To study the effects of phosphorylation by glycogen synthase kinase-3beta (GSK-3beta) on the ability of the microtubule-associated protein tau to promote microtubule self-assembly, tau isoform 1 (foetal tau) and three mutant forms of this tau isoform were investigated. The three mutant forms of tau had the following serine residues, known to be phosphorylated by GSK-3, replaced with alanine residues so as to preclude their phosphorylation: (1) Ser-199 and Ser-202 (Ser-199/202-->Ala), (2) Ser-235 (Ser-235-->Ala) and (3) Ser-396 and Ser-404 (Ser-396/404-->Ala). Wild-type tau and the mutant forms of tau were phosphorylated with GSK-3beta, and their ability to promote microtubule self-assembly was compared with the corresponding non-phosphorylated tau species. In the non-phosphorylated form, wild-type tau and all of the mutants affected the mean microtubule length and number concentrations of assembled microtubules in a manner consistant with enhanced microtubule nucleation. Phosphorylation of these tau species with GSK-3beta consistently reduced the ability of a given tau species to promote microtubule self-assembly, although the affinity of the tau for the microtubules was not greatly affected by phosphorylation since the tau species remained largely associated with the microtubules. This suggests that the regulation of microtubule assembly can be controlled by phosphorylation of tau at sites accessible to GSK-3beta by a mechanism that does not necessarily involve the dissociation of tau from the microtubules.
The effects of the tubulin-colchicine complex (Tu-Col) on the dynamic behavior of microtubules have been examined under steady-state conditions in vitro. The addition of Tu-Col to tubulin microtubules at steady state results in only partial microtubule disassembly. Nevertheless, both the rate and the extent of tubulin exchange into microtubules are markedly suppressed by concentrations of Tu-Col which are low relative to the total amount of free tubulin. In addition, the time-dependent changes in microtubule length distribution, characteristic of dynamic instability, are suppressed by the addition of Tu-Col. Examination by video-enhanced dark-field microscopy of individual microtubules in the presence of Tu-Col shows that the principal effect of this complex is to reduce the growth rate at both ends of the microtubule. We have used computer simulation to rationalize the action of Tu-Col in terms of its effects on the experimentally observable parameters, namely, the rates of growth and shortening and the mean lifetimes of growth and shortening, which provide an empirical description of the dynamic behavior of microtubules. The results have been interpreted within the framework of the lateral cap formulation for microtubule dynamic instability [Martin, S. R., Schilstra, M. J., & Bayley, P. M. (1993) Biophys. J. 65, 578-596]. The simplest model mechanism requires only that Tu-Col binds to the microtubule end and inhibits further addition reactions in either the 5-start or the 8-start direction of the microtubule lattice. Monte Carlo simulations show that Tu-Col can, in this way, cause major suppression of the dynamic transitions of microtubules without inducing bulk microtubule disassembly. This type of mechanism could be important for the regulation of microtubule dynamics in vivo.
The regulation of microtubule dynamics in vitro by microtubule-associated proteins (MAPs) was examined, using purified porcine MAP1B and MAP2. MAP1B has a significantly smaller effect on the observed critical concentration for microtubule assembly than MAP2. Assembly is faster in the presence of either MAP, and the resulting microtubules are shorter, indicating that nucleation is substantially promoted by the MAPs. Both MAPs stabilise the microtubule lattice as observed from podophyllotoxin-induced disassembly, but the effect of MAP1B is weaker than the effect of MAP2. At steady-state of assembly MAP1B still allows microtubule dynamic instability to occur as inferred from microtubule length changes. The comparison of the effects of MAP1B and MAP2 indicates that the reduction of the observed critical concentration is attributable to the reduction of the depolymerisation rate and correlates with the extent of suppression of dynamic instability. Numerical simulations illustrate that microtubule dynamics are strongly influenced by relatively small changes in the strength of a limited subset of subunit interactions in the lattice. The observed characteristic differences between the MAPs may be important for the regulation of distinct populations of microtubules which coexist in the same cell, where differences in stability and dynamics may be essential for their different spatial roles as, for example, in developing neurons.
The effects of free drug and tubulin-drug complexes on steadystate GTP\GDP-associated microtubules and on equilibrium guanosine 5h-[ β,γ-imido]triphosphate-associated microtubules are compared. The addition of colchicine or the tubulincolchicine complex (TuCol) to steady-state microtubules induces microtubule disassembly. Only limited disassembly of equilibrium microtubules is observed under similar conditions. Addition of colchicine or the bifunctional colchicine analogue 2-methoxy-5-(2h,3h,4h-trimethoxyphenyl)tropone to preassembled steadystate or equilibrium microtubules does induce disassembly, but establishment of the new steady state or equilibrium is very slow. These observations are related to the fact that TuCol readily adds to the microtubule end, but is only incorporated into the lattice with difficulty. As a result, microtubule growth is effectively inhibited and the critical concentration is significantly increased.
The molecular mechanism underlying microtubule dynamic instability depends on the relationship between the addition of tubulin-GTP to a growing microtubule and its hydrolysis in the microtubule lattice to tubulin-GDP, with release of inorganic phosphate (Pi). Since this relationship remains controversial, we have re-examined the release of Pi upon microtubule assembly using a fluorometric assay for Pi, based on the phosphate-binding protein of Escherichia coli [Brune M., Hunter, J. L., Corrie, J. E. T., and Webb, M. R. (1994) Biochemistry 33, 8262-8271]. Microtubule assembly and Pi release were monitored simultaneously in a standard fluorimeter as an increase in the turbidity and fluorescence, respectively, in tubulin-GTP solutions assembled under conditions supporting dynamic instability. At the steady state of assembly, Pi release is nonlinear with respect to time, proceeding at a rate determined by the following: (a) the intrinsic GTPase activity of the nonpolymerized tubulin-GTP, and (b) the microtubule number concentration, which decreases progressively. Direct observation of the time course of nucleated microtubule assembly indicates that Pi release is closely coupled to microtubule elongation, even during the initial stages of assembly when uncoupling of tubulin-GTP addition and GTP hydrolysis would be most evident. Studies of the inhibition and reversal of the growth phase by cytostatic drugs show no evidence of a burst of Pi release. We conclude that nucleotide hydrolysis can keep pace with tubulin-GTP addition rates of 200 molecules per second per microtubule and that extended caps of tubulin-GTP or tubulin-GDP-Pi are not generated in normal assembly, nor are they required to stabilize growing microtubules or to support the phenomenon of dynamic instability of microtubules at the steady state.
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