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The x-ray structure of chicken skeletal muscle troponin C (TnC), the Ca2+-binding subunit of the troponin complex, shows that the protein is about 70 angstroms long with an unusual dumbbell shape. The carboxyl and amino domains are separated by a single long alpha helix of about nine turns. Only the two high-affinity Ca2+-Mg2+ sites of the COOH-domain are occupied by metal ions resulting in conformational differences between the COOH- and NH2-domains. These differences are probably important in the triggering of muscle contraction by TnC. Also the structure of TnC is relevant in understanding the function of other calcium-regulated proteins, in particular that of calmodulin because of its strong similarity in amino acid sequence.

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Exact method for the calculation of pseudorotation parametersP, τ_mand their errors. A comparison of the Altona–Sundaralingam and Cremer–Pople treatment of puckering of five-membered rings

Rao¹,

Westhof²,

1981

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Stereochemistry of nucleic acids and their constituents. X. solid‐slate base‐slacking patterns in nucleic acid constituents and polynucleotides

et al. 1971

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SynopsisThe base-stacking patterns in over 70 published crystal structures of nucleic acid constituents and polynucleotides were examined. Several recurring stacking patterns were found. Base stacking in the solid state apparently is very specific, with particular modes of interaction persisting in various crystalline environments. The vertical stacking of purines and pyrimidines in polynucleotides is similar to that observed in crystals of tiucleic acid constituents. Only partial base overlap was found in the majority of the structures examined. Usually, the base overlap is accomplished by positioning polar substituents over the ring system of an adjacent base. The stacking interactions are similar to those found in the crystal structures of other polar aromatic compounds, but are considerably different from the ring-ring interactions in nonpolar aromatic compounds. Apparently, dipole-induced dipole forces are largely responsible for solid-state base stacking. It is found that halogen substituents affect, base-stacking patterns. In general, the presence of a halogen substituent results in a stacking pattern which permits intimate contact between the halogen atom and adjacerit purine or pyrimidine rings. Considering differences in the stacking patterns found for halogenated and nonhalogenated pyrimidines, a niodel is proposed to account for the mutagenic effects of halogenated pyrimidineo.

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Structure of the oxidized long‐chain flavodoxin from anabaena 7120 at 2 å resolution

et al. 1992

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The structure of the long-chain flavodoxin from the photosynthetic cyanobacterium Anabaena 7120 has been determined at 2 A resolution by the molecular replacement method using the atomic coordinates of the long-chain flavodoxin from Anacystis nidulans. The structure of a third long-chain flavodoxin from Chondrus crispus has recently been reported. Crystals of oxidized A . 7120 flavodoxin belong to the monoclinic space group P2, with a = 48.0, b = 32.0, c = 51.6A, and 0 = 92", and one molecule in the asymmetric unit. The 2 A intensity data were collected with oscillation films at the CHESS synchrotron source and processed to yield 9,795 independent intensities with Rmerg of 0.07. Of these, 8,493 reflections had I > 2a and were used in the analysis. The model obtained by molecular replacement was initially refined by simulated annealing using the XPLOR program. Repeated refitting into omit maps and several rounds of conjugate gradient refinement led to an R-value of 0.185 for a model containing atoms for protein residues 2-169, flavin mononucleotide (FMN), and 104 solvent molecules. The FMN shows many interactions with the protein with the isoalloxazine ring, ribityl sugar, and the 5'-phosphate. The flavin ring has its pyrimidine end buried into the protein, and the functional dimethyl benzene edge is accessible to solvent. The FMN interactions in all three long-chain structures are similar except for the 04' of the ribityl chain, which interacts with the hydroxyl group of Thr 88 side chain in A. 7120, while with a water molecule in the other two. The phosphate group interacts with the atoms of the 9-15 loop as well as with NE1 of Trp 57. The N5 atom of flavin interacts with the amide NH of Ile 59 in A . 7120, whereas in A . nidulans it interacts with the amide NH of Val 59 in a similar manner. In C. crispus flavodoxin, N5 forms a hydrogen bond with the side chain hydroxyl group of the equivalent Thr 58. The hydrogen bond distances to the backbone NH groups in the first two flavodoxins are 3.6 A and 3.5 A , respectively, whereas in the third flavodoxin the distance is 3.1 A , close to the normal value. Even though the hydrogen bond distances are long in the first two cases, still they might have significant energy because their microenvironment in the protein is not accessible to solvent. In all three long-chain flavodoxins, a water molecule bridges the ends of the inserted loop in the os strand and minimally perturbs its hydrogen bonding with p4. Many of the water molecules in these proteins interact with the flavin binding loops. The conserved &core of the three long-chain and two short-chain flavodoxins superpose with root mean square deviations ranging from 0.48 A to 0.97 A .

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Refined structure of chicken skeletal muscle troponin C in the two-calcium state at 2-A resolution.

Satyshur

Rao

Pyżalska

et al. 1988

Journal of Biological Chemistry

273

111

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Structure of chicken skeletal muscle troponin C at 1.78 Å resolution

Satyshur

Pyżalska²,

Greaser³

et al. 1994

Acta Cryst D

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The structure of chicken skeletal muscle troponin C (TnC) has been refined to an R value of 0.168, using 14 788 reflections, in the resolution range 8.0-1.78 .~,. Our earlier 2 ,A, resolution structure [Satyshur, Rao, Pyzalska, Drendel, Greaser & Sundaralingam (1988).J. Biol. Chem. 263, 1628-1647 served as the starting model. The refined model includes atoms for all protein residues (1-162), 2 Ca 2+ ions, 169 water molecules and one sulfate ion. The high-resolution refinement shows more clearly the details of the protein and water structure. The side chains Glu63, Cysl01, Arg123, Aspl40 and Asp152 adopt two discretely ordered conformations. The long central helix is only slightly curved/bent (7.9 ° ) and all the central helix NH-.-O--C hydrogen bonds are intact. Seven of the nine carbonyl O atoms of the mid segment of this helix, including the D/E linker region, are hydrogen bonded to water molecules which weakens the helix hydrogen bonds. In contrast, in each of the protected upper and lower thirds of the long central helix, only two carbonyl O atoms are hydrogen bonded to water molecules. The hydrogen-bonding patterns displayed by some of the carbonyl O atoms of NT and A helices of the N-terminal domain and the F and H helices of the C-terminal domain, which are on the exposed surface of the protein, are similar. The B helix of the calcium-free site I is kinked, with the local helix axes at either end making an angle of 39 ° , by two inserted water molecules between N--H and O--C groups, breaking the adjacent helix hydrogen bonds. A sul-

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Structure of Paramecium tetraurelia calmodulin at 1.8 Å resolution

Rao

Satyshur

et al. 1993

Protein Science

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The crystal structure of calmodulin (CaM; M, 16,700, 148 residues) from the ciliated protozoan Paramecium tetraurelia (PCaM) has been determined and refined using 1.8 A resolution area detector data. The crystals are regions differ, where the B-factors are also high, particularly in PCaM and MCaM. Unlike the MCaM structure, with one kink at D80 in the middle of the linker region, and the DCaM structure, with two kinks at K75 and 185, in our PCaM structure there are no kinks in the helix; the distortion appears to be more gradually distributed over the entire helical region, which is bent with an apparent radius of curvature of 74.5(2) A. The different distortions in the central helical region probably arise from its inherent mobility.

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S.T. Rao

Comparison of super-secondary structures in proteins

Molecular Structure of Troponin C from Chicken Skeletal Muscle at 3-Angstrom Resolution

Exact method for the calculation of pseudorotation parametersP, τ_mand their errors. A comparison of the Altona–Sundaralingam and Cremer–Pople treatment of puckering of five-membered rings

Stereochemistry of nucleic acids and their constituents. X. solid‐slate base‐slacking patterns in nucleic acid constituents and polynucleotides

Structure of the oxidized long‐chain flavodoxin from anabaena 7120 at 2 å resolution

Refined structure of chicken skeletal muscle troponin C in the two-calcium state at 2-A resolution.

Structure of chicken skeletal muscle troponin C at 1.78 Å resolution

Structure of Paramecium tetraurelia calmodulin at 1.8 Å resolution

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S.T. Rao

Comparison of super-secondary structures in proteins

Molecular Structure of Troponin C from Chicken Skeletal Muscle at 3-Angstrom Resolution

Exact method for the calculation of pseudorotation parametersP, τmand their errors. A comparison of the Altona–Sundaralingam and Cremer–Pople treatment of puckering of five-membered rings

Stereochemistry of nucleic acids and their constituents. X. solid‐slate base‐slacking patterns in nucleic acid constituents and polynucleotides

Structure of the oxidized long‐chain flavodoxin from anabaena 7120 at 2 å resolution

Refined structure of chicken skeletal muscle troponin C in the two-calcium state at 2-A resolution.

Structure of chicken skeletal muscle troponin C at 1.78 Å resolution

Structure of Paramecium tetraurelia calmodulin at 1.8 Å resolution

Contact Info

Product

Resources

About

Exact method for the calculation of pseudorotation parametersP, τ_mand their errors. A comparison of the Altona–Sundaralingam and Cremer–Pople treatment of puckering of five-membered rings