Phosphorylation of a p38‐like MAPK is involved in sensing cellular redox state and drives atypical tubulin polymer assembly in angiosperms

Reactive oxygen species (ROS) imbalance is a stressful condition for plant cells accompanied by dramatic changes in tubulin cytoskeleton. Here, evidence is provided that alterations in ROS levels directly interfere with the phosphorylation state of a p38‐like MAPK in the angiosperms Triticum turgidum and Arabidopsis thaliana. Both oxidative stress generators and chemicals inducing ROS scavenging or decreasing ROS production resulted in the accumulation of a phospho‐p46 protein similar to p38‐MAPK. Importantly, the rhd2 A. thaliana mutants exhibited a remarkable increase in levels of phospho‐p46. The presence of the p38‐MAPK inhibitor SB203580 attenuated the response to ROS disturbance, prevented microtubule disappearance and resulted in a dramatic decrease in the number of atypical tubulin polymers. Moreover, in roots treated simultaneously with substances inducing ROS overproduction and others resulting in low ROS levels, phospho‐p46 levels and the organization of tubulin cytoskeleton were similar to controls. Collectively, our experimental data suggest, for the first time in plants, that p46 functions as a putative sensor of redox state, the activation of which initiates downstream signalling events leading to microtubule disruption and subsequent assembly of atypical tubulin polymers. Thus, p46 seems to participate in perception of ROS homeostasis disturbance as well as in cellular responses to redox imbalance.     

Phaeoacremonium spp. and Botryosphaeriaceae spp. Associated with Date Palm (Phoenix dactylifera L.) Decline in Iran

During spring and summer of 2011, a survey was undertaken on some palm groves in the Kerman province (south‐eastern Iran) to determine the fungal pathogens associated with date palm (Phoenix dactylifera L.) decline diseases. Samples were taken from date palm trees showing yellowing, wilting and dieback symptoms. Isolations were made from symptomatic tissues on malt extract agar (MEA) supplemented with 100 mg/l streptomycin sulphate (MEAS). Two species of Phaeoacremonium, Phaeoacremonium aleophilum and Pm. parasiticum, and two species of Botryosphaeriaceae, Botryosphaeria dothidea andDiplodia mutila, were isolated from affected trees and identified on the basis of morphological, cultural and molecular characteristics. Pathogenicity tests were performed on date palm (4‐year‐old potted plants) under greenhouse conditions. Based on the pathogenicity tests, Pm. aleophilum was the most virulent and caused the longest lesions. This is the first report of Pm. aleophilum and B. dothidea and their pathogenicity on date palm tree.     

The octarepeat region of hamster PrP （PrP51-91） enhances the formation of microtubule and antagonize Cu^2＋-induced microtubule-disrupting activity

Prion protein （PrP） is considered to associate with microtubule and its major component, tubulin. In the present study, octarepeat region of PrP （PrP51-91） was expressed in prokaryotic-expressing system. Using GST pull-down assay and co-immunoprecipitation, the molecular interaction between PrP51-91 and tubulin was observed. Our data also demonstrated that PrP51-91 could efficiently stimulate microtubule assembly in vitro, indicating a potential effect of PrP on microtubule dynamics. Moreover, PrP51-91 was confirmed to be able to antagonize Cu^2＋-induced microtubule-disrupting activity in vivo, partially protecting against Cu^2＋- intoxication to culture cells and stabilize cellular microtubule structure. The association of the octarepeat region of PrP with tubufin may further provide insight into the biological function of PrP in the neurons.     

Insights into the Morphology of Haplozoan Parasites (Dinoflagellata) using Confocal Laser Scanning Microscopy

We describe new insights into the morphology and life history of the bizarre parasite Haplozoon axiothellae (Dinoflagellata) using light microscopy (LM), scanning electron microscopy (SEM), and confocal laser scanning microscopy (CLSM). Trophonts were isolated from the intestines of host maldanid polychaetes, Axiothella rubrocincta, collected from San Juan Island, Washington, USA. LM and SEM confirmed features previously observed, such as amphiesmal projections, mature and immature junctions between the nucleated compartments of the vermiform syncytium and visible polygonal alveoli. CLSM of adult trophonts fluorescently stained for DNA, tubulin, centrin, and plasma membrane demonstrated several new ultrastructural traits: (1) an extensive basket of parallel microtubules within the trophomere used for host attachment, (2) two physically separated MTOCs (i.e. putative pairs of basal bodies) beneath pores on the ventral side of each compartment, (3) robust mitotic and/or meiotic spindles associated with one to four nuclei in each compartment, (4) spindles with polar bodies that are disconnected from the MTOCs, (5) a centrin-stained fibril within the trophomeres that potentially functions to retract the motile stylet, and (6) cytokinesis in the posterior-most compartments. This study renames haplozoan compartments using the suffix “-mere” rather than “-cyte” (i.e. trophomere, gonomere, sporomere) to reflect their status within a single syncytium.     

4-Hydroxynonenal interacts with tubulin by reacting with its functional -SH groups

4-Hydroxynonenal, which is one of the most important products of lipid peroxidation, alters microtubular organization and structure in 3T3 fibroblasts. Changes in cell shape and the disappearance of microtubules are observed by immunofluorescence after incubation with the aldehyde, and the colchicine binding activity of tubulin from 3T3 cells is modified. Moreover, the aldehyde determines a decrease in the ability of purified tubulin to polymerize and to bind colchicine. These effects may be related to the interaction of the aldehyde with functional -SH groups of tubulin which are necessary for protein integrity and functions. Indeed, the addition of cysteine protects against the damaging effects of the aldehyde.     

Distinct and overlapping binding sites for IKP104 and vinblastine on tubulin

IKP104 is one of a group of tubulin-binding drugs whose interaction with tubulin suggests that it may bind to the protein at or close to the region where vinblastine binds. By itself IKP104 is a potent enhancer of tubulin decay as evidenced by the fact that it induces the exposure of the sulfhydryl groups and hydrophobic areas on tubulin. In this respect, IKP104 differs from vinblastine and other drugs such as phomopsin A, dolastatin 10, rhizoxin, and maytansine which are competitive or noncompetitive inhibitors of vinblastine binding. In contrast, however, in the presence of colchicine, IKP104 behaves differently and strongly stabilizes tubulin, to an extent much greater than does colchicine alone. IKP104 appears to have two classes of binding site on tubulin, differing in affinity; the acceleration of decay appears to be mediated by the low-affinity site (Chaudhuriet al., 1998,J. Protein Chem., in press). We investigated the relationship of the binding of IKP104 and vinblastine. We found that the high-affinity site or sites of IKP104 overlap with or interact with the vinblastine-binding sites, but that the low-affinity site is distinctly different.     

Microtubules self-repair in living cells

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Microtubular protein impairment by pentanal and hexanal

Pentanal and hexanal are some of the aldehydes produced by lipid peroxidation, that causes damage to several subcellular structures. Lipoperoxidation products may directly attack cytoskeleton structures, the integrity of which is required for secretion mechanisms, e.g. 4-hydroxy-alkenals after microtubular integrity and function. Purified microtubular protein incubated with pentanal and hexanal at different concentrations revealed a tubulin-aldehyde interaction affecting the polymerization reaction and the colchicine-binding activity. These reactions apparently do not involve sulphydryl groups, and the addition of mercaptoethanol does not protect microtubules from the action of aldehydes, the effect of which is however more homogeneous, as only small differences can be noticed among the various aldehyde concentrations used.     

The differential distribution of beta tubulin mRNAs in individual mammalian brain cells

It has been shown by in vitro translation of polyadenylated messenger RNAs (poly(A)+ mRNAs) that the mRNAs encoding both alpha and beta tubulin isotypes are present at much higher relative levels in the developing rat brain than they are in the adult, suggesting that the requirements for tubulin subunits vary with cell type and/or with the developmental stages of a particular cell type. The postnatally developing rat cerebellum, with its readily identifiable cell populations that perform the gamut of developmental tasks, is a suitable model for analyzing specific cellular mRNA distributions during development. In this report, by in situ hybridization techniques it is shown that, by comparison to total cellular poly(A)+ mRNA levels, there is relatively more of the total beta tubulin mRNAs in mitotically active external granule layer cells than in those in the internal granule layer. These results show that migration and differentiation of these granule cells is accompanied by a decrease in their beta tubulin mRNA levels relative to the levels in granule cells of the external granule cell layer. Furthermore, the relative levels of beta tubulin mRNA both in the prenatally formed Purkinje cells and the postnatally formed stellate cells are two to fourfold less than in the granule cells of the internal granule cell layer.