Modulation of tubulin-nucleotide interactions by metal ions: comparison of beryllium with magnesium and initial studies with other cations

Cadmium induced inhibition of autophagy is associated with microtubule disruption and mitochondrial dysfunction in primary rat cerebral cortical neurons

Recent studies have reported that mitochondria serve as direct targets for cadmium- (Cd-) induced neuronal toxicity, which can be attenuated by autophagy. The molecular mechanisms' underlying Cd-induced mitochondrial dysfunction and autophagy in neurons are not known. In this study, we studied the upstream signaling pathways induced by Cd-mediated mitochondrial metabolism alterations using primary rat neuron as a model. We found that Cd induced the destruction of microtubules (MTs), and resulted in tau hyper-phosphorylation and decreased acetylated tubulin levels, which were related to a decrease in mitochondrial membrane potential (MMP) and adenosine triphosphate (ATP) levels. As a result of taxol disruption, alterations in macroautophagy, like altered cellular distribution of the autophagy-related protein light chain 3 beta (LC3B) and the expression of Atg5 were found compared with Cd group. We found for the first time that MT disruption induced by Cd reduced the levels of autophagy, leading to mitochondrial dysfunction. These observations suggest new therapeutic strategies aimed to activate or ameliorate pro-survival macroautophagy.

Interplay of calcium and cadmium in mediating cadmium toxicity

The environmentally important toxic metal, cadmium, exists as the Cd(2+) ion in biological systems, and in this state structurally resembles Ca(2+). Thus, although cadmium exerts a broad range of adverse actions on cells by virtue of its propensity to bind to protein thiol groups, it is now well appreciated that Cd(2+) participates in a number of Ca(2+)-dependent pathways, attributable to its actions as a Ca(2+) mimetic, with a central role for calmodulin, and the Ca(2+)/calmodlin-dependent protein kinase II (CaMK-II) that mediates effects on cytoskeletal dynamics and apoptotic cell death. Cadmium interacts with receptors and ion channels on the cell surface, and with the intracellular estrogen receptor where it binds competitively to residues shared by Ca(2+). It increases cytosolic [Ca(2+)] through several mechanisms, but also decreases transcript levels of some Ca(2+)-transporter genes. It initiates mitochondrial apoptotic pathways, and activates calpains, contributing to mitochondria-independent apoptosis. However, the recent discovery of the role CaMK-II plays in Cd(2+)-induced cell death, and subsequent implication of CaMK-II in Cd(2+)-dependent alterations of cytoskeletal dynamics, has opened a new area of mechanistic cadmium toxicology that is a focus of this review. Calmodulin is necessary for induction of apoptosis by several agents, yet induction of apoptosis by Cd(2+) is prevented by CaMK-II block, and Ca(2+)-dependent phosphorylation of CaMK-II has been linked to increased Cd(2+)-dependent apoptosis. Calmodulin antagonism suppresses Cd(2+)-induced phosphorylation of Erk1/2 and the Akt survival pathway. The involvement of CaMK-II in the effects of Cd(2+) on cell morphology, and particularly the actin cytoskeleton, is profound, favouring actin depolymerization, disrupting focal adhesions, and directing phosphorylated FAK into a cellular membrane. CaMK-II is also implicated in effects of Cd(2+) on microtubules and cadherin junctions. A key question for future cadmium research is whether cytoskeletal disruption leads to apoptosis, or rather if apoptosis initiates cytoskeletal disruption in the context of Cd(2+).

Microtubules as a critical target for arsenic toxicity in lung cells in vitro and in vivo

To understand mechanisms for arsenic toxicity in the lung, we examined effects of sodium m-arsenite (As³⁺) on microtubule (MT) assembly in vitro (0-40 µM), in cultured rat lung fibroblasts (RFL6, 0-20 µM for 24 h) and in the rat animal model (intratracheal instillation of 2.02 mg As/kg body weight, once a week for 5 weeks). As³⁺ induced a dose-dependent disassembly of cellular MTs and enhancement of the free tubulin pool, initiating an autoregulation of tubulin synthesis manifest as inhibition of steady-state mRNA levels of βI-tubulin in dosed lung cells and tissues. Spindle MT injuries by As³⁺ were concomitant with chromosomal disorientations. As³⁺ reduced the binding to tubulin of [³H]N-ethylmaleimide (NEM), an -SH group reagent, resulting in inhibition of MT polymerization in vitro with bovine brain tubulins which was abolished by addition of dithiothreitol (DTT) suggesting As³⁺ action upon tubulin through -SH groups. In response to As³⁺, cells elevated cellular thiols such as metallothionein. Taxol, a tubulin polymerization agent, antagonized both As³⁺ and NEM induced MT depolymerization. MT-associated proteins (MAPs) essential for the MT stability were markedly suppressed in As³⁺-treated cells. Thus, tubulin sulfhydryls and MAPs are major molecular targets for As³⁺ damage to the lung triggering MT disassembly cascades.

Laulimalide and paclitaxel: a comparison of their effects on tubulin assembly and their synergistic action when present simultaneously

Previous work has shown that laulimalide, a sponge-derived natural product, resembles paclitaxel in enhancing tubulin assembly and in its effects on cellular microtubules. The two compounds, however, seem to have distinct binding sites on tubulin polymer. Nearly equimolar amounts of tubulin, laulimalide, and paclitaxel are recovered from microtubules formed with both drugs. In the present study, we searched for differences between laulimalide and paclitaxel in their interactions with tubulin polymer. Laulimalide was compared with paclitaxel and epothilone A, a natural product that competes with paclitaxel in binding to microtubules, for assembly properties at different temperatures and for effects of GTP and microtubule-associated proteins on assembly. Although minor differences were observed among the three drugs, their overall effects were highly similar, except that aberrant assembly products were observed more frequently with paclitaxel and that the polymers formed with laulimalide and epothilone A were more stable at 0 degrees C. The most dramatic difference observed between laulimalide and epothilone A was that only laulimalide was able to enhance assembly synergistically with paclitaxel, as would be predicted if the two drugs bound at different sites in polymer. Because stoichiometric amounts of laulimalide and paclitaxel can cause extensive tubulin assembly, maximum synergy was observed at lower temperatures under reaction conditions in which each drug alone is relatively inactive. Laulimalide-induced assembly, like paclitaxel-induced assembly, was inhibited by drugs that inhibit tubulin assembly by binding at either the colchicine- or vinblastine-binding site. When radiolabeled GTP is present in a reaction mixture with either laulimalide or paclitaxel, nucleotide hydrolysis occurs with incorporation of radiolabeled GDP into polymer.

Nickel (Ni2+) enhancement of microtubule assembly in vitro is dependent on GTP function

Microtubule (MT) assembly in vitro is accompanied by hydrolysis of tubulin-bound GTP at E-site. Ni2+, a human carcinogen, has been shown to markedly perturb the MT system in cultured cells and enhance MT assembly in vitro. To further probe the mechanisms of such multiple Ni2+ damaging actions on MT, we have focused on dissecting the role of the Ni2+/GTP interaction in influencing MT assembly in vitro as monitored by a turbidity assay at A350 at 27 degrees C using purified bovine brain MT proteins containing 162 microM each of Mg2+ and EGTA. MT assembly was initiated by addition of GTP and progressed in a GTP dose-dependent manner. The minimal and optimal exogenous [GTP] required for MT assembly were 15.6 and 500 microM, respectively. Replacement of GTP (25-87%) with increasing [NiCl2] while keeping the sum of [GTP] and [Ni2+] constant at 500 microM enabled MT assembly to proceed with shortened "lags" but reaching the same maximum plateau levels or elongation rates as with 500 microM GTP only. However, in reactions with Ni2+ replacing >94% of GTP, marked inhibition of MT assembly (lower plateaus) occurred. Electron microscopic (EM) examinations showed that MT formed with high Ni2+ substitutions for GTP appeared shorter, more numerous, and resistant to Ca2+ disruption than those assembled with 500 microM GTP only. Notably, in the presence of 500 microM Ni2+ with no GTP added, no typical MT were observed under EM, despite increases in turbidity of the reaction. In addition, the critical concentration of MT proteins required for assembly was also considerably decreased under conditions of Ni2+ replacements of GTP. These results point to an important role of GTP/Ni2+ interaction in modulating the Ni2+ enhancement of MT assembly in vitro.

Interaction of tubulin with guanosine 5'-O-(1-thiotriphosphate) diastereoisomers: specificity of the alpha-phosphate binding region

The exchangeable nucleotide-binding site of tubulin has been studied using diastereoisomers A (Sp) and B (Rp) of guanosine 5'-O-(1-thiotriphosphate) (GTP alpha S) in which the phosphorus atom to which sulfur is attached is chiral. GTP alpha S(A) (10 microM) nucleated assembly of purified tubulin (20 microM) into microtubules in buffer containing 0.1 M 2-(N-morpholino)ethanesulfonic acid with 3 mM Mg2+ and 1 mM EGTA, pH 6.6 at 37 degrees C. With 0.2 mM GTP alpha S(A), the critical concentration (Cc; minimum protein concentration required for assembly) was 8 microM tubulin. Neither 0.2 mM GTP nor GTP alpha S(B) promoted microtubule assembly in buffer with 0.5-6.75 mM Mg2+ and 20-70 microM tubulin. The Cc values for GTP alpha S-(A)-induced assembly of tubulin in buffer with 30% glycerol and of microtubule protein (tubulin and microtubule-associated proteins) in buffer were lower than for GTP. GTP alpha S(A)-induced microtubules were more stable to the cold and to Ca2+. GTP alpha S(A) and GTP but not GTP alpha S(B) bound tightly to tubulin at 4 degrees C. Although GTP alpha S(B) did not nucleate assembly, it did bind to tubulin since it was incorporated into the growing microtubule. Both isomers were hydrolyzed in the microtubules. These studies show that GTP alpha S(A) promotes tubulin assembly better than GTP and GTP alpha S(B) and that there is stereoselectivity at the alpha-phosphate binding region of tubulin. The stereoselectivity may be due to different MgGTP alpha S(A) and -(B) interactions with tubulin.

The magnesium-GTP interaction in microtubule assembly

Microtubule-associated-protein-dependent assembly of tubulin with GDP in the exchangeable site (tubulin-GDP) can occur with minimal free Mg2+ (< 3 microM). This reaction is totally inhibited by EDTA and by GTP concentrations over 2 mM and stimulated by MgCl2. Quantitative aspects of this stimulation are affected by both the Mg2+ and GTP concentrations but no relationship exists between reaction rates and relative amounts of different magnesium and GTP species. GTP binding to tubulin-GDP, while maximally stimulated 2-3-fold by exogenous MgCl2, was inhibited less than 50% by EDTA, and the amount of GTP bound increased as its concentration rose to levels that inhibited polymerization. Studies on the binding of Mg2+ to tubulin-GDP in the presence and absence of GTP showed that the increase in the amount of tubulin-associated Mg2+ was substoichiometric to the amount of GTP bound (maximum stoichiometry of additional Mg2+ to GTP bound, 0.7). Upon polymerization the increased Mg2+ content of tubulin was reduced, indicating its loss during GTP hydrolysis. Mg2+ thus plays a critical role in assembly distinct from its enhancement of GTP binding to the exchangeable site. If magnesium is present in trace amounts, this role must either be catalytic during polymerization or limited to nucleation.

Multiple sites for subtilisin cleavage of tubulin: effects of divalent cations

Limited digestion of pig brain GDP-tubulin by subtilisin was carried out in the presence of Mg2+, Mn2+, Ca2+, Zn2+, or Be2+. Isoelectric focusing, followed by SDS-PAGE, revealed characteristic divalent cation-dependent changes in the alpha- and beta-tubulin cleavage patterns. Previous studies revealed that the beta-cleavage pattern is different for heterodimers and microtubules [Lobert and Correia, 1992: Arch. Biochem. Biophys. 296: 152-160]. Divalent cation effects on subtilisin digestion of tubulin indicate different classes of divalent cation binding sites. Western blot analysis locates the proteolytic zone at residue 430 or higher in both subunits for all conditions. Turbidity and electron microscopy reveal that GDP-tubulin cleaved by subtilisin in the presence of Mg2+, Ca2+, or Mn2+ forms sheets of rings. Mn2+ induces ring formation in uncleaved GDP-tubulin. Isotype-depleted tubulin was generated by the removal of class III beta-tubulin using immunoaffinity chromatography. Subtilisin digestion of the depleted fraction and the purified class III beta-tubulin demonstrates that cleavage occurs at three to four distinct sites. Thus, subtilisin-digested tubulin is more heterogeneous than was previously reported and the cleavage sites depend on solution conditions, divalent cations, and the state of assembly. This has important implications for experiments that utilize subtilisin-digested tubulin for studying microtubule-associated protein binding.