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.

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.

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.

Regulatory and structural EF-hand motifs of neuronal calcium sensor-1: Mg 2+ modulates Ca 2+ binding, Ca 2+ -induced conformational changes, and equilibrium unfolding transitions.

Neuronal calcium sensor-1 (NCS-1) is a major modulator of Ca(2+) signaling with a known role in neurotransmitter release. NCS-1 has one cryptic (EF1) and three functional (EF2, EF3, and EF4) EF-hand motifs. However, it is not known which are the regulatory (Ca(2+)-specific) and structural (Ca(2+)- or Mg(2+)-binding) EF-hand motifs. To understand the specialized functions of NCS-1, identification of the ionic discrimination of the EF-hand sites is important. In this work, we determined the specificity of Ca(2+) binding using NMR and EF-hand mutants. Ca(2+) titration, as monitored by [(15)N,(1)H] heteronuclear single quantum coherence, suggests that Ca(2+) binds to the EF2 and EF3 almost simultaneously, followed by EF4. Our NMR data suggest that Mg(2+) binds to EF2 and EF3, thereby classifying them as structural sites, whereas EF4 is a Ca(2+)-specific or regulatory site. This was further corroborated using an EF2/EF3-disabled mutant, which binds only Ca(2+) and not Mg(2+). Ca(2+) binding induces conformational rearrangements in the protein by reversing Mg(2+)-induced changes in Trp fluorescence and surface hydrophobicity. In a larger physiological perspective, exchanging or replacing Mg(2+) with Ca(2+) reduces the Ca(2+)-binding affinity of NCS-1 from 90 nM to 440 nM, which would be advantageous to the molecule by facilitating reversibility to the Ca(2+)-free state. Although the equilibrium unfolding transitions of apo-NCS-1 and Mg(2+)-bound NCS-1 are similar, the early unfolding transitions of Ca(2+)-bound NCS-1 are partially influenced in the presence of Mg(2+). This study demonstrates the importance of Mg(2+) as a modulator of calcium homeostasis and active-state behavior of NCS-1.

Measurement of 1J(Ni,Calpha(i)), 1J(Ni,C'i-1), 2J(Ni,Calpha(i-1)), 2J(H(N)i,C'i-1) and 2J(H(N)i,Calpha(i)) values in 13C/15N-labeled proteins.

Use of partial or selective (13)C/(15)N labeling of specific amino acid residues in a given protein to measure the values of (1)J((15)N(i),(13)C(alpha) (i)), (2)J((1)H(N),(13)C(alpha) (i)), (2)J((15)N(i),(13)C(alpha) (i-1)), (1)J((15)N(i),(13)C'(i-1)) and (2)J((1)H(N),(13)C'(i-1)) is described. This was achieved by recording a sensitivity-enhanced 2D [(15)N-(1)H] HSQC experiment, without mixing the spin states of C(alpha) and C' during the course of entire experiment.

A novel approach for uniform (13)C and (15)N labeling of DNA for NMR studies.

A novel method is proposed for large-scale synthesis of (13)C- and (15)N-labeled DNA for NMR studies. In this methodology, endonuclease-sensitive repeat amplification (ESRA), a modified PCR strategy, has been used to amplify tandem repeats of the target DNA sequence. The design of the template is such that restriction enzyme (RE) sites separate repeats of the target sequence. The ESRA product is then cloned into a suitable vector. The Escherichia coli cells harboring the plasmid are grown in minimal medium containing [(13)C]glucose and (15)NH(4)Cl as the sole source of carbon and nitrogen, respectively. The target sequence is released by RE digestion of the plasmid, followed by purification using PAGE. Under optimized conditions, the yield ( approximately 5 mg/liter of culture) of (13)C/(15)N-labeled DNA prepared using this approach is found to be several times higher compared to other known enzymatic methods. Successful incorporation of the isotopes has been confirmed using 2D NMR techniques.