Antigenic validation of recombinant hemagglutinin-neuraminidase protein of Newcastle disease virus expressed in Saccharomyces cerevisiae.

The outer membrane glycoprotein, hemagglutinin-neuraminidase (HN) of Newcastle disease virus (NDV) is important for virus infection and subsequent immune response by host, and offers target for development of recombinant antigen-based immunoassays and subunit vaccines. In this study, the expression of HN protein of NDV is attempted in yeast expression system. Yeast offers eukaryotic environment for protein processing and posttranslational modifications like glycosylation, in addition to higher growth rate and easy genetic manipulation. Saccharomyces cerevisiae was found to be better expression system for HN protein than Pichia pastoris as determined by codon usage analysis. The complete coding  sequence of HN gene was amplified with the histidine tag, cloned in pESC-URA under GAL10 promotor and transformed in Saccharomyces cerevisiae. The recombinant HN (rHN) protein was characterized by western blot, showing glycosylation heterogeneity as observed with other eukaryotic expression systems. The recombinant protein was purified by affinity column purification. The protein could be further used as subunit vaccine.

Effect of urea denaturation on tryptophan fluorescence and nucleotide binding on tubulin studied by fluorescence and NMR spectroscopic methods.

Tubulin, the major protein of microtubules, has been shown to be an example of protein undergoing multistep unfolding. Local unfolding and stepwise loss of a number of characteristic functions were demonstrated. In order to understand urea induced effects on tryptophan fluorescence and nucleotide binding on tubulin, both fluorescence and NMR techniques were used. Tubulin was denatured by different urea concentrations. The present experiments were carried out at concentrations of tubulin (to approximately 10 microM) at which most of the protein will be in the dimeric state. Quenching studies in the presence of KI suggest that all the tryptophans are fairly solvent exposed. Similar studies using acrylamide as quencher, suggest unfolding of tubulin at these protein concentrations to be an apparent two state process between the native and the completely unfolded states unlike at low concentrations where a partially folded intermediate was observed. No observable effects of the nucleotide or the metal ion on tryptophan fluorescence were observed. An attempt was made using NMR to monitor the changes in the nucleotide interaction with tubulin as the protein is unfolded by urea denaturation. No significant effects were observed in the binding of the nucleotide to tubulin by urea denaturation.

Time-resolved fluorescence of tryptophans in yeast hexokinase-PI: effect of subunit dimerization and ligand binding.

Time-resolved and steady-state fluorescence measurements have been performed on monomeric and dimeric forms of yeast hexokinase-PI. Observation of similar emission spectra and fluorescence decay parameters for both the forms of the enzyme suggests that tryptophan residue(s) are not likely to be present at the subunit-subunit interface and the process of dimerization does not perturb the local environment of tryptophan(s). The fluorescence decay of tryptophans in enzyme could be fitted to a bi-exponential function with two lifetime components, tau1 approximately 2.2 ns and tau2 approximately 3.9 ns. Binding of glucose, which is known to convert the 'open' conformation of the enzyme to a 'closed' active conformation, results in approximately 30% reduction in emission intensity and a selective decrease in tau1 from approximately 2.2 to approximately 1.1 ns. These effects can be reversed by the addition of trehalose 6-phosphate (an inhibitor of yeast hexokinase), suggesting that the trehalose 6-phosphate inhibits the enzyme by binding to its 'open' inactive conformation rather than competing with glucose to bind to the 'closed' active conformation. Binding of nucleotide ligands (ATP, ADP and adenyl-(beta,gamma-methylene)-diphosphate (AMPPCP)) to the monomeric or dimeric form of enzyme quenched the steady-state fluorescence by approximately 4-8%, but had no measurable effect on the distribution of lifetimes or on their magnitudes. Addition of nucleotides to the enzyme-glucose complex also did not produce any further change in fluorescence decay parameters. These results indicate that it is highly unlikely that the formation of a ternary enzyme-glucose-nucleotide complex from the binary enzyme-glucose complex is accompanied by a large conformational change in the enzyme, as has been surmised in some earlier studies.

Effect of glucose on the conformation of ADPMg(II) bound at the active site of yeast hexokinase PI.

The conformation of ADPMg(II) bound at the active site of yeast hexokinase PI has been determined using transferred nuclear Overhauser effect spectroscopy (TRNOESY). We have measured the time dependent NOE buildup of all the proton pairs of ADP in enzyme. ADPMg(II) and enzyme. glucose.ADPMg(II) complexes at 500 MHz and 10 degrees C. The data have been analyzed using complete relaxation matrix approach to obtain various inter-proton distances. These distances were used as restraints in the molecular dynamics and energy minimization to obtain the conformation of the bound nucleotide. The results from these calculations suggest that in both the complexes, the nucleotide binds in an anti conformation with a glycosidic torsion angle chi = 55 +/- 5 degrees and 52 +/- 5 degrees in PI.ADPMg(II) and PI.glucose.ADPMg(II) complexes, respectively. However, the phase angle of pseudorotation (P) which defines the sugar pucker in the two complexes was found to be 99 degrees, corresponding to 0T1 for PI.ADPMg(II) complex and 69 degrees corresponding to 4T0 for PI.glucose.ADPMg(II) complex. The cleft closure conformational change in the enzyme induced by glucose seems to affect the conformation of the ribosyl moiety of the bound nucleotide.

Interaction of bis(1-anilino-8-naphthalenesulfonate) with yeast hexokinase: a steady-state fluorescence study.

Bis(1-analino-8-naphthalenesulfonate) (bis-ANS) is a useful probe for hydrophobic areas on protein molecules and it has been proposed that it has a general affinity for the nucleotide binding site(s). There appear to be two different classes of binding sites for bis-ANS on hexokinase and these can be tentatively assigned as primary and secondary binding sites. The rate of binding of bis-ANS at the primary binding site is fast, whereas binding at secondary site(s) is slow. The slow increase in the fluorescence intensity on binding with bis-ANS is not due to conformational change in the enzyme, which may lead to the increase in the quantum yield of the bound dye. Circular dichroism measurements indicate that there is no significant change in the secondary structure on binding with this probe. In the presence of saturating amounts of glucose, the increase in fluorescence intensity due to binding at the secondary binding site(s) is significantly lowered. This indicates that glucose-induced conformational change has been sensed by this probe. From kinetic studies, it has been observed that bis-ANS is an effective competitive inhibitor of yeast hexokinase with respect to ATP. The stoichiometry of binding of this fluorescent probe is about one per subunit at the primary site both in the presence and absence of glucose, and the dissociation constant of bis-ANS is unaffected by glucose. It is possible to decrease significantly the amount of fluorescence intensity at the primary site by nucleotides. These results indicate that bis-ANS interacts at the site where nucleotide interacts. Energy transfer experiments indicate the proximity of some tryptophan(s) and bound bis-ANS molecule(s).

Yeast hexokinase PII--bound nucleotide conformation at the active site.

The structure of adenine nucleotide bound at the active site of yeast hexokinase PII (PII) was studied in the complexes PII x ADPMg(II), PII x ADPMg(II) x Glc and PII x ADPMg(II) x NO3- x Glc using two-dimensional transferred NOE spectroscopy. Binding of the nucleotide ligand to the enzyme resulted in downfield shift of several ligand resonances. Changes in the chemical shift as a function of ligand concentration indicate that various resonances in the bound and free form of the ligand appear to be in fast exchange. The largest chemical shift change between the bound and the free states (delta vM = 88 +/- 9 Hz) at an NMR frequency of 500 MHz was observed for the H2 resonance of the adenine ring. A lower limit for the rate of ligand dissociation from the complex derived from these results is k(off) >> 550 s(-1). Interproton NOEs for various ligand protons in PII x ADPMg(II), PII x ADPMg(II) x Glc and PII x ADPMg(II) x NO3- x Glc complexes were measured at 500 MHz at 10 degrees C. The NOE buildup curves constructed from such measurements made at various mixing times (40, 80, 120, 160 and 200 ms) were analyzed using complete relaxation matrix calculations and various interproton distances were determined. These distances were used in restrained molecular dynamics calculations to derive the conformation of the nucleotide bound at the active site of the enzyme. The results of these calculations indicate that the nucleotide binds in an anti conformation. The glycosidic torsion angle chi (O4'-C1'-N9-C8) determined for the nucleotide in PII x ADPMg(II), PII x ADPMg(II) x Glc and PII x ADPMg(II) x NO3- x Glc complexes are 68 +/- 4 degrees, 52 +/- 4 degrees and 49 +/- 4 degrees respectively. In all these complexes, the ribose pucker is best represented by the unsymmetrical O4'-endo-C1'-exo twist ((o)T1). The observed decrease in the glycosidic torsion angle of the bound nucleotide is attributed to the glucose-induced conformational changes in the enzyme. The structure of the nucleotide derived here is at variance from the one proposed on the basis of X-ray crystallography and model building [Shoham, M. & Steitz, T. A. (1980) J. Mol. Biol. 140, 1-14].