Mode of interaction between lysozyme and the other proteins of the hen's egg vitelline membrane

Salt solutions and charged detergents are efficient solubilizing agents for ovovitelline membrane lysozyme. Reassociation experiments with chemically modified lysozymes indicate that positively charged amino acid residues of lysozyme (the epsilon-amino group of lysine and the guanidino group of arginine) are involved in the interaction with other proteins of the vitelline membrane. Exogenous proteins are adsorbed to lysozyme-free vitelline membranes, only if they have a high pI, comparable to that of lysozyme. It is concluded that the lysozyme-ovovitelline membrane interaction is predominantly ionic. An ovomucin-lysozyme complex is postulated as the major component of the outer layer of the membrane.     

Molecular dynamics simulations of a stretch-activated channel inhibitor GsMTx4 with lipid membranes: two binding modes and effects of lipid structure

Our recent molecular dynamics simulation study of hanatoxin 1 (HaTx1), a gating modifier that binds to the voltage sensor of K(+) channels, has shown that HaTx1 has the ability to interact with carbonyl oxygen atoms of both leaflets of the lipid bilayer membrane and to be located at a deep position within the membrane. Here we performed a similar study of GsMTx4, a stretch-activated channels inhibitor, belonging to the same peptide family as HaTx1. Both toxins have an ellipsoidal shape, a belt of positively charged residues around the periphery, and a hydrophobic protrusion. Results show that, like HaTx1, GsMTx4 can interact with the membrane in two different ways. When all the positively charged residues interact with the outer leaflet lipid, GsMTx4 can assume a shallow binding mode. On the other hand, when the electrostatic interaction brings the positively charged groups of K-8 and K-28 into the vicinity of the carbonyl oxygen atoms of the inner leaflet lipids, the system exhibits a deep binding mode. This deep mode is accompanied by local membrane thinning. For both HaTx1 and GsMTx4, our mean force measurement analyses show that the deep binding mode is energetically favored over the shallow mode when a DPPC (dipalmitoyl-phosphatidylcholine) membrane is used at 310 K. In contrast, when a POPC (palmitooleoyl-phosphatidylcholine) membrane is used at 310 K, the two binding modes exhibited similar stability for both toxins. Similar analyses with DPPC membrane at 330 K led to an intermediary result between the above two results. Therefore, the structure of the lipid acyl chains appears to influence the location and the dynamics of the toxins within biological membranes. We also compared the behavior of an arginine and a lysine residue within the membrane. This is of interest because the arginine residue interaction with the lipid carbonyl oxygen atoms mediates the deep binding mode for HaTx1, whereas the lysine residue plays that role for GsMTx4. The arginine residue generally shows smoother dynamics near the lipid carbonyl oxygen atoms than the lysine residue. This difference between arginine and lysine may partly account for the functional diversity of the members of the toxin family.     

Cation-pi interactions studied in a model coiled-coil peptide

Cation-pi interactions between aromatic amino acids and the positively charged residues lysine and arginine have been proposed to play an important role in stabilizing protein structure. We have used a peptide that adopts a coiled coil structure as a model system to evaluate the energetic contribution of cation-pi interactions to protein folding. Peptides were designed in which phenylalanine, tyrosine, and tryptophan were placed at a solvent-exposed position of the helix, one turn removed from an arginine residue that could provide a favorable cation-pi interaction. Only the arginine-phenylalanine pairing provided significant stabilization of the peptide structure and it appears that hydrophobic packing, rather than the cation-pi effect, is more likely to be responsible for the stability of this peptide. We conclude that any stabilizing effect of cation-pi interactions in these peptides is much smaller than that predicted from computational studies.     

In silico study on the effect of surface lysines and arginines on the electrostatic interactions and protein stability

Charged amino acids are mostly exposed on a protein surface, thereby forming a network of interactions with the surrounding amino acids as well as with water. In particular, positively charged arginine and lysine have different side chain geometries and provide a different number of potential electrostatic interactions. This study reports a comparative analysis of the difference in the number of two representative electrostatic interactions, such as salt-bridges and hydrogen bonds, contributed by surface arginine and lysine, as well as their effect on protein stability using molecular modeling and dynamics simulation techniques. Two in silico variants, the R variant with all arginines and the K variant with all lysines on the protein surface, were modeled by mutating all the surface lysines to arginines and the surface arginines to lysines, respectively, for each of the 10 model proteins. A structural comparison of the respective two variants showed that the majority of R variants possessed more salt-bridges and hydrogen bond interactions than the K variants, indicating that arginine provides a higher probability of electrostatic interactions than lysine owing to its side chain geometry. Molecular dynamics simulations of these variants revealed the R variants to be more stable than the K variants at room temperature but this effect was not prominent under protein denaturating conditions, such as 353 and 333 K with 8 M urea. These results suggest that the arginine residues on a protein surface contribute to the protein stability slightly more than lysine by enhancing the electrostatic interactions.     

Structural requirements for high-affinity heparin binding: alanine scanning analysis of charged residues in the C-terminal domain of human extracellular superoxide dismutase

An essential property of human extracellular superoxide dismutase (hEC-SOD) is its affinity for heparin and heparan sulfate proteoglycans located on cell surfaces and in the connective tissue matrix. The C-terminal domain of hEC-SOD plays the major role in this interaction. This domain has an unusually high content of charged amino acids: six arginine, three lysine, and five glutamic acid residues. In this study, we used alanine scanning mutagenesis of charged amino acids in the C-terminal domain to elucidate the requirements for the heparin/heparan sulfate interaction. As a tool in this study, we used a fusion protein comprising the C-terminal domain of hEC-SOD fused to human carbonic anhydrase II (HCAII). The interaction studies were performed using the surface plasmon resonance technique and heparin-Sepharose chromatography. Replacement of the glutamic acid residues by alanine resulted, in all cases, in tighter binding. All alanine substitutions of basic amino acid residues, except one (R205A), reduced heparin affinity. The arginine and lysine residues in the cluster of basic amino acid residues (residues 210-215), the RK-cluster, are of critical importance for the binding to heparin, and arginine residues promote stronger interactions than lysine residues.     

Influence of cation-pi interactions in different folding types of membrane proteins

Cation-pi interactions play an important role to the stability of protein structures. In this work, we analyze the influence of cation-pi interactions in three-dimensional structures of membrane proteins. We found that transmembrane strand (TMS) proteins have more number of cation-pi interactions than transmembrane helical (TMH) proteins. In TMH proteins, both the positively charged residues Lys and Arg equally experience favorable cation-pi interactions whereas in TMS proteins, Arg is more likely than Lys to be in such interactions. There is no relationship between number of cation-pi interactions and number of residues in TMH proteins whereas a good correlation was observed in TMS proteins. The average cation-pi interaction energy for TMH proteins is -16 kcal/mol and that for TMS proteins is -27 kcal/mol. The pair-wise cation-pi interaction energy between aromatic and positively charged residues showed that Lys-Trp energy is stronger in TMS proteins than TMH proteins; Arg-Phe, Arg-Tyr and Lys-Phe have higher energy in TMH proteins than TMS proteins. The decomposition of energies into electrostatic and van der Waals revealed that the contribution from electrostatic energy is twice as that from van der Waals energy in both TMH and TMS proteins. The results obtained in the present study would be helpful to understand the contribution of cation-pi interactions to the stability of membrane proteins.     

Structure-sweetness relationship in egg white lysozyme: role of lysine and arginine residues on the elicitation of lysozyme sweetness

Lysozyme is one of the sweet-tasting proteins. To clarify the structure-sweetness relationship and the basicity-sweetness relationship in lysozyme, we have generated lysozyme mutants with Pichia systems. Alanine substitution of lysine residues demonstrated that two out of six lysine residues, Lys13 and Lys96, are required for lysozyme sweetness, while the remaining four lysine residues do not play a significant role in the perception of sweetness. Arginine substitution of lysine residues revealed that the basicity, but not the shape, of the side chain plays a significant role in sweetness. Single alanine substitutions of arginine residues showed that three arginine residues, Arg14, Arg21, and Arg73, play significant roles in lysozyme sweetness, whereas Arg45, Arg68, Arg125 and chemical modification by 1,2-cyclohexanedione did not affect sweetness. From investigation of the charge-specific mutations, we found that the basicity of a broad surface region formed by five positively charged residues, Lys13, Lys96, Arg14, Arg21, and Arg73, is required for lysozyme sweetness. Differences in the threshold values among sweet-tasting proteins might be caused by the broadness and/or the density of charged residues on the protein surface.     

A study on the effect of surface lysine to arginine mutagenesis on protein stability and structure using green fluorescent protein

Two positively charged basic amino acids, arginine and lysine, are mostly exposed to protein surface, and play important roles in protein stability by forming electrostatic interactions. In particular, the guanidinium group of arginine allows interactions in three possible directions, which enables arginine to form a larger number of electrostatic interactions compared to lysine. The higher pKa of the basic residue in arginine may also generate more stable ionic interactions than lysine. This paper reports an investigation whether the advantageous properties of arginine over lysine can be utilized to enhance protein stability. A variant of green fluorescent protein (GFP) was created by mutating the maximum possible number of lysine residues on the surface to arginines while retaining the activity. When the stability of the variant was examined under a range of denaturing conditions, the variant was relatively more stable compared to control GFP in the presence of chemical denaturants such as urea, alkaline pH and ionic detergents, but the thermal stability of the protein was not changed. The modeled structure of the variant indicated putative new salt bridges and hydrogen bond interactions that help improve the rigidity of the protein against different chemical denaturants. Structural analyses of the electrostatic interactions also confirmed that the geometric properties of the guanidinium group in arginine had such effects. On the other hand, the altered electrostatic interactions induced by the mutagenesis of surface lysines to arginines adversely affected protein folding, which decreased the productivity of the functional form of the variant. These results suggest that the surface lysine mutagenesis to arginines can be considered one of the parameters in protein stability engineering.     

A hydrophilic microenvironment in the substrate-translocating groove of the YidC membrane insertase is essential for enzyme function

The YidC family of proteins are membrane insertases that catalyze the translocation of the periplasmic domain of membrane proteins via a hydrophilic groove located within the inner leaflet of the membrane. All homologs have a strictly conserved, positively charged residue in the center of this groove. In Bacillus subtilis, the positively charged residue has been proposed to be essential for interacting with negatively charged residues of the substrate, supporting a hypothesis that YidC catalyzes insertion via an early-step electrostatic attraction mechanism. Here, we provide data suggesting that the positively charged residue is important not for its charge but for increasing the hydrophilicity of the groove. We found that the positively charged residue is dispensable for Escherichia coli YidC function when an adjacent residue at position 517 was hydrophilic or aromatic, but was essential when the adjacent residue was apolar. Additionally, solvent accessibility studies support the idea that the conserved positively charged residue functions to keep the top and middle of the groove sufficiently hydrated. Moreover, we demonstrate that both the E. coli and Streptococcus mutans YidC homologs are functional when the strictly conserved arginine is replaced with a negatively charged residue, provided proper stabilization from neighboring residues. These combined results show that the positively charged residue functions to maintain a hydrophilic microenvironment in the groove necessary for the insertase activity, rather than to form electrostatic interactions with the substrates.     

Positive charges in the cytoplasmic domain of Escherichia coli leader peptidase prevent an apolar domain from functioning as a signal.

Leader peptidase, an integral transmembrane protein of Escherichia coli, requires two apolar topogenic elements for its membrane assembly: a 'hydrophobic helper' and an internal signal. The highly basic cytoplasmic region between these domains is a translocation poison sequence, which we have shown blocks the function of a preceding signal sequence. We have used oligonucleotide-directed mutagenesis to remove positively charged residues within this polar domain to determine if it is the basic character in this region that has the negative effect on translocation. Our results show that mutations that remove two or more of the positively charged residues within the polar region no longer block membrane assembly of leader peptidase. In addition, when the translocation poison domain (residues 30-52) is replaced with six lysine residues, the preceding apolar domain cannot function as an export signal, whereas it can with six glutamic acids. Thus, positively charged residues within membrane proteins may have a major role in determining the function of hydrophobic domains in membrane assembly.     

Discrimination between different methylation states of chemotaxis receptor Tar by receptor methyltransferase CheR

Bacterial chemotaxis receptors are posttranslationally modified by carboxyl methylation of specific glutamate residues within their cytoplasmic domains. This highly regulated, reversible modification counterbalances the signaling effects of ligand binding and contributes to adaptation. On the basis of the crystal structure of the gamma-glutamyl methyltransferase CheR, we have postulated that positively charged residues in helix alpha2 in the N-terminal domain of the enzyme may be complementary to the negatively charged methylation region of the methyltransferase substrates, the bacterial chemotaxis receptors. Several altered CheR proteins, in which positively charged arginine or lysine residues were substituted with alanines, were constructed and assayed for their methylation activities toward wild-type receptor and a series of receptor variants containing different glutamates available for methylation. One of the CheR mutant proteins (Arg53Ala) showed significantly lower activity toward all receptor constructs, suggesting that Arg53 may play a general role in catalysis of methyl transfer. The rest of the mutant proteins exhibited different patterns of relative methylation rates toward different receptor substrates, indicating specificity, probably through interaction of CheR with the receptor at sites distal to the specific site of methylation. The findings imply complementarity between positively charged residues of the alpha2 helix of CheR and the negatively charged glutamates of the receptor. It is likely that this complementarity is involved in discriminating different methylation states of the receptors.     

Evidence for a direct role for sialic acid in the attachment of encephalomyocarditis virus to human erythrocytes

Sialic acid residues are required in cellular receptors for many different mammalian viruses. Sialic acid could have a direct role, being an integral part of the virus binding site on the receptor. Alternatively, negatively charged sialic acid could have an indirect role, being responsible for holding the receptor in the required configuration for virus recognition, for instance, by interacting with positively charged amino acid residues found in the polypeptide chain of receptors. We have investigated the role of sialic acid in virus attachment by studying the interaction of the small RNA virus encephalomyocarditis (EMC) with glycophorin A, its receptor on human erythrocytes. In several experiments, influenza virus A was used for control purposes. Blocking positive charges on glycophorin either in lysine residues by acetylation or in arginine residues with butanedione did not affect its interaction with EMC virus. In contrast, blocking negatively charged carboxyl groups in sialic acid residues by amidation destroyed the ability of glycophorin to inhibit EMC virus attachment suggesting an important role for this part of sialic acid in EMC virus attachment. Removal of the polyhydroxy side chain in sialic acid residues of glycophorin by mild oxidation with periodate followed by reduction with borohydride had little effect on its interaction with EMC virus. Further, sialic acid species with either an acetyl or glycolyl group attached to the amino group on position 5 interacted equally well with EMC virus.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of different positively charged amino acids, C-terminally of the signal peptidase cleavage site, on the translocation kinetics of a precursor protein in Escherichia coli K-12

Abstract Introduction of positively charged amino acids immediately downstream of the signal sequence in prokaryotic precursor proteins is known to affect the export process. However, it is not clear whether different positively charged amino acids affect the export process similarly. To investigate this, the glutamate at position +2 of outer membrane protein PhoE was substituted by arginine, lysine of histidine. Pulse-chase experiments revealed that the Lys and Arg residues at position +2 caused a reduced processing rate, and that the effect was markedly more severe in the case of the Arg residue. Trypsin accessibility experiments revealed that the accumulated precursors were present in the cytoplasm. Since the degree of the inhibitory effect corresponded to the p K _{r a} of the different positively charged amino acids, this suggests that the positively charged residues must be deprotonated during the secretory process.     

Interaction of lysine residues with the metal thiolate clusters in metallothionein

Metallothioneins are unique diamagnetic metal thiolate cluster proteins. Both vertebrate and invertebrate forms contain, besides their large cysteine content (30%), up to 14% lysine plus arginine. In the amino acid sequences, the basic residues are juxtaposed to cysteine residues and have been suggested to play a role in neutralizing the excess negative charge of the metal thiolate complexes [Kojima, Y., Berger, C., Vallee, B. L., & K?gi, J. H. R. (1976) Proc. Natl. Acad. Sci. U.S.A. 73, 3413-3417]. To document such a function, we compared the susceptibility of the lysine residues in cadmium and zinc metallothioneins and in the metal-free S-carboxamidomethyl derivative toward arylation by trinitrobenzenesulfonic acid. The results show an at least 20-fold lower initial rate of reaction with the metal-containing as opposed to that with the metal-free form, indicating a protective effect of metal complex formation on the lysine residues, the degree of protection being dependent on the nature of the metal. The modification of the lysine residues by trinitrobenzenesulfonic acid produces changes in the CD spectral features of the cadmium thiolate cluster structure. The lowered chemical reactivity of the lysine residues in the metal-containing form correlates with an upward displacement of their average pKa's to 10.9 from 10.3 in the metal-free S-carboxamidomethyl derivative. We attribute these effects at least in part to hydrogen bonding of the positively charged epsilon-amino groups to the thiolate ligands of the negatively charged cadmium thiolate units.     

The translocation of negatively charged residues across the membrane is driven by the electrochemical potential: evidence for an electrophoresis-like membrane transfer mechanism.

The role of the membrane electrochemical potential in the translocation of acidic and basic residues across the membrane was investigated with the M13 procoat protein, which has a short periplasmic loop, and leader peptidase, which has an extended periplasmically located N-terminal tail. For both proteins we find that the membrane potential promotes membrane transfer only when negatively charged residues are present within the translocated domain. When these residues are substituted by uncharged amino acids, the proteins insert into the membrane independently of the potential. In contrast, when a positively charged residue is present within the N-terminal tail of leader peptidase, the potential impedes translocation of the tail domain. However, an impediment was not observed in the case of the procoat protein, where positively charged residues in the central loop are translocated even in the presence of the membrane potential. Intriguingly, several of the negatively charged procoat proteins required the SecA and SecY proteins for optimal translocation. The studies reported here provide insights into the role of the potential in membrane protein assembly and suggest that electrophoresis can play an important role in controlling membrane topology.     

Electrostatic interactions play an essential role in the binding of oleic acid with α‐lactalbumin in the HAMLET‐like complex: A study using charge‐specific chemical modifications

H uman α ‐lactalbumin m ade le thal to t umor cells (HAMLET) and its analogs are partially unfolded protein‐oleic acid (OA) complexes that exhibit selective tumoricidal activity normally absent in the native protein itself. To understand the nature of the interaction between protein and OA moieties, charge‐specific chemical modifications of lysine side chains involving citraconylation, acetylation, and guanidination were employed and the biophysical and biological properties were probed. Upon converting the original positively‐charged lysine residues to negatively‐charged citraconyl or neutral acetyl groups, the binding of OA to protein was eliminated, as were any cytotoxic activities towards osteosarcoma cells. Retention of the positive charges by converting lysine residues to homoarginine groups (guanidination); however, yielded unchanged binding of OA to protein and identical tumoricidal activity to that displayed by the wild‐type α‐lactalbumin‐oleic acid complex. With the addition of OA, the wild‐type and guanidinated α‐lactalbumin proteins underwent substantial conformational changes, such as partial unfolding, loss of tertiary structure, but retention of secondary structure. In contrast, no significant conformational changes were observed in the citraconylated and acetylated α‐lactalbumins, most likely because of the absence of OA binding. These results suggest that electrostatic interactions between the positively‐charged basic groups on α‐lactalbumin and the negatively‐charged carboxylate groups on OA molecules play an essential role in the binding of OA to α‐lactalbumin and that these interactions appear to be as important as hydrophobic interactions. Proteins 2013. © 2012 Wiley Periodicals, Inc.     

Chemical modification studies of Rhizomucor miehei protease: evidence for the role of basic amino acids in enzyme catalysis.

The effect of chemical modification on milk clotting and proteolytic activities of aspartyl protease obtained from Rhizomucor miehei NRRL 3500 was examined in the absence and the presence of its specific inhibitor pepstatin A. The effect on the ratio of milk clotting activity (MC) to proteolytic activity (PA), an index of the quality of milk clotting proteases was also determined. Modification of the enzyme with trinitrobenzenesulfonic acid, diethylpyrocarbonate and phenylglyoxal produced an increase in the ratio of MC/PA, while modification with 2- hydroxy-5-nitrobenzyl bromide did not affect the ratio. Modification with N-acetylimidazole resulted in a marginal increase in MC/PA ratio. Protection using pepstatin A during modification with phenylglyoxal, N-acetylimidazole and 2-hydroxy-5-nitrobenzyl bromide, protected both MC and PA. In the case of modification by diethylpyrocarbonate, pepstatin A protected only MC. Pepstatin A did not protect both the activities on the modification of the enzyme by trinitrobenzene sulfonic acid. These observations indicate the presence of arginine, tyrosine and tryptophan at the catalytic site of the enzyme, for eliciting MC and PA of the enzyme. In general, modification of the positively charged residues increases the MC/PA ratio of the enzyme. In addition the modified lysine residues responsible for the inactivation of the enzyme were not involved in the active site of the enzyme. Thus the lysine residues might have a secondary role in enzyme catalysis. Further, histidine at the catalytic site was found to be exclusively involved in milk clotting activity. The enzyme with modified histidine residues were more susceptible to autocatalysis, indicating that histidine residues protect the enzyme against autolysis.     

Importance of the lysine cluster in the translocation of anions through the pyrophosphate specific channel OprO

Pseudomonas aeruginosa is a Gram-negative bacterium with an intrinsic resistance towards antibiotics due to the lack of a large diffusion pores. Exchange of substances with the environment is done mainly through a set of narrow and substrate-specific porins in its outer membrane that filter molecules according to their size and chemical composition. Among these proteins are OprP and OprO involved in the selective uptake of mono- and pyrophosphates, respectively. Both proteins are homotrimers and each monomer features an hourglass-shaped channel structure including a periplasmic cavity with a lysine cluster. In this study, we focus on the characterization of this lysine cluster in OprO. The importance of these lysine residues was shown with alanine substitutions in single channel conductance experiments, by titration of mono- and pyrophosphate in multi-channel analysis and by molecular dynamics simulations. All obtained data demonstrated that the closer the mutated lysine residues are to arginine 133, the lower gets the single channel conductance. It was found that the ion flow through each monomer can follow two different lysine paths indicating that phosphate ions have a larger freedom on the periplasmic side of the constriction region. Our results emphasize the important role of the lysine residue 121 in the binding site together with arginine 133 and aspartic acid 94. An improved understanding of the ion mobility across these channels can potentially lead to an optimized permeation of (phosphonic acid containing) antibiotics through the outer membrane of P. aeruginosa and the development of new drug molecules.