The possible chain bendings in polydeoxynucleotides.

Energy minimization studies were carried out on the trimeric subunit of DNA, dApdApdA by treating the thirteen relevant dihedral angles as simultaneous variables in the total energy function. The four important sugar pucker states ³E-³E-³E, ²E-²E-²E, ³E-²E-³E and ²E-³E-²E were investigated. From the characteristic chain diverting properties of the low energy conformations four possible types of bend families were identified and their probable sites of occurrence in the polydeoxynucleotides predicted.     

Enhanced production of fibrinolytic enzyme by a new Xanthomonas oryzae IND3 using low-cost culture medium by response surface methodology

Cardiovascular diseases (CVDs) cause high mortality throughout the world. Existing fibrinolytic agents are highly expensive and have many side effects. Microbial fibrinolytic enzymes are very much considered as novel therapeutic candidate for the treatment of CVDs. Reports on fibrinolytic enzyme from Xanthomonas sp. is lacking. This study reports fibrinolytic enzymes from Xanthomonas oryzae IND3 as it shows hyperactivity on fibrin-agarose plates. This organism utilized various agro-industrial wastes for enzymes production. Among all, cow dung enhanced more enzyme production, hence it was used as the low-cost substrate for statistical optimization of fibrinolytic protease in Solid state fermentation. Response surface methodology was employed to optimize the factors and enhanced yield by 4-fold. The interactions among the variables, viz, sucrose, yeast extract, and pH of the medium were investigated using Central Composite Design (CCD). The predicted fibrinolytic enzyme activity was 2340 U/g, and the observed fibrinolytic enzyme activity was 2294?±?12.8?U/g. The fibrinolytic enzyme degraded blood clot in vitro completely. This study is the first report on statistical optimization of fibrinolytic enzyme production in SSF from Xanthomonas sp. The crude extract has immense activity on proteinaceous wastes. The production of fibrinolytic protease using the low-cost substrate could reduce the production cost of enzyme.     

Studies on the conformation of amino acids. IX. Conformations of butyl, seryl, threonyl, cystennyl, and valyl residues in a dipeptide unit

Potential energies of conformation of a dipeptide unit with butyl, seryl, threonyl, eysteinyl, and valyl side groups have been computed by using classical energy expressions. The presence of a γ-atom introduces characteristic restrictions on the backbone rotational angles ? and ψ the γ-atom itself is restricted to three staggered positions about the C^α—C^β bond. The important results are that a γ-carbon in position I (χ¹ ? 60°) cannot be accommodated in the standard right-and left-handed α-helices, whereas a γ-oxygen or sulfur could easily be accommodated in the right-handed α-helix. Further, a γ-carbon or a heteroatom in position II (χ¹ ? 180°) does not favor a conformation ψ ? 180°, compared to two other positions. The valyl side group significantly reduces the allowed ? and ψ values and energetically prefers a β-conformation compared to right-or left-handed α-helical conformations. The less favorable α-helical conformation is possible only for γ (III, II) combination of the valyl residue. The observed ?, ψ, and χ¹ values of all the amino acid residues in the three protein molecules, lysozyme, myoglobin, and chymotrypsin are compared with the theoretical predictions and the agreement is excellent. The results bring out the important fact that even in large molecules, the conformation of local segments are predominantly governed by the short-range intramolecular interactions.     

Amino acid composition and thermal stability of proteins

This study investigates the relationship between the thermal stability of a globular protein and its amino acid composition. The method deals with the relationship between the amino acid compositions and melting points in a set of proteins by computing single-residue and group correlations. Groups of residues are shown to stabilize or destabilize the molecule against temperature. The stabilizing group consists of polar-charged residues and nonpolar residues possessing high surrounding hydrophobicity. The polar-uncharged residues destabilize the molecule against temperature, serine being the most destabilizing residue. A very high cooperativity exists among the stabilizing nonpolar residues suggesting that their characteristic clustering inside the globule may enhance the thermostability of a protein. In small globular proteins which act as single cooperative units, the melting temperature remains mainly a function of amino acid composition, whereas in complex molecules it depends on other factors also.     

Conformational characteristics of the trinucleoside diphosphate d(ApApA) from energy-minimization studies

Energy-minimization studies were carried out on the trinucleoside diphosphate d(ApApA). The potential energy contributions from nonbonded, electrostatic, hydrogen-bonding, and torsional interactions were minimized by treating the 13 relevant dihedral angles as simultaneous variables. For the C(3′)-endo trimer, 14 low-energy conformations are within 10 kcal/mol above the lowest energy found, compared to only 3 in the case of the C(2′)-endo trimer. This result shows the flexible character of the C(3′)-endo unit. The hairpin-type, loop-promoting conformer with (ω′,ω) = (101°, 59°) was found to be the most favored structure at the 3′-terminus of d(ApApA). The predicted U- and L-type bend conformers were found to lie within 5 kcal/mol, compared to the lowest energy B-DNA structure. The A-DNA and Watson-Crick DNA types of helical conformers also lie within very small energy barriers. The phosphate group at the 5′-end of the nucleotide residue has a definite influence on the base of the corresponding nucleotide, keeping it in the normal anti-region, and hence on the base-stacking property. The results are compared with the presently available experimental data, mainly with the tRNA^Phe crystal.     

Conformational characteristics of dApdA,dApdT, dTpdA,and dTpdT from energy minimization studies

The conformational characteristics of the deoxydinucleoside monophosphates with adenine and thymine bases in all possible sequences, namely, dApdA, dApdT, dTpdA, and dTpdT have been studied using an improved set of energy parameters to calculate the total potential energy and an improved set of energy parameters to calculate the total potential energy and an improved version of the minimization technique to minimize the total energy by allowing all seven dihedral angles of the molecular fragment to vary simultaneously. The results reveal that the most preferred conformation in all these units usually corresponds to one of the four helical conformations, namely, the A-DNA, B-DNA, C-DNA, and Watson-Crick DNA models. These helical conformations differ in energies by about 3 kcal/mol with respect to one another. The conformations which could promote a loop or bend in the backbone are, in general, less stable by about 3.5 kcal/mol with respect to the respective lowest-energy helical conformation. The results indicate that there is a definite influence of bases and their actual sequences on the preferred conformations of the deoxydinucleoside monophosphates. The lowest-energy structure, although corresponding to one of the four helical conformations, differ with the type of the deoxydinucleoside monophosphate. Good or reasonable base stacking is noted in dApdA and dTpdA with both C(3′)-endo and C(2′)-endo sugars and in dApdT and dTpdT with only C(3′)-endo sugar. The inversion of the base sequence in deoxydinucleoside monophosphates alters the order of preference of low-energy conformations as well as the base-stacking property of the unit. The paths linking the starting and final states in the (ω′, ω) plane show interesting features with regard to the energy spread, thus providing insight into the path of conformational movement ofthe molecule under slight perturbation. The stabilities of the A and B forms, including the internal energies of the C(3′)-endo ans C(2′)-endo sugar systems, indicate that for dTpdT the B → A transition is less probable. For dApdA, dApdT, and dTpdA this transition is probable in the same order of preference. We propose that the T-A sequence in the polynucleotide chain might serve as the site accessible for B ? A transitions. The theoretical predictions are in good agreement with the experimental observations.     

Conformational characteristics of the RNA subunit ApA from energy minimization studies

In an attempt to better our understanding of the conformational stabilities in RNAs, an intensive theoraticl study has been carried out on one of its dimeric subunits, ApA, using an improved set of atom-atom interaction energy parameters and an improved version of energy-minimization technique. The C(3′)0endo and the C(2′)-endo sugar ApA units were sperately considered and 38 probable conformations have been analyzed in each case. The total potential energy, comprising nonbonded, electrostatic, and torsional contributions, was minimized by varying all seven relevant dihedral angles simumtaneously. The result reveal that 17 conformations in the case of C(3′)-endo sugar ApA and 7 confomations in the case of C(2′)-endo sugar ApA unit, the lowest energy conformation corresponds to a nonhelical structure and the A-RNA and the Watson-Crick-yype conformations lie at energy levels of about 0.5 and 1.0 Kcal/mo., respectively, above the lowest energy found. For ApA with the lops of different types in the backbone and they all differ in energies by about 3.5 Kcal/mol with refrence to the lowest energy founs. It is noted that the order ofmprefrence of the base stacking is observed in the A-RNA and the Watson-Crick type conformers. The ApA unit with C(2′)-endo sugar is forced to assume phosphodiester conformations with large deviations fom the expected staggered conformations compared to the ApA unit with C(3′)-endo sugar. The result obtained for ApA are discussed with refrence to those previously obtained for the dApdA unit. Te theoretical predictions are compared with the experimental data on the tRNA^Phe crystal, as well as those on fibrous RNAs and RNa subunitlike crystal structures. This study brings out many important aspects of the conformational stability of ApA which have been missed by studies made by others on this system.