Nilashis Nandi

Correlation between the microscopic and mesoscopic chirality in Langmuir monolayers

In this review, we briefly discuss the present status of the experimental information based on Brewster-angle microscopic studies of chiral monolayers and recent molecular theories on chiral amphiphilic systems. The theoretical results are compared with experimental information. Attention has been drawn to the fact that chirality present at the molecular level (at the microscopic length scale) is responsible for driving the chiral shape of the domains composed of such molecules which are of mesoscopic dimension. In some cases, strong influences of molecular chirality on the domain morphology are observed. While such correlations between chirality present at different levels of the structural hierarchy are known for many biological assemblies, the recent studies on biomimetic Langmuir monolayers conclusively provide a correlation between chirality present at different length scales of the molecular architecture.

Mechanism of the activation step of the aminoacylation reaction: a significant difference between class I and class II synthetases

In the present work we report, for the first time, a novel difference in the molecular mechanism of the activation step of aminoacylation reaction between the class I and class II aminoacyl tRNA synthetases (aaRSs). The observed difference is in the mode of nucleophilic attack by the oxygen atom of the carboxylic group of the substrate amino acid (AA) to the αP atom of adenosine triphosphate (ATP). The syn oxygen atom of the carboxylic group attacks the α-phosphorous atom (αP) of ATP in all class I aaRSs (except TrpRS) investigated, while the anti oxygen atom attacks in the case of class II aaRSs. The class I aaRSs investigated are GluRS, GlnRS, TyrRS, TrpRS, LeuRS, ValRS, IleRS, CysRS, and MetRS and class II aaRSs investigated are HisRS, LysRS, ProRS, AspRS, AsnRS, AlaRS, GlyRS, PheRS, and ThrRS. The variation of the electron density at bond critical points as a function of the conformation of the attacking oxygen atom measured by the dihedral angle ψ (Cα–C′) conclusively proves this. The result shows that the strength of the interaction of syn oxygen and αP is stronger than the interaction with the anti oxygen for class I aaRSs. This indicates that the syn oxygen is the most probable candidate for the nucleophilic attack in class I aaRSs. The result is further supported by the computation of the variation of the nonbonded interaction energies between αP atom and anti oxygen as well as syn oxygen in class I and II aaRSs, respectively. The difference in mechanism is explained based on the analysis of the electrostatic potential of the AA and ATP which shows that the relative arrangement of the ATP with respect to the AA is opposite in class I and class II aaRSs, which is correlated with the organization of the active site in respective aaRSs. A comparative study of the reaction mechanisms of the activation step in a class I aaRS (Glutaminyl tRNA synthetase) and in a class II aaRS (Histidyl tRNA synthetase) is carried out by the transition state analysis. The atoms in molecule analysis of the interaction between active site residues or ions and substrates are carried out in the reactant state and the transition state. The result shows that the observed novel difference in the mechanism is correlated with the organizations of the active sites of the respective aaRSs. The result has implication in understanding the experimentally observed different modes of tRNA binding in the two classes of aaRSs.

Chirality in Biological Nanospaces : Reactions in Active Sites

Introduction Chirality and chiral discrimination Enzymes, active site, and vital biological reactions Chirality and reactions in active sites References Chiral discrimination in the active site of oxidoreductase Cytochrome P450: discrimination in drug (warfarin) interaction Enantioselectivity of hydride transfer of NADPH by alcohol oxidoreductase and conversion of epoxide to ss-keto acid by 2-[(R)-2-hydroxypropylthio]-ethanesulfonate dehydrogenase Lipooxygenase and cyclooxygenase: generation of chiral peroxide from achiral polyunsaturated fatty acid Nitric oxide synthase: effects of substrate and cofactors on chiral discrimination for binding the enantiomeric ligands Enoyl reductase: chirality dependent branching of a growing polyketide chain References Transferases and chiral discrimination Peptidyl transferase center within ribosome: peptide bond formation and chiral discrimination Chiral discrimination by telomerase Chiral discrimination by HIV-1 reverse transcriptase Chiral discrimination and nuclear DNA polymerases References Influence of chirality on the hydrolysis reactions within the active site of hydrolases Chiral discrimination by epoxide hydrolases Chiral discrimination by lipases References Influence of chirality on the reactions in the active site of lyases Hydroxynitrile lyases: interaction with chiral substrates Acceptance of both epimers of uronic acid by chondroitin lyase ABC References Chiral discrimination in the active site of ligases Chiral discrimination by germacrene D synthases Chiral discrimination by aminoacyl-tRNA synthetases References Summary and future References Index

Chiral discrimination in the confined environment of biological nanospace: reactions and interactions involving amino acids and peptides

Although chiral discrimination in biological systems is overwhelmingly present, its molecular mechanism remained a puzzle. Why the basic blocks of life like L-amino acid and D-sugar are not being scrambled and retain enantiomeric purity since evolution is an unresolved question. In the present review we focus on the recent experimental and computational studies on the chiral discrimination in reactions such as peptide synthesis and aminoacylation. Experimental studies have shown that a clear homochiral preference exists favouring L-amino acid. Recent combined quantum mechanical/molecular mechanical studies explain the high level of stereospecificity of the processes and revealed multiple factors responsible for the discrimination and concomitant retention of the biological homochirality. Chirality of the relevant molecular segments and the intricate interaction between them as well as with the surrounding residues are important. The confinement of the chiral reactants within the biological nanospaces like the peptidyl transferase centre in tRNA and active site of the aminoacyl transferase as well as the nanoscale proximity are important for the manifestation of the discrimination. Multiple favourable influences of the stereochemistry of the natural chirality (D-form) of the sugar ring are noted. This explains the heterochiral relationship of the D-sugar and L-amino acid in biology. In addition to factors such as chirality, confinement and nanoscale proximity of the molecular segments, the network of electrostatic interaction present in the active site plays a significant role in the chiral discrimination in aminoacylation. Chiral discriminations in the biological cavities of nucleic acid and cyclodextrin are also briefly reviewed.

Chirality and protein biosynthesis.

Chirality is present at all levels of structural hierarchy of protein and plays a significant role in protein biosynthesis. The macromolecules involved in protein biosynthesis such as aminoacyl tRNA synthetase and ribosome have chiral subunits. Despite the omnipresence of chirality in the biosynthetic pathway, its origin, role in current pathway, and importance is far from understood. In this review we first present an introduction to biochirality and its relevance to protein biosynthesis. Major propositions about the prebiotic origin of biomolecules are presented with particular reference to proteins and nucleic acids. The problem of the origin of homochirality is unresolved at present. The chiral discrimination by enzymes involved in protein synthesis is essential for keeping the life process going. However, questions remained pertaining to the mechanism of chiral discrimination and concomitant retention of biochirality. We discuss the experimental evidence which shows that it is virtually impossible to incorporate D-amino acids in protein structures in present biosynthetic pathways via any of the two major steps of protein synthesis, namely aminoacylation and peptide bond formation reactions. Molecular level explanations of the stringent chiral specificity in each step are extended based on computational analysis. A detailed account of the current state of understanding of the mechanism of chiral discrimination during aminoacylation in the active site of aminoacyl tRNA synthetase and peptide bond formation in ribosomal peptidyl transferase center is presented. Finally, it is pointed out that the understanding of the mechanism of retention of enantiopurity has implications in developing novel enzyme mimetic systems and biocatalysts and might be useful in chiral drug design.

Differential Förster Resonance Energy Transfer from the Excimers of Poly(N-vinylcarbazole) to Coumarin 153

Photophysics of the nonconjugated vinyl polymer poly(N-vinylcarbazole) (PNVC) has been explored in the presence of coumarin 153 (C153) exploiting steady state and time-resolved fluorometric techniques. Dual emission from the two distinct excimers of PNVC adds importance to the study and makes it interesting. The study substantiates the occurrence of Förster resonance energy transfer (FRET) from PNVC to C153. The differential involvement of the two excimers in the energy transfer process has been established. Considering the fact that FRET is a long distance dipole induced phenomenon, this differential effect has been rationalized from a difference in the dipole moments of the two excimers. Determination of the quenching constants reveals an order of magnitude more quenching of the high energy excimer than the low energy one in the presence of the quencher C153.

Aminoacylation reaction in the histidyl-tRNA synthetase: fidelity mechanism of the activation step.

Aminoacylation is a vital step of natural biosynthesis of peptide. Correct aminoacylation is a necessary prerequisite for the elimination of noncognate amino acids such as D-amino acids. In the present work, we studied the fidelity mechanism of histidine (His) activation (first step of aminoacylation reaction) using a combined quantum mechanical/semiempirical method based on a model of crystal structure of the oligomeric complex of histidyl-tRNA synthetase (HisRS) from Escherichia coli. The study of the variation in the energy during the mutual approach of the His and ATP to form adenylate shows that the surrounding nanospace of synthetase confines the reactants (L-His and ATP) and proximally places in a geometry suitable for the in-line nucleophilic attack. The significantly higher energy of the energy surface of the model containing D-His is due to unfavorable interaction of D-His with ATP and surrounding residues. This indicates that the network of interaction (principally electrostatic) is highly unfavorable when D-amino acid is incorporated. The reorganization of the surrounding nanospace can lower the unfavorable nature of the intermolecular energy surface of D-His and surrounding residues. However, such a rearrangement requires large-scale structural reorganization of the synthetase structure and is unfavorable. The variation in the bond angles and distances in going from the reactant state to the product state via transition state confirms the mechanism of nucleophilic attack and concomitant inversion of oxygen atoms around alpha-phosphorus (alpha-P). Calculation of the electrostatic potential indicates that in addition to the Mg(2+) the Arg residues in the active site facilitate the nucleophilic attack by reducing the negative charge distributed over the oxygen atoms attached to the alpha-P of ATP. Arg 259 residue has a role similar to that played by the two Mg(2+) cations as this residue is in close proximity of the alpha-P of ATP. Arg 113 also facilitates the reduction of the negative charge on the other side of the reaction center. The favorable electrostatic interaction of the Arg 259 with ATP and His is also concluded from the calculation of the binding energy. The Arg 259 anchors the carboxylic acid group of His and the oxygen atom of the alpha-phosphate group during the progress of reaction. Consequently, Arg 259 plays an important catalytic role in the activation step rather than merely reducing the negative charge density over the ATP.

Orientation and distance dependent chiral discrimination in the first step of the aminoacylation reaction: Integrated molecular orbital and semi-empirical method (ONIOM) based calculation

Aminoacylation is a vital step in natural biosynthesis process of peptide and is the key step in correlating the realm of protein with the RNA world. Incorrect aminoacylation might lead to misacylation of d-amino acid in the tRNA which might cause synthesis of a hetero-peptide rather than natural homopeptide leading to the altered functionality of the peptide. However, the accuracy of this process is remarkable and leads to the attachment of the correct enantiomer of the amino acid with their cognate tRNA. Thus, the chiral discrimination is stringent. In the present work, we presented a combined ONIOM (ab initio/semi-empirical) study of the chiral discrimination in the first step of aminoacylation reaction based on a model of crystal structure of the oligomeric complex of histidyl-tRNA synthetase (HisRS) from Escherichia coli complexed with ATP and histidinol and histidyl-adenylate. The study reveals that the molecular mechanism of the chiral discrimination involves the amino acid, ATP as well as surrounding residues of the synthetase. Several factors are noted to be responsible for discrimination and explain the high level of stereospecificity of the process. The chirality of the amino acid of the substrate and its (principally) electrostatic interaction with the ATP is important for discrimination. The distance and orientational changes involved in the approach of the d-His towards the ATP is energetically unfavorable. The charge distributions on the His and ATP are important for the discrimination. Removal of the charges in the model drastically reduces the discrimination. Restricted nature of the mutual orientation within the cavity of the active site where the His and ATP are located during the change in orientation for the approach to form the adenylate makes the resultant interaction profile as different for l-His and d-His also influences chiral discrimination. The analysis of the transition state structure revealed that alteration of the chirality of the His destabilize the transition state by removing the favorable electrostatic interaction between the Glu-83 and NH(3)(+) group of the His substrate. The proximity of the surrounding residues as present in the active site of the synthetase with the His and ATP (the separation is of nanometer range) has influence of discrimination. The study provides a molecular mechanism of the retention of biological homochirality.

Helfrich's concept of intrinsic force and its molecular origin in bilayers and monolayers

Bilayers and monolayers are excellent models of biological membranes. The constituents of the biological membranes such as lipids, cholesterols and proteins are chiral. Chiral molecules are abundant in nature (protein, nucleic acid and lipid). It is obvious that relationship between chirality and morphology (as well as function) of biological membrane is of interest for its fundamental importance and has technological implication regarding various membrane functions. The recent years have witnessed that a number of experimental studies in biomimetic systems have shown fascinating morphologies where chirality of the constituent molecule has decisive influence. Significant progress is made towards the understanding of these systems from the theoretical and computational studies. Helfrichs concept of intrinsic force arising from chirality is a milestone in understanding the biomimetic system such as bilayer and the related concepts, further progresses in molecular understanding made in recent years and experimental studies revealing the influence of chirality on morphology are the focus of the present review. Helfrichs concept of intrinsic force arising due to chirality is useful in understanding two-dimensional bilayers and one-dimensional monolayers and related mimetic systems. Various experimental techniques are used, which can probe the molecular architecture of these mimetic systems at different length scales and both macroscopic (thermodynamic) as well as microscopic (molecular) theories are developed. These studies are aimed to understand the role of chirality in the molecular interaction when the corresponding molecule is present in an aggregate. When one looks into the variety of morphologies exhibited by three-dimensional bilayer and two-dimensional monolayer, the later types of systems are more exotic in the sense that they show more diversity and interesting chiral discrimination. Helfrichs concept of intrinsic force may be considered useful in both cases. The intrinsic force due to chirality is the decisive factor in determining morphology which is explained by molecular approaches. Finally, biological and technological implications of such morphological variations are briefly mentioned.

Dynamics of the Active Sites of Dimeric Seryl tRNA Synthetase from Methanopyrus kandleri.

Aminoacyl tRNA synthetases (aaRSs) carry out the first step of protein biosynthesis. Several aaRSs are multimeric, and coordination between the dynamics of active sites present in each monomer is a prerequisite for the fast and accurate aminoacylation. However, important lacunae of understanding exist concerning the conformational dynamics of multimeric aaRSs. Questions remained unanswered pertaining to the dynamics of the active site. Little is known concerning the conformational dynamics of the active sites in response to the substrate binding, reorganization of the catalytic residues around reactants, time-dependent changes at the reaction center, which are essential for facilitating the nucleophilic attack, and interactions at the interface of neighboring monomers. In the present work, we carried out all-atom molecular dynamics simulation of dimeric (mk)SerRS from Methanopyrus kandleri bound with tRNA using an explicit solvent system. Two dimeric states of seryl tRNA synthetase (open, substrate bound, and adenylate bound) and two monomeric states (open and substrate bound) are simulated with bound tRNA. The aim is to understand the conformational dynamics of (mk)SerRS during its reaction cycle. While the present results provide a clear dynamical perspective of the active sites of (mk)SerRS, they corroborate with the results from the time-averaged experimental data such as crystallographic and mutation analysis of methanogenic SerRS from M. kandleri and M. barkeri. It is observed from the present simulation that the motif 2 loop gates the active site and its Glu351 and Arg360 stabilizes ATP in a bent state favorable for nucleophilic attack. The flexibility of the walls of the active site gradually reduces near reaction center, which is a more organized region compared to the lid region. The motif 2 loop anchors Ser and ATP using Arg349 in a hydrogen bonded geometry crucial for nucleophilic attack and favorably influences the electrostatic potential at the reaction center. Synchronously, Arg366 of the β sheet at the base holds the syn oxygen of the attacking carboxylic group so that the attack by the anti oxygen is feasible. This residue also contributes to the reduction of the unfavorable electrostatic potential at the reaction center. Present simulation clearly shows the catalytic role of the residues at reaction center. A precise and stable geometry of hydrogen bonded network develops within the active site, which is essential for the development of an optimum transition state geometry. All loops move away from the platform of active site in the open or adenylate bound state and the network of hydrogen bond disappears. The serine binding site is most rigid among all three subsites. The Ser is held here in a highly organized geometry bound by Zn(2+) and Cys residues. Present simulation further suggests that the helix-turn-helix motif connecting the monomers might have important role in coordinating the functional dynamics of the two active sites. The N-terminal domain is involved in long-range electrostatic interaction and specific hydrogen bond interaction (both direct and water mediated) with tRNA. Overall conformational fluctuation is less in the N terminal compared to the catalytic domain due to the presence of a motif 2 loop, loop f, and serine ordering loop, which change conformation in the later domain during the reaction cycle. The dynamic perspective of the active site of (mk)SerRS with the mobile loop acting as the gate and dynamically silent β sheets performing as the base has similarity with the perception of the active site in various other enzymes.