolysis increased gradually for the duration of the experiment (30 min) after exposure to 1 M sucrose without lysozyme, whereas with lysozyme plasmolysis reached a maximum (4.09 micrograms2/micrometers3) in 2 to 5 min. The examination of ultrastructure showed that the protoplast bodies of lysozyme-treated cells in 1 M sucrose and untreated cells in 2 M sucrose are maximally retracted from the intact wall of the bacteria; hardly any retraction of protoplasts could be seen for untreated cells in 1 M sucrose. The data suggest that the B. licheniformis cells are isoosmotic to 800 to 1,100 mosM solutions, but are able to withstand much greater osmotic pressure with no signs of plasmolysis because the cell wall and the plasma membrane are held in close association, perhaps by a covalent bond. It is likely that lysozyme weakens this bond by degradation of the peptidoglycan layer. Cellular autolysis also weakens this wall-membrane association.     

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.     

Label-free and sensitive electrogenerated chemiluminescence aptasensor for the determination of lysozyme

A novel label-free electrogenerated chemiluminescence (ECL) aptasensor for the determination of lysozyme is designed employing lysozyme binding aptamer (LBA) as molecular recognition element for lysozyme as a model analyte and Ru(bpy)(3)(2+) as an ECL signal compound. This ECL aptasensor was fabricated by self-assembling the thiolated LBA onto the surface of a gold electrode. Using this aptasensor, sensitive quantitative detection of lysozyme is realized on basis of the competition of lysozyme with Ru(bpy)(3)(2+) cation for the binding sites of LBA. In the presence of lysozyme, the aptamer sequence prefers to form the LBA-lysozyme complex, the less negative environment allows Ru(bpy)(3)(2+) cations to be less bound electrostatically to the LBAs on the electrode surface, in conjunction with the generation of a decreased ECL signal. The integrated ECL intensity versus the concentration of lysozyme was linear in the range from 6.4×10(-10) M to 6.4×10(-7) M. The detection limit was 1.2×10(-10) M. This work demonstrates that using the competition of target protein with an ECL signal compound Ru(bpy)(3)(2+) for binding sites of special aptamer confined on the electrode is promising approach for the design of label-free ECL aptasensors for the determination of proteins.     

Chemical mutations of the catalytic carboxyl groups in lysozyme to the corresponding amides

In a two-step process, esterification and ammonolysis, Glu-35 and Asp-52 in lysozyme were amidated to glutamine and asparagine residues. Since the side chains of glutamine and asparagine are almost equal in size to those of glutamic acid and aspartic acid, these conversions would provide appropriate derivatives to elucidate the catalytic participations of these residues. The enzymatic activities of the resulting [Gln35]lysozyme and [Asn52]lysozyme were found to be less than 4% of that of native lysozyme in a pH range of 3.4-8.0. As these derivatives were inactive, we could determine the dissociation constants (Ks values) for the binding of beta-1,4-linked n-mer, a hexasaccharide of N-acetyl-D-glucosamine, to [Gln35]lysozyme and [Asn52] lysozyme. The values of Ks at pH 5.5 and 40 degrees C were 1.6 X 10(-5) M for [Gln35]lysozyme and 2.7 X 10(-5) M for [Asn52]lysozyme. These values are similar to that for native lysozyme. The results are direct proof for the involvements of Glu35 and Asp52 in the catalytic action of lysozyme. A method for ammonolysis of ester groups in proteins in liquid ammonia is described and will be useful for amidation of carboxyl groups of proteins.     

Accelerated secretion of human lysozyme with a disulfide bond mutation.

The mutant human lysozyme, [Ala77, Ala95]lysozyme, in which the disulfide bond Cys77-Cys95 is eliminated, is known to exhibit increased secretion in yeast, compared to wild-type human lysozyme [Taniyama, Y., Yamamoto, Y., Nakao, M., Kikuchi, M. & Ikehara, M. (1988) Biochem. Biophys. Res. Commun. 152, 962-967]. To investigate this phenomenon, mammalian cells were used to analyze the secretion kinetics of [Ala77, Ala95]lysozyme and wild-type human lysozyme. The secretion rate of [Ala77, Ala95]lysozyme during the 150-min chase period was significantly accelerated [half-life (t1/2) = 29 min] compared to that of wild-type human lysozyme (t1/2 = 83 min), when expressed at the same levels within the cells. In contrast, after the 150-min chase, the rates of disappearance of both wild-type and mutant human lysozymes within the cells were similar, and considerably slower (t1/2 = 220 min), respectively. The remaining intracellular wild-type human lysozyme was localized mainly in the endoplasmic reticulum, whereas accelerated transport of the [Ala77, Ala95]lysozyme mutant protein from the endoplasmic reticulum to the Golgi apparatus was observed. Also in yeast cells, similar secretion kinetics and the differences in t1/2 for wild-type and mutant human lysozymes during the early chase period were observed. The two-phase kinetics of disappearance of intracellular human lysozymes suggest that only a proportion of the proteins becomes secretion competent soon after synthesis and is completely secreted during the early chase period, whereas others enter the distinct, slow pathways of intracellular transport and/or degradation. Increased secretion of [Ala77, Ala95]lysozyme is possibly due to enhanced competence for secretion acquired in the endoplasmic reticulum at the early stage of transport events, which is closely connected with the removal of a disulfide bond.     

Kinetic behavior of slowly equilibrating association-dissociation enzyme systems]

The shape of the plots of product accumulation versus time (t) has been analysed for slowly equilibrating association-dissociation enzyme systems of the types 2p in equilibrium P (P is enzyme oligomer which is able to dissociate reversibly forming two identical halves p) and M in equilibrium M2 in equilibrium M2 in equilibrium... (M is monomer which has two association sites overlapping with active sites). It is assumed that the rate of equilibration between oligomeric forms is comparable with the rate of over-all enzymatic reaction and that substrate-oligomer complexes are in rapid equilibrium with free components. It has been shown that characteristic feature of kinetic behavior of slowly equilibrating association-dissociation enzyme systems is that the value of tau depends on enzyme concentration (tau is the intercept on t-axis for linear asymptota of the curve of product concentration versus time at t leads to infinity).