Characterization of low-energy excited states in the native state ensemble of non-myristoylated and myristoylated neuronal calcium sensor-1.

Information on the low-energy excited states of a given protein is important as this controls the structural adaptability and various biological functions of proteins such as co-operativity, response towards various external perturbations. In this article, we characterized individual residues in both non-myristoylated (non-myr) and myristoylated (myr) neuronal calcium sensor-1 (NCS-1) that access alternate states by measuring nonlinear temperature dependence of the backbone amide-proton (¹H(N)) chemical shifts. We found that ~20% of the residues in the protein access alternative conformations in non-myr case, which increases to ~28% for myr NCS-1. These residues are spread over the entire polypeptide stretch and include the edges of α-helices and ß-strands, flexible loop regions, and the Ca²(+)-binding loops. Besides, residues responsible for the absence of Ca²(+)-myristoyl switch are also found accessing alternative states. The C-terminal domain is more populated with these residues compared to its N-terminal counterpart. Individual EF-hands in NCS-1 show significantly different number of alternate states. This observation prompts us to conclude that this may lead to differences in their individual conformational flexibility and has implications on the functionality. Theoretical simulations reveal that these low-energy excited states are within an energy band of 2-4 kcal/mol with respect to the native state.

N-terminal myristoylation alters the calcium binding pathways in neuronal calcium sensor-1.

Neuronal calcium sensor-1 (NCS-1) interacts with many membranes and cytosolic proteins, both in a Ca(2+)-dependent and in a Ca(2+)-independent manner, and its physiological role is governed by its N-terminal myristoylation. To understand the role of myristoylation in altering Ca(2+) response and other basic biophysical properties, we have characterized the Ca(2+) filling pathways in both myristoylated (myr) and non-myristoylated (non-myr) forms of NCS-1. We have observed that Ca(2+) binds simultaneously to all three active EF-hands in non-myr NCS-1, whereas in the case of myr NCS-1, the process is sequential, where the second EF-hand is filled first, followed by the third and fourth EF-hands. In the case of myr NCS-1, the observed sequential Ca(2+) binding process becomes more prominent in the presence of Mg(2+). Besides, the analysis of (15)N-relaxation data reveals that non-myr NCS-1 is more dynamic than myr NCS-1. The overall molecular tumbling correlation time increases by approximately 20% upon myristoylation. Comparing the apo forms of non-myr NCS-1 and myr NCS-1, we found the possibility of existence of some substates, which are structurally closer to the holo form of the protein. There are more such substates in the case of non-myr NCS-1 than in the case of the myr NCS-1, suggesting that the former accesses larger volumes of conformational substates compared with the latter. Further, the study reveals that the possibility of Ca(2+) binding simultaneously to different parts of the protein is more favourable in non-myr NCS-1 than in myr NCS-1.

Magnesium Hydrogen Phosphate: An Efficient Catalyst for Acrylic Acid Production from Biorenewable Lactic Acid.

A series of Magnesium hydrogen phosphate (MgHP) catalysts with different magnesium to phosphorous (Mg/P) mole ratios at varying calcination temperatures has been synthesised, bearing in mind the effectiveness as well as the stability of MgHP to catalyse acrylic acid (AA) production from biorenewable lactic acid (LA), a synthetic process applicable to biomass conversion. The physicochemical properties of the MgHP catalysts have been thoroughly characterised and the formation of Mg(NH4)PO4, MgHPO4 and Mg2P2O7 with different structural and acidic properties have been reported. The high catalytic performance of MgHP catalysts with high AA yields (100% conversion and 85% selectivity) at high space velocities (WHSVLA = 3.13 h-1) have been achieved at 360 °C. NH3-Temperature programmed desorption (TPD) and pyridine FTIR have shown that the effectiveness of a catalyst is accounted for not primarily by the actual strength of acidic sites, but is due to the presence of Lewis acidic sites compared to Bronsted sites.

Structural change in a B-DNA helix with hydrostatic pressure.

Study of the effects of pressure on macromolecular structure improves our understanding of the forces governing structure, provides details on the relevance of cavities and packing in structure, increases our understanding of hydration and provides a basis to understand the biology of high-pressure organisms. A study of DNA, in particular, helps us to understand how pressure can affect gene activity. Here we present the first high-resolution experimental study of B-DNA structure at high pressure, using NMR data acquired at pressures up to 200 MPa (2 kbar). The structure of DNA compresses very little, but is distorted so as to widen the minor groove, and to compress hydrogen bonds, with AT pairs compressing more than GC pairs. The minor groove changes are suggested to lead to a compression of the hydration water in the minor groove.

Efficient Vapor-Phase Selective Hydrogenolysis of Bio-Levulinic Acid to γ-Valerolactone Using Cu Supported on Hydrotalcite Catalysts.

In this work, Cu nanoparticles (Cu NPs, 2-20 nm) supported on Hydrotalcite catalysts exhibit enhanced selectivity for γ-valerolactone (GVL) during hydrogenolysis of levulinic acid (LA). At 260 °C, over 3 wt% Cu achieved 87.5% of LA conversion with a maximum GVL selectivity (95%). In contrast, LA hydrogenolysis over 3Cu/Hydrotalcite catalyst is highly active and stable toward the production of GVL due to balanced acido-basicity and higher Cu dispersion with ultrasmall particle sizes, which are investigated through the temperature programmed desorption (TPD) of ammonia, N2O titration, and transmission electron microscopy (TEM) analysis. Hydrotalcite in combination with inexpensive Cu catalyst is found to be an efficient and environmentally benign for LA hydrogenolysis.

Methyl dynamics for understanding hydrophobic core packing of dynamically different motifs of double-stranded RNA binding domain of protein kinase R.

Double-stranded RNA binding domains of human protein kinase R (dsRBD-PKR) regulate distinct cellular functions and the fate of an RNA molecule in the cell. This highly homologous domains present in multiple copies in a number of species, exhibit individual and specific functional specificity. Number of NMR and X-ray crystallographic structural studies reveals that such domains take a common alpha-beta-beta-beta-alpha tertiary fold. However, the functional specificities of these domains could be due to the dynamics of the individual amino acid residues, as has been shown earlier in the case of backbone dynamics of 15N-1H of dsRNA binding motifs (dsRBMs) of human protein kinase R (PKR) (Nanduri S, Rahman F, Williams BRG, Qin J. EMBO J 2000;19:5567-5574). To further investigate if the differences in dynamics of the two dsRBMs are restricted to only backbone, or if the side-chain motions are also different to the extent of influencing their packing of the two hydrophobic cores, we have investigated the methyl group dynamics using 13C-methyl relaxation measurements. The results show that the hydrophobic core of dsRBM1 is more tightly packed than dsRBM2, and it seems to undergo less fast scale motions in the subnanosecond regime.

Incoming nucleotide binds to Klenow ternary complex leading to stable physical sequestration of preceding dNTP on DNA.

Klenow-DNA complex is known to undergo a rate-limiting, protein conformational transition from an 'open' to 'closed' state, upon binding of the 'correct' dNTP at the active site. In the 'closed' state, Mg(2+) mediates a rapid chemical step involving nucleophilic displacement of pyrophosphate by the 3' hydroxyl of the primer terminus. The enzyme returns to the 'open' state upon the release of PPi and translocation permits the next round of reaction. To determine whether Klenow can translocate to the next site on the addition of the next dNTP, without the preceding chemical step, we studied the ternary complex (Klenow-DNA-dNTP) in the absence of Mg(2+). While the ternary complex is proficient in chemical addition of dNTPs in Mg(2+), as revealed by primer extensions, the same in Mg(2+)-deficient conditions lead to non-covalent (physical) sequestration of first two 'correct' dNTPs in the ternary complex. Moreover, the second dNTP traps the first one in the DNA-helix of the ternary complex. Such a dNTP-DNA complex is found to be stable even after the dissociation of KLENOW: This reveals the novel state of the dNTP-DNA complex where the complementary base is stacked in a DNA-helix non-covalently, without the phosphodiester linkage. Further, shuttling of the DNA between the polymerase and the exonuclease site mediates the release of such a DNA complex. Interestingly, Klenow in such a Mg(2+)-deficient ternary complex exhibits a 'closed' conformation.

Fold-back structures at the distal end influence DNA slippage at the proximal end during mononucleotide repeat expansions.

Polymerase slippage during DNA synthesis by the Klenow fragment of DNA polymerase across A, C, G and T repeats (30 bases) has been studied. Within minutes, duplexes that contain only repeats (30 bp) expand dramatically to several hundred base pairs long. Rate comparisons in a repeat duplex when one strand was expanded as against that when both strands were expanded suggest a model of migrating hairpin loops which in the latter case coalesce into a duplex. Moreover, slippage (at the proximal or 3'-end) is subject to positive and negative effects from the 5'-end (distal) of the same strand. Growing T and G strands generate T.A:T and G-G:C motif fold-back structures at the distal end that hamper slippage at the proximal end. On the other hand, growing tails at the distal end upon annealing with excess complementary template accentuates proximal slippage several-fold.

Structural basis for uracil DNA glycosylase interaction with uracil: NMR study.

Two dimensional (2D) NMR and molecular dynamics simulations have been used to determine the three dimensional (3D) structure of a hairpin DNA, d-CTA-GAGGATCC-TUTT-GGATCCT (22mer; abbreviated as U2-hairpin), which has uracil at the second position from the 5' end of the tetraloop. The(1)H resonances of this hairpin have been assigned almost completely. NMR restrained molecular dynamics and energy minimization procedures have been used to describe the 3D structure of U2-hairpin. This study establishes that the stem of the hairpin adopts a right-handed B-DNA conformation, while the T(12)and T(15)nucleotides stack upon 3' and 5' ends of the stem, respectively. Further, T(14)stacks upon both T(12)and T(15). Though U(13)partially stacks upon T(14), no stacking interaction is observed between U(13)and T(12). All the individual nucleotide bases belonging to the stem and T(12)and T(15)of the loop adopt ' anti ' conformation with respect to their sugar moiety, while the U(13)and T(14)of the loop are in ' syn ' conformation. The turning phosphate in the loop is located between T(13)and T(14). This study and a concurrent NMR structural study on yet another hairpin DNA d-CTAGAGGAATAA-TTTU-GGATCCT (22mer; abbreviated as U4-hairpin), with uracil at the fourth position from the 5' end of the tetraloop throw light upon various interactions which have been reported between Escherichia coli uracil DNA glycosylase (UDG) and uracil containing DNA. The epsilon of T(12)and alpha, beta, gamma, epsilon and zeta of U(13)and gamma of T(14), which partially influence the local conformation of U(13)in U2-hairpin are all locked in ' trans ' conformation. Such stretched out backbone conformation in the vicinity of U(13)could be the reason as to why the U2-hairpin is found to be the poor substrate for its interaction with UDG compared to the other substrates in which the uracil is at first, third and fourth positions of the tetraloop from its 5' end, as reported earlier by Vinay and Varshney. This study shows that UDG actively promotes the flipping of uracil from a stacked conformation and rules out the possibility of UDG recognizing the flipped out uracil bases.

Structural characterisation of a uracil containing hairpin DNA by NMR and molecular dynamics.

Three-dimensional (3D) structure of a hairpin DNA d-CTAGAGGATCCTTTUGGATCCT (22mer; abbreviated as U4-hairpin), which has a uracil nucleotide unit at the fourth position from the 5' end of the tetra-loop has been solved by NMR spectroscopy. The(1)H resonances of this hairpin have been assigned almost completely. NMR restrained molecular dynamics and energy minimisation procedures have been used to describe the 3D structure of the U4 hairpin. This study establishes that the stem of the hairpin adopts a right handed B-DNA conformation while the T(12)and U(15)nucleotide stack upon 3' and 5' ends of the stem, respectively. Further, T(14)stacks upon both T(12)and U(15)while T(13)partially stacks upon T(14). Very weak stacking interaction is observed between T(13)and T(12). All the individual nucleotide bases adopt ' anti ' conformation with respect to their sugar moiety. The turning phosphate in the loop is located between T(13)and T(14). The stereochemistry of U(15)mimics the situation where uracil would stack in a B-DNA conformation. This could be the reason as to why the U4-hairpin is found to be the best substrate for its interaction with uracil DNA glycosylase (UDG) compared to the other substrates in which the uracil is at the first, second and third positions of the tetra-loop from its 5' end, as reported previously.

Analysis of intrasugar interproton NOESY cross-peaks as an aid to determine sugar geometries in DNA fragments.

A systematic analysis of the conformation of deoxyribofuranose rings in DNA fragments has been described using two-dimensional nuclear Overhauser effect spectroscopy (2D NOESY). The approach is based on the interpretation of the intrasugar proton-proton distances which can be estimated using a low-mixing-time pure-absorption mode w1-scaled NOESY spectrum. The experimental distances are compared with the theoretical values calculated as a function of pseudorotation phase angle (P) describing the sugar geometries. The approach can be used as a complementary aid to J couplings for establishing sugar conformations in individual nucleotide units of DNA fragments. Using this strategy on d-ACATCGATGT, we observed that individual nucleotides exhibit O4'-endo sugar pucker. The results rule out possibilities of the existence of a fast equilibrium (on the NMR time scale) between C2'-endo (or S-domain) and C3'-endo (or N-domain) sugar puckers.

Secondary structure of a calcium binding protein (CaBP) from Entamoeba histolytica.

A calcium binding protein from Entamoeba histolytica, (EhCaBP, M(r) approximately 15 kDa) is the causative agent for amoebiosis and has a very low sequence homology (approximately 30%) with other known CaBPs. Almost complete sequence specific resonance assignments for (1)H, (13)C and (15)N spins in EhCaBP were obtained using double and triple resonance NMR experiments. Qualitative interpretation of the nuclear Overhauser enhancements, chemical shift indices and of hydrogen exchange rates threw valuable light upon the secondary structure of this protein. CaBP is found to have two globular domains each of which consists of two pairs of helix-loop-helix motifs. Though this protein has a very small sequence homology with calmodulins, the topological arrangement of the alpha-helices and beta-strands in EhCaBP resemble them.

Solution structure of d-GAATTCGAATTC by 2D NMR. A new approach to determination of sugar geometries in DNA segments.

A new approach based on the correlated spectroscopy (COSY) in 2D NMR has been described for determination of sugar geometries in oligonucleotides. Under the usual low resolution conditions employed in COSY, the intensities of cross peaks depend on the magnitudes of coupling constants. There are five vicinal coupling constants in a deoxyribose ring which are sensitive to the sugar geometry. The presence, absence and rough comparison of relative intensities of COSY cross peaks arising from such coupling constants enable one to fix the sugar conformation to a fair degree of precision. The methodology has been applied to d-GAATTCGAATTC. It is observed that ten out of the twelve nucleotide units in this sequence exhibit a rare O1'-endo geometry. The EcoRI cleavage sites (between G and A) in the dodecanucleotide show an interesting variation in the conformation with the two sugars attached to the Gs acquiring a geometry between C2'-endo and C4'-endo.

Evidence for A+(anti)-G(syn) mismatched base-pairing in d-GGTAAGCGTACC.

Two-dimensional NMR spectroscopy has been used to study the structure and hydrogen bonding scheme of A:G mismatched base pairing in d-GGTAAGCGTACC at pH 5.8. Under the conditions of our study, the molecule forms a B-DNA helix, with the mismatched bases in the A+ anti)-G(syn) conformation. The adenosine exists in the protonated form. The NOESY spectrum in 90% H2O + 10% 2H2O has been used to assign all observable imino and amino protons including those involved in the A+(anti)-G(syn) base pair. Both the proton donors in the A:G mismatched inter-base hydrogen bonding are situated on adenosine.

Molecular mechanics calculations on a triple stranded DNA involving C+.G-T and T.A+-C mismatched base triples.

We have carried out molecular modeling of a triple stranded pyrimidine(Y). purine(R): pyrimidine(Y) (where ':' refers to Watson-Crick and '.' to Hoogsteen bonding) DNA, formed by a homopurine (d-TGAGGAAAGAAGGT) and homo-pyrimidine (d-CTCCTTTCTTCC). Molecular mechanics calculations using NMR constraints have provided a detailed three dimensional structure of the triplex. The entire stretches of purine and the pyrimidine nucleotides have a conformation close to B-DNA. The three strands are held by the canonical C+.G:C and T.A:T hydrogen bonds. The structure also contains two mismatch C+.G-T and T.A+-C base triples which have been characterized for the first time. In the A+-C base-pair of the T.A+-C triple, both hydrogen donors are situated on the purine (A+(1N) and A+(6N)). We observe a unique hydrogen bonding interaction scheme in case of C+.G-T where one acceptor, G(60), is bonded to three donors (C+(3NH), C+(4NH2) and T(3NH)). Though the C+.G-T base triple is less stable than C+.G:C, it is significantly more stable than T.A:T. On the other hand, T.A+-C is as stable as the T.A:T base triad.

NMR structural characterisation of a hairpin DNA with two-base loop: solution conformation of d-GGTACIAGTACC.

An inosine-adenosine mismatched base-pair oligonucleotide, d-GGTACIAGTACC has been studied by 1H and 31P NMR spectroscopy. Almost complete 1H and 31P resonance assignments of the oligomer at 0.90 mM concentration and 310 K have been achieved. NMR results demonstrate that the oligomer adopts a hairpin conformation, which has a structure with two purines I6 and A7 forming a two-base loop on a B-DNA stem. Stacking is continued on the 5'-side of the loop, with the I6 stacked upon C5. The base A7, on the 3'-side of the loop stacks partially with I6. All the bases are in anti conformation with respect to their respective sugar moiety.

Sequence specific 1H, 13C and 15N resonance assignments of hahellin in 8 M urea.

The sequence specific (1)H, (13)C and (15)N resonance assignments of hahellin in 8 M urea-denatured state have been accomplished by NMR spectroscopy. Secondary chemical shift analysis reveals the native-like propensities for ß-rich conformation in the denatured state.

Resonance assignments of myristoylated and non-myristoylated neuronal calcium sensor-1(NCS-1) embedded in a membrane.

Neuronal Calcium Sensor-1 (NCS-1) is a member of calcium sensor family. It is originally identified as frequenin. NCS-1 has been found to interact with membrane and cytosolic proteins and its physiological role is governed by N-terminal myristoylation. In this paper, we report the NMR assignments of both myristoylated and non-myristoylated NCS-1 in the presence of a membrane.

Sequence specific 1H, 13C and 15N backbone resonance assignments of UVI31+ from Chlamydomonas reinhardtii.

The cDNA of UVI31+ was cloned from C. reinhardtii and expressed in E. coli from where the protein was purified to homogeneity. The purified protein exhibited beta-lactamase activity (Manuscript in preparation). However, UVI31+ has no homology with the known ß-lactamases. In order to understand the structural basis of the ability of UVI31+ to hydrolyze ß-lactam antibiotics, we in parallel, set out to structurally characterize it by NMR. Its ß-lactamase activity in relation to the solution structure by NMR is likely to provoke deeper understanding of its mechanism and facilitate the rationalization of other functions of the protein, if any. In this endeavor, we report almost complete sequence-specific backbone (1)H, (13)C and (15)N NMR assignments of UVI31+.

Sequence specific 1H, 13C, and 15N resonance assignments of Hahellin from Hahella chejuensis, a putative member of the betagamma-crystallin superfamily.

The sequence specific (1)H, (13)C, and (15)N resonance assignments of Hahellin, a putative member of betagamma-crystallin family, from Hahella Chejuensis, have been accomplished by NMR spectroscopy. The resonance assignments reveal that the protein adopts predominantly a beta-sheet conformation as in the case of betagamma-crystallin folds.