Solvent effects on the structure,dynamics and activity of lysozyme

Kuntz and Kauzmann have argued that dehydrating a protein results in conformational changes. In contrast, Rupleyet al. have developed a hydration model which involves no significant change in conformation; the onset of enzyme activity in hen egg-white lysozyme at hydration values of about 0.2 g water/g protein they ascribe rather to a solvation effect. Using a direct difference infra-red technique we can follow specific hydration events as water is added to a dry protein. Conformational studies of lysozyme using laser Raman spectroscopy indicate changes in conformation with hydration that are complete just before measurable activity is found. Parallel nuclear magnetic resonance measurements of exchangeability of the main chain amide hydrogens, as a function of hydration from near dryness, suggest a hydration-related increase in conformational flexibility which occurs before-and is probably necessary for-the Raman-detected conformational changes. Very recent inelastic neutron scattering measurements provides direct evidence of a flexibility change induced by hydration, which is apparently necessary before the enzyme can achieve adequate flexibility for it to begin to function.     

The influence of hydration on the conformation of lysozyme studied by solid-state 13C-nmr spectroscopy

¹³C proton decoupled cross-polarization magic-angle spinning nmr spectra of lysozyme are reported as a function of hydration. Increases in hydration level enhance the resolution of the spectra, particularly in the aliphatic region, but has no significant effect on either the rotating frame proton spin–lattice relaxation time or the cross-relaxation time. The enhancement in spectral resolution with hydration is attributed to a decrease in the distribution of isotropic chemical shifts, which reflects a decrease in the distribution of conformational states sampled by the protein. Changes in the distribution of isotropic chemical shifts occur after the addition of water to the charged groups as coverage of the polar side chains and peptide groups takes place. The onset of this behavior occurs at a hydration level of about, 0.1–0.2 g water/g protein and is largely complete at about 0.3 g water/g protein, the same hydration range where changes in the heat capacity are observed. That hydrogen exchange of buried protons can occur at hydration levels significantly lower than those at which changes in the distribution of conformational states are first observed suggests that some motions that mediate exchange are already present in the dry protein. The preservation of efficient dipolar coupling indicates that the conformational rearrangements that do-occur on hydration are small and do not involve any significant overall expansion of free volume or weakening of interactions that would increase the reorientational freedom of protein groups. © 1993 John Wiley & Sons, Inc.     

Covalent labeling and mass spectrometry reveal subtle higher order structural changes for antibody therapeutics

Monoclonal antibodies are among the fastest growing therapeutics in the pharmaceutical industry. Detecting higher-order structure changes of antibodies upon storage or mishandling, however, is a challenging problem. In this study, we describe the use of diethylpyrocarbonate (DEPC)-based covalent labeling (CL) – mass spectrometry (MS) to detect conformational changes caused by heat stress, using rituximab as a model system. The structural resolution obtained from DEPC CL-MS is high enough to probe subtle conformation changes that are not detectable by common biophysical techniques. Results demonstrate that DEPC CL-MS can detect and identify sites of conformational changes at the temperatures below the antibody melting temperature (e.g., 55 ?C). The observed labeling changes at lower temperatures are validated by activity assays that indicate changes in the F_ab region. At higher temperatures (e.g., 65 ?C), conformational changes and aggregation sites are identified from changes in CL levels, and these results are confirmed by complementary biophysical and activity measurements. Given the sensitivity and simplicity of DEPC CL-MS, this method should be amenable to the structural investigations of other antibody therapeutics.     

The decisive role of the water structure in changes of conformation of nucleic acids.

This review summarizes data on the structure and properties of water under normal conditions, at high salt concentration and under high pressure. We correlate the observed conformational transitions in nucleic acids with changes in water structure and activity, and suggest a mechanism of conformational transitions of nucleic acid involving these changes. We conclude that the Z-DNA form is induced only at low water activity caused by high salt concentrations and/or high pressure.     

Probing Substates in Sperm Whale Myoglobin Using High-Pressure Crystallography

Pressures in the 100 MPa range are known to have an enormous number of effects on the action of proteins, but straightforward means for determining the structural basis of these effects have been lacking. Here, crystallography has been used to probe effects of pressure on sperm whale myoglobin structure. A comparison of pressure effects with those seen at low pH suggests that structural changes under pressure are interpretable as a shift in the populations of conformational substates. Furthermore, a novel high-pressure protein crystal-cooling method has been used to show low-temperature metastability, providing an alternative to room temperature, beryllium pressure cell-based techniques. The change in protein structure due to pressure is not purely compressive and involves conformational changes important to protein activity. Correlation with low-pH structures suggests observed structural changes are associated with global conformational substates. Methods developed here open up a direct avenue for exploration of the effects of pressure on proteins.     

How environment supports a state: molecular dynamics simulations of two states in bacteriorhodopsin suggest lipid and water compensation

The light-driven proton pump bacteriorhodopsin (bR) is a transmembrane protein that uses large conformational changes for proton transfer from the cytoplasmic to the extracellular regions. Crystal structures, due to their solvent conditions, do not resolve the effect of lipid molecules on these protein conformational changes. To begin to understand the molecular details behind such large conformational changes, we simulated two conformations of wild-type bacteriorhodopsin, one of the dark-adapted state and the second of an intermediate (M(O)) state, each within an explicit dimyristoyl-phosphatidylcholine (DMPC) lipid bilayer. The simulations included all-hydrogen and all-atom representations of protein, lipid, and water and were performed for 20 ns. We investigate the equilibrium properties and the dynamic motions of the two conformations in the lipid setting. We note that the conformational state of the M(O) intermediate bR remains markedly different from the dark-adapted bR state in that the M(O) intermediate shows rearrangement of the cytoplasmic portions of helices C, F, and G, and nearby loops. This difference in the states remained throughout the simulations, and the results are stable on the molecular dynamics timescale and provide an illustration of the changes in both lipid and water that help to stabilize a particular state. Our analysis focuses on how the environment adjusts to these two states and on how the dynamics of the helices, loops, and water molecules can be related to the pump mechanism of bacteriorhodopsin. For example, water generally behaves in the same manner on the extracellular sides of both simulations but is decreased in the cytoplasmic region of the M(O) intermediate. We suspect that the different water behavior is closely related to the fluctuations of microcavities volume in the protein interior, which is strongly coupled to the collective motion of the protein. Our simulation result suggests that experimental observation can be useful to verify a decreased number of waters in the cytoplasmic regions of the late-intermediate stages by measuring the rate of water exchange with the interior of the protein.     

Actin-related proteins (Arps): conformational switches for chromatin-remodeling machines?

The actin superfamily of ATPases includes cytoskeletal actins, the stress 70 proteins (e.g. hsc70), sugar kinases, glycerol kinase, and several prokaryotic cell cycle proteins. Although these proteins share limited sequence identity, they all appear to maintain a similar tertiary structure, the "actin fold", which may serve to couple ATP hydrolysis to protein conformational changes. Recently, an actin-related protein (Arp) subfamily has been identified based on sequence homology to conventional actin. Although some Arps are clearly involved in cytoskeletal functions, both actin and/or Arps have been found as stoichiometric subunits of several nuclear chromatin-remodeling enzymes. Here we present two related models in which actin and/or Arps function as conformational switches that control either the activity or the assembly of chromatin-remodeling machines.     

Novel role for pectin methylesterase in Arabidopsis: a new function showing ribosome-inactivating protein (RIP) activity

Ribosome-inactivating proteins (RIPs, EC 3.2.2.22) are plant enzymes that can inhibit the translation process by removing single adenine residues of the large rRNA. These enzymes are known to function in defense against pathogens, but their biological role is unknown, partly due to the absence of work on RIPs in a model plant. In this study, we purified a protein showing RIP activity from Arabidopsis thaliana by employing chromatography separations coupled with an enzymatic activity. Based on N-terminal and internal amino acid sequencing, the RIP purified was identified as a mature form of pectin methylesterase (PME, At1g11580). The purified native protein showed both PME and RIP activity. PME catalyzes pectin deesterification, releasing acid pectin and methanol, which cause cell wall changes. We expressed the full-length and mature form of cDNA clones into an expression vector and transformed it in Escherichia coli for protein expression. The recombinant PME proteins (full-length and mature) expressed in E. coli did not show either PME or RIP activity, suggesting that post-translational modifications are important for these enzymatic activities. This study demonstrates a new function for an old enzyme identified in a model plant and discusses the possible role of a protein's conformational changes corresponding to its dual enzymatic activity.     

High pressure-induced changes of biological membrane. Study on the membrane-bound Na(+)/K(+)-ATPase as a model system.

In order to study the pressure-induced changes of biological membrane, hydrostatic pressures of from 0.1 to 400 MPa were applied to membrane-bound Na(+)/K(+)-ATPase from pig kidney as a model system of protein and lipid membrane. The activity showed at least a three-step change induced by pressures of 0.1-100 MPa, 100-220 MPa, and 220 MPa or higher. At pressures of 100 MPa or lower a decrease in the fluidity of lipid bilayer and a reversible conformational change in transmembrane protein is induced, leading to the functional disorder of membrane-associated ATPase activity. A pressure of 100-220 MPa causes a reversible phase transition in parts of the lipid bilayer from the liquid crystalline to the gel phase and the dissociation of and/or conformational changes in the protein subunits. These changes could cause a separation of the interface between alpha and beta subunits and between protein and the lipid bilayer to create transmembrane tunnels at the interface. Tunnels would be filled with water from the aqueous environment and take up tritiated water. A pressure of 220 MPa or higher irreversibly destroys and fragments the gross membrane structure, due to protein unfolding and interface separation, which is amplified by the increased pressure. These findings provide an explanation for the high pressure-induced membrane-damage to subcellular organelles.     

Using UHF-dielectrometry to study protein structural transitions

UHF-dielectrometry method is based on the following facts: i) there is dispersion (i.e. dependence on frequency) of the dielectric permeability epsilon; ii) bound and free water have remarkable different epsilon, mobility and dispersion regions; iii) conformational changes in a macromolecule lead to redistribution of free and bound water and to change of the amount of free water molecules. Choosing the working frequency in the region of dispersion of free water molecules (9.2 GHz) we can detect conformational changes in proteins using free water as a marker. In this work the temperature dependencies of dielectric parameters of albumin and fibrinogen solutions were obtained in the temperature interval 5-40 degrees C. In contrast to dependencies for poor solvent, temperature dependencies of dielectric parameters for protein solutions are of non-monotonous character; they have a number of peculiarities in the temperature ranges of 8-10, 22-24 and 34-36 degrees C. At these temperatures redistribution of free and bound water in protein-water system occurs due to structural changes in protein molecules. In this work the mechanism of temperature changes of spatial organisation of protein molecules was proposed. Perhaps, this mechanism is responsible for maintenance of thermal stability of the functionally active conformation of native proteins.     

Structure of cubic insulin crystals in glucose solutions.

X-ray structures of cubic insulin crystals in high concentrations of glucose at different pH levels and temperatures have been refined to high resolution. We have identified one glucose-binding site near the N-terminus of the A-chain whose occupancy is pH dependent. The effects of reduced water activity on the ordered protein and solvent structures have been examined. Our analysis showed no notable conformational changes in the ordered protein structures or ordered solvent molecules near the protein surface, but the presence of glucose does have a significant effect on the overall density distribution of the bulk solvent in the solvent-accessible volume. We compared the structure of cubic insulin at room temperature and liquid-nitrogen temperature, under identical solvent conditions, using glucose as a cryoprotectant. In this case, we found that the average temperature factor of the protein is reduced and more water molecules can be identified, but there are no significant changes in the protein conformation.     

Analysis of aluminum-yeast hexokinase interaction: modifications on protein structure and functionality

The aluminum and yeast hexokinase interaction was studied. Structural changes were correlated with variations in protein functionality. Results show two different behaviors: At low metal concentrations preferential adsorption of metal (and water exclusion) induces aggregate formation. No significant changes in the protein structure occur, but there is a continuous loss of activity (from the first concentration). At large salt concentrations a monomerization process and a conformational change in the secondary structure as well as in the three-dimensional structure take place. This change reduces the percentage of -helix conformation, gives thermal stability to the protein, and allows the exposure of some tryptophan residue and hydrophobic regions. The protein inhibition increases. Conformational change and monomerization may allow access of the metal to the substrate site, mainly the ATP site. The inhibition in any case is of mixed type with a competitive component.     

Induced fit in RNA-protein recognition

Two generalizations can be drawn from the recent rapid progress in understanding RNA-protein interactions. First, there is a great diversity of observed protein and RNA structural motifs. Second, formation of almost every RNA-protein complex that has been characterized involves conformational changes in the protein, the RNA, or both. The role of these conformational changes in the biological function of RNA-protein complexes is not at all clear. Whether or not conformational changes are a critical feature of ribonucleoprotein complex assembly or are an unimportant mechanistic detail, the ubiquity of these changes warrants careful consideration of their implications.     

Effects of lipid environment on the conformational changes of an ABC importer

In order to shuttle substrates across the lipid bilayer, membrane proteins undergo a series of conformation changes that are influenced by protein structure, ligands, and the lipid environment. To test the effect of lipid on conformation change of the ABC transporter MolBC, EPR studies were conducted in lipids and detergents of variable composition. In both a detergent and lipid environment, MolBC underwent the same general conformation changes as detected by site-directed EPR spectroscopy. However, differences in activity and the details of the EPR analysis indicate conformational rigidity that is dependent on the lipid environment. From these observations, we conclude that native-like lipid mixtures provide the transporter with greater activity and conformational flexibility as well as technical advantages such as reconstitution efficiency and protein stability.     

Circular dichroism studies on the alpha-D-galactopyranosyl binding lectin isolated from the seeds of Bandeiraea simplicifolia.

The conformation of the alpha-D-galactopyranosyl binding lectin isolated from Bandeiraea simplicifolia seeds has been investigated over a broad range of pH in the presence of various solvents by circular dichroism (CD) spectroscopy in the region 200-300 nm. Analyses of the spectra obtained on the native protein show the lectin to contain a considerable proportion of beta structure (30-40%). The native conformation was found to be largely insensitive to changes in pH, but was influenced by sodium dodecyl sulfate or trifluoroethanol. Alterations in conformation in the presence of these agents were reflected in the CD spectra and show the presence of alpha helix under these conditions. These changes in conformation are accompanied by a loss in polysaccharide-precipitating activity. The protein is irreversibly denatured in 8 M urea. Neither removal of the intrinsic calcium ions from the protein nor addition of methyl alpha-D-galactopyranoside induces any appreciable change in the CD spectra of the protein although the former treatment abolishes the polysaccharide-precipitating capacity of the lectin. The conformational data obtained in the present study are compared with data available from conformational studies of other lectins and leads to the hypothesis that most lectins probably contain beta structure as the predominant conformational feature.     

Effects of lipid environment on the conformational changes of an ABC importer

In order to shuttle substrates across the lipid bilayer, membrane proteins undergo a series of conformation changes that are influenced by protein structure, ligands, and the lipid environment. To test the effect of lipid on conformation change of the ABC transporter MolBC, EPR studies were conducted in lipids and detergents of variable composition. In both a detergent and lipid environment, MolBC underwent the same general conformation changes as detected by site-directed EPR spectroscopy. However, differences in activity and the details of the EPR analysis indicate conformational rigidity that is dependent on the lipid environment. From these observations, we conclude that native-like lipid mixtures provide the transporter with greater activity and conformational flexibility as well as technical advantages such as reconstitution efficiency and protein stability.     

Construction of a recombinase-deficient mutant recA protein that retains single-stranded DNA-dependent ATPase activity

The recA1 mutation is a single point mutation that replaces glycine 160 of the recA polypeptide with an aspartic acid residue. The mutant recA1 protein has a greatly reduced single-stranded DNA-dependent ATPase activity at pH 7.5 compared to the wild-type protein. Interestingly, the recA1 protein does exhibit a vigorous ATPase activity at pH 6.2. To explore the molecular basis of this pH effect, we used site-directed mutagenesis to replace aspartic acid 160 of the recA1 polypeptide with an isosteric, but nonionizing, asparagine residue. The new [Asn160]recA protein catalyzes ATP hydrolysis at pH 7.5 with the same turnover number as the wild-type protein. This result suggests that the activation of the recA1 protein ATPase activity that occurs at pH 6.2 may be due, in part, to neutralization of the negatively charged aspartic acid 160 side chain. Although it is an active single-stranded DNA-dependent ATPase, the [Asn160]recA protein is unable to complement a recA deletion in vivo and is unable to carry out the three-strand exchange reaction in vitro. Further examination of ATP hydrolysis (under strand exchange conditions) revealed that the ATPase activity of the [Asn160]recA protein is strongly suppressed in the presence of Escherichia coli single-stranded DNA-binding protein (a component of the strand exchange assay), whereas the ATPase activity of the wild-type recA protein is stimulated by the E. coli protein. To account for these results, we speculate that ATP may induce specific conformational changes in the wild-type recA protein that are essential to the DNA pairing process and that these conformational changes may not occur with the [Asn160]recA protein.     

Effect of Chemical Chaperones on Glucose-Induced Lysozyme Modifications

Nonenzymatic glycation of biomacromolecules occurs due to the diabetes mellitus and ageing. A number of small molecules, known as chemical chaperones, stabilize protein conformation against thermal and chemically induced denaturation. These compounds are including: polyamines (e.g. spermine and spermidine), amino acids (e.g. lysine) and polyols (e.g. glycerol). In this study the effect of spermidine (Spd), spermine (Spm), and glycerol on glycation, structure and function of lysozyme (LZ), as an extra-cellular protein, by different techniques is investigated. LZ is incubated with or without glucose (50 or 100 mM) in the absence or presence of Spd/Spm/glycerol at 37 °C up to 16 weeks. All the observed changes of glycated-LZ in comparison with the native protein, including: increased fluorescence emission, alteration in the secondary and tertiary structure, and reduced electrophoretic mobility- indicate its structural changes that are accompanied with its reduced activity. Glucose in the presence or absence of Spd induces the protein dimerization, but glucose plus Spm induces its trimmerization. In contrast, glycerol inhibits the LZ glycation and prevents the large changes on its structure and function. Glucose binds lysine residues, decreases the protein positive charges and induces some alterations in its structure and activity. Polyamines also directly bind to LZ, increase its positive charges and hence induce more glycation; more conformational changes, oligomerization and its inactivation in the presence of glucose, but glycerol affect the protein environment and preserve protein from these harmful effects.     

Probing Structural Changes during Self-assembly of Surface-Active Hydrophobin Proteins that Form Functional Amyloids in Fungi

Hydrophobins are amphiphilic proteins secreted by filamentous fungi in a soluble form, which can self-assemble at hydrophilic/hydrophobic or water/air interfaces to form amphiphilic layers that have multiple biological roles. We have investigated the conformational changes that occur upon self-assembly of six hydrophobins that form functional amyloid fibrils with a rodlet morphology. These hydrophobins are present in the cell wall of spores from different fungal species. From available structures and NMR chemical shifts, we established the secondary structures of the monomeric forms of these proteins and monitored their conformational changes upon amyloid rodlet formation or thermal transitions using synchrotron radiation circular dichroism and Fourier-transform infrared spectroscopy (FT-IR). Thermal transitions were followed by synchrotron radiation circular dichroism in quartz cells that allowed for microbubbles and hence water/air interfaces to form and showed irreversible conformations that differed from the rodlet state for most of the proteins. In contrast, thermal transitions on hermetic calcium fluoride cells showed reversible conformational changes. Heating hydrophobin solutions with a water/air interface on a silicon crystal surface in FT-IR experiments resulted in a gain in β-sheet content typical of amyloid fibrils for all except one protein. Rodlet formation was further confirmed by electron microscopy. FT-IR spectra of pre-formed hydrophobin rodlet preparations also showed a gain in β-sheet characteristic of the amyloid cross-β structure. Our results indicate that hydrophobins are capable of significant conformational plasticity and the nature of the assemblies formed by these surface-active proteins is highly dependent on the interface at which self-assembly takes place.