Microtubules grow by the addition of bent guanosine triphosphate tubulin to the tips of curved protofilaments.

We used electron tomography to examine microtubules (MTs) growing from pure tubulin in vitro as well as two classes of MTs growing in cells from six species. The tips of all these growing MTs display bent protofilaments (PFs) that curve away from the MT axis, in contrast with previously reported MTs growing in vitro whose tips are either blunt or sheetlike. Neither high pressure nor freezing is responsible for the PF curvatures we see. The curvatures of PFs on growing and shortening MTs are similar; all are most curved at their tips, suggesting that guanosine triphosphate-tubulin in solution is bent and must straighten to be incorporated into the MT wall. Variations in curvature suggest that PFs are flexible in their plane of bending but rigid to bending out of that plane. Modeling by Brownian dynamics suggests that PF straightening for MT growth can be achieved by thermal motions, providing a simple mechanism with which to understand tubulin polymerization.

Serum-induced neurite retraction in CAD cells--involvement of an ATP-actin retractile system and the lack of microtubule-associated proteins.

Cultured catecholamine-differentiated cells [which lack the microtubule-associated proteins (MAPs): MAP1B, MAP2, Tau, STOP, and Doublecortin] proliferate in the presence of fetal bovine serum, and, in its absence, cease dividing and generate processes similar to the neurites of normal neurons. The reintroduction of serum induces neurite retraction, and proliferation resumes. The neurite retraction process in catecholamine-differentiated cells was partially characterized in this study. Microtubules in the cells were found to be in a highly dynamic state, and tubulin in the microtubules consisted primarily of the tyrosinated and deacetylated isotypes. Increased levels of acetylated or Δ2-tubulin (which are normally absent) did not prevent serum-induced neurite retraction. Treatment of differentiated cells with lysophosphatidic acid or adenosine deaminase induced neurite retraction. Inhibition of Rho-associated protein kinase, ATP depletion and microfilament disruption each (individually) blocked serum-induced neurite retraction, suggesting that an ATP-dependent actomyosin system underlies the mechanism of neurite retraction. Nocodazole treatment induced neurite retraction, but this effect was blocked by pretreatment with the microtubule-stabilizing drug paclitaxel (Taxol). Paclitaxel did not prevent serum-induced or lysophosphatidic acid-induced retraction, suggesting that integrity of microtubules (despite their dynamic state) is necessary to maintain neurite elongation, and that paclitaxel-induced stabilization alone is not sufficient to resist the retraction force induced by serum. Transfection with green fluorescent protein-Tau conferred resistance to retraction caused by serum. We hypothesize that, in normal neurons (cultured or in vivo), MAPs are necessary not only to stabilize microtubules, but also to establish interactions with other cytoskeletal or membrane components to form a stable structure capable of resisting the retraction force.

Involvement of membrane tubulin in erythrocyte deformability and blood pressure.

OBJECTIVE: To test the hypothesis that erythrocyte deformability is influenced by changes in the content of membrane tubulin (Mem-tub). METHODS AND RESULTS: Human erythrocytes contain tubulin distributed in three pools (membrane, sedimentable, soluble). Erythrocytes from hypertensive humans have a higher proportion of Mem-tub. Increased Mem-tub content in hypertensive patients was correlated with decreased erythrocyte deformability. Treatment of erythrocytes from normotensive individuals with taxol increased Mem-tub content and reduced deformability, whereas treatment of hypertensive patients erythrocytes with nocodazole had the opposite effect. In-vivo experiments with rats were performed to examine the possible relationship between Mem-tub content, erythrocyte deformability, and blood pressure. Spontaneously hypertensive rats (SHRs) showed lower erythrocyte deformability than normotensive Wistar rats. During the development of hypertension in SHR, tubulin in erythrocytes is translocated to the membrane, and this process is correlated with decreased deformability. In-vivo treatment (intraperitoneal injection) of SHR with nocodazole decreased Mem-tub content, increased erythrocyte deformability, and decreased blood pressure, whereas treatment of Wistar rats with taxol had the opposite effects. CONCLUSION: These findings indicate that increased Mem-tub content contributes to reduced erythrocyte deformability in hypertensive animals.

The nuclear mitotic apparatus (NuMA) protein: localization and dynamics in human oocytes, fertilization and early embryos.

The oocyte's meiotic spindle is a dynamic structure that relies on microtubule organization and regulation by centrosomes. Disorganization of centrosomal proteins, including the nuclear mitotic apparatus (NuMA) protein and the molecular motor complex dynein/dynactin, can lead to chromosomal instability and developmental abnormalities. The present study reports the distribution and function of these proteins in human oocytes, zygotes and early embryos. A total of 239 oocytes, 90 zygotes and discarded embryos were fixed and analyzed with confocal microscopy for NuMA and dynactin distribution together with microtubules and chromatin. Microtubule-associated dynein-dependent transport functions were explored by inhibiting phosphatase and ATPase activity with sodium-orthovanadate (SOV). At germinal vesicle (GV) stages, NuMA was dispersed across the nucleoplasm. After GV breaks down, NuMA became cytoplasmic before localizing at the spindle poles in metaphase I and II oocytes. Aberrant NuMA localization patterns were found during oocyte in vitro maturation. After fertilization, normal and abnormal pronuclear stage zygotes and embryos displayed translocation of NuMA to interphase nuclei. SOV treatment for up to 2 h induced lower maturation rates with chromosomal scattering and ectopic localization of NuMA. Accurate distribution of NuMA is important for oocyte maturation, zygote and embryo development in humans. Proper assembly of NuMA is likely necessary for bipolar spindle organization and human oocyte developmental competence.

Submembraneous microtubule cytoskeleton: regulation of ATPases by interaction with acetylated tubulin.

The ATP-hydrolysing enzymes (Na(+),K(+))-, H(+)- and Ca(2+)-ATPase are integral membrane proteins that play important roles in the exchange of ions and nutrients between the exterior and interior of cells, and are involved in signal transduction pathways. Activity of these ATPases is regulated by several specific effectors. Here, we review the regulation of these P-type ATPases by a common effector, acetylated tubulin, which interacts with them and inhibits their enzyme activity. The presence of an acetyl group on Lys40 of alpha-tubulin is a requirement for the interaction. Stimulation of enzyme activity by different effectors involves the dissociation of tubulin/ATPase complexes. In cultured cells, acetylated tubulin associated with ATPase appears to be a constituent of microtubules. Stabilization of microtubules by taxol blocks association/dissociation of the complex. Membrane ATPases may function as anchorage sites for microtubules.

Quantum models of the mind: are they compatible with environment decoherence?

Quantum models of the mind associate consciousness with coherent superposition of states in the brain. Some authors consider consciousness to be the result of a kind of internal quantum measurement process in the brain. In this paper we discuss the ideas of Hameroff-Penrose and Tegmark and their calculation for an estimate of decoherence time. We criticize the Hameroff-Penrose model in the context of a quantum brain model by gravitational collapse orchestrated objective reduction (OOR), assumed by Penrose, and we propose instead that the decoherence process is caused by interaction with the environment. We consider it useful to exploit this possibility because of the growing importance of the decoherence theory in quantum measurement, and also because quantum mechanics can be applied to brain study independently of the Hameroff-Penrose model for mind and consciousness. Our conclusion is that the Hameroff-Penrose model is not compatible with decoherence, but nevertheless the quantum brain can still be considered if we replace gravitational collapse OOR with decoherence. However, our result does not agree with Tegmark's conclusion of refuting not only the Hameroff-Penrose gravitational collapse but also the quantum brain, based on decoherence time calculations in specific cases in the brain. In spite of this fact we also disagree with some points of the response to Tegmark's article given by Hagan, Hameroff, and Tuszynski.

Heterogeneous distribution and organization of cytoskeletal proteins drive differential modulation of metabolic fluxes.

On the basis of experimental data obtained in vitro, we propose that differential segregation of actin and tubulin in the cytoplasm may be a regulatory mechanism of metabolic fluxes. The results presented point out that the same enzymes may be differentially modulated at different locations in the cytoplasm, depending on the cytoskeletal protein present at that location, its concentration, polymeric status, or geometric arrangement. Essentially, actin or microtubular protein would exert their effect on enzymatic catalysis through displacement of the equilibrium of enzyme oligomers either to active or less active species. The latter was corroborated by mathematical modeling of the dynamic coupling between microtubular protein assembly-disassembly and pyruvate kinase activity. From these results, a precise biochemical meaning can be given to the putative linkage existing between the mechanisms by which cells rearrange their cytoplasmic architecture and the dynamics of biochemical reactions taking place concomitantly.

Effect of the anti-microtubule drug oryzalin on growth and differentiation of the parasitic protozoan Leishmania mexicana.

The parasitic protozoan Leishmania mexicana differentiates from a non-motile intracellular amastigote in the mammalian macrophage phagolysosome into a motile, extracellular promastigote in the insect vector gut. This developmental program has been accomplished in vitro, thus providing a useful model for studying changes in the cytoskeleton during cell differentiation. The role of microtubules in leishmania differentiation was demonstrated by using the dinitroaniline herbicide oryzalin, which inhibited both leishmania proliferation and differentiation; 25 microM oryzalin reduced promastigote division by over 95%. Interestingly, at a sublethal dose (5 microM), promastigotes became round and multiflagellated but remained motile. At 50 microM oryzalin, the number of intracellular amastigotes decreased by 50%. However, leishmania differentiation seemed to be the most drug-sensitive stage: there was a 60% reduction in amastigote-to-promastigote differentiation at 0.5 microM oryzalin. The specific action of oryzalin on leishmania microtubules was verified by its inhibition of in vitro polymerization of leishmania microtubules, but not control mammalian microtubules (from rat brain). These findings indicate that microtubules play a major role in leishmania proliferation, maintenance of cell shape, and cytodifferentiation.

The integrity of tubulin molecule is not required for the activity of tubulin carboxypeptidase.

Tubulin dimer, alpha-tubulin subunit, and C-terminal peptides obtained from the alpha-tubulin subunit were compared in their capabilities to act as substrates of tubulin carboxypeptidase. The results obtained indicate that the enzyme does not require the beta-tubulin subunit to release tyrosine from alpha-tubulin. The 17-Kd C-terminal peptide of the alpha-tubulin subunit was obtained and it was detyrosinated at the same rate as tubulin dimer. A smaller C-terminal peptide of 2.8-3.7 Kd showed a lower capability to act as substrate. Similar results were obtained with pancreatic carboxypeptidase A. From the analysis of the results we consider that an optimal activity of the tubulin carboxypeptidase depends mainly on the accessibility of the C-terminal end of alpha-tubulin.