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.

Interaction of microtubules with active principles of Xanthium strumarium.

Indigenous variety of Xanthium strumarium (X. strumarium) was screened for its antimitotic activity using the microtubule-tubulin system isolated from mammalian tissue. A preliminary phytochemical screening of the whole extracts of the plant was carried out followed by partial purification of the whole extract of X.strumarium. The separated fractions obtained were identified and used for in vitro polymerization studies. The whole as well as partially separated chemical constituents of X. strumarium showed effective inhibition of tubulin polymerization. The results thus suggest that X. strumarium may possess antimitotic components.

Nucleotide binding to tubulin-investigations by nuclear magnetic resonance spectroscopy.

In an attempt to distinguish between the interaction of GTP and ATP with tubulin dimer, high-resolution 1H- and 31P-NMR experiments have been carried out on the nucleotides in the presence of tubulin. The location of the ATP binding sites on the protein in relation to the GTP sites is still not clear. Using NMR spectroscopy, we have tried to address this question. Evidence for the existence of a site labelled as X-site and another site (labelled as L-site) for both the nucleotides on tubulin has been obtained. It is suggested that this X-site is possibly the putative E-site. In order to gain further insight into the nature of these sites, the Mg(II) at the N-site has been replaced by Mn(II) and the paramagnetic effect of Mn(II) on the linewidth of the proton resonances of tubulin-bound ATP and GTP has been studied. The results show that the L-site nucleotide is closer to the N-site metal ion compared to the X-site nucleotide. On the basis of these results, it is suggested that the L-site of ATP is distinct from the L-site of GTP while the X-site of both the nucleotides seems to be same. By using the paramagnetic effect of the metal ion, Mn(II), at the N-site on the relaxation rates of tubulin-bound ATP at L-site, distances of the protons of the base, sugar and phosphorous nuclei of the phosphorous moiety of ATP, from the N-site metal ion have been mapped. The base protons are approximately equal to 0.8-1 nm from this metal ion site. On the other hand, the phosphorous nuclei of the phosphate groups are somewhat nearer (approximately equal to 0.4-0.5 nm) from the N-site metal ion.