Tubulin sulfhydryl groups and polymerization in vitro. Effects of di- and trivalent cations

Occurrence of Volcanogenic Inorganic Mercury in Wild Mice Spinal Cord: Potential Health Implications

Mercury accumulation has been proposed as a toxic factor that causes neurodegenerative diseases. However, the hazardous health effects of gaseous elemental mercury exposure on the spinal cord in volcanic areas have not been reported previously in the literature. To evaluate the presence of volcanogenic inorganic mercury in the spinal cord, a study was carried out in São Miguel island (Azores, Portugal) by comparing the spinal cord of mice exposed chronically to an active volcanic environment (Furnas village) with individuals not exposed (Rabo de Peixe village), through the autometallographic silver enhancement histochemical method. Moreover, a morphometric and quantification analysis of the axons was carried out. Results exhibited mercury deposits at the lumbar level of the spinal cord in the specimens captured at the site with volcanic activity (Furnas village). A decrease in axon calibre and axonal atrophy was also observed in these specimens. Given that these are relevant hallmarks in the neurodegenerative pathologies, our results highlight the importance of the surveillance of the health of populations chronically exposed to active volcanic environments.

Genotoxic Effects of Silver Amalgam and Composite Restorations: Micronuclei-Based Cohort and Case-Control Study in Oral Exfoliated Cells

Context

A huge number of people carry dental fillings which contain either mercury-based amalgam and/or the recently introduced methacrylate-based resins. It has been shown that both these materials are known to be leached into the oral cavity and induce genotoxic alterations in the buccal mucosal cells. Because of its low cost and ease of manipulation, dental amalgam is still widely used as a restorative material in developing countries. The health risks associated with the components of this restorative material has always been a matter of concern. The present study was designed to assess the frequency of micronuclei (MN) in oral mucosal cells as it is a promising tool for studying the genotoxic effect of clastogenic agents on them.

Aims

The aim of this study is to evaluate the genotoxic effects of silver amalgam and composite restorations by measuring the mean number of MN in oral exfoliated cells.

Materials and Methods

The present study was a prospective cohort study which includes a study group consisting of 110 participants. The study sample was equally divided into 55 participants requiring only amalgam restoration and 55 participants requiring only composite restoration in any permanent molar teeth. The same participants before the restoration formed the control group. Smears were obtained from each patient before and 10 days after restoration and were stained with DNA-specific Feulgen stain. The number of cells containing MN out of 500 cells were counted and recorded. After the evaluation of the slides, the results were compiled and subjected to statistical analysis.

Results

There was a statistically significant (P < 0.01) variation in the mean number of MN after the restoration in both amalgam (5.41 ± 1.25) and composite (2.83 ± 0.85) restorations when compared to before the restoration. However, the mean number of MN in composite restoration was significantly less when compared to amalgam restoration. There was also a statistically significant difference in the mean number of MN in subjects with single restoration when compared with multiple restorations in both amalgam and composite restorations.

Conclusions

The observations from the present study showed the genotoxic effect of amalgam and composite restorations on the oral cavity. However, composite restorations were least cytotoxic when compared to amalgam restoration. Future research and technical advancements are needed for developing safer materials for use in humans.

The Expression and Significance of Metallothioneins in Murine Organs and Tissues Following Mercury Vapour Exposure

The fate of inspired mercury vapour (Hg0) is critical in the central nervous system (CNS) where it can circumvent the blood—brain barrier (BBB) at the neuromuscular junction (NMJ) and accumulate indefinitely in motor neurons by retrograde transport. The detoxification of systemic Hg0 by lung and liver requires investigation. We exposed 129/Sv wild-type (Wt) and 129/Sv MT-I, II double knockout (KO) mice to 500 μg Hg0/m3 for 4 hours to investigate the expression of MT in the lung, liver, and spinal cord following Hg0 exposure using unexposed groups as controls. There were congestive changes in liver and lung of both Wt and MT-KO groups of Hg0-treated mice; these changes appeared more pronounced in the MT-KO group. Motor neurons in the spinal cord did not show any pathological changes. Based on expression of MT, liver appears to have a major role in trapping and stabilising mercury. In the spinal cord, MT was expressed in all white matter astrocytes and in some grey matter astrocytes. Notably, motor neurons did not express MT, and the presence of MT could not be demonstrated in the axons of the ventral root. The absence of MT expression in motor neurons and their axons suggests the dependence of the motor system on the detoxifying capacity of liver MTs.

Effects of hexavalent chromium on microtubule organization, ER distribution and callose deposition in root tip cells of Allium cepa L

The subcellular targets of hexavalent chromium [Cr(VI)] were examined in Allium cepa root tips with confocal laser scanning microscopy. Cr(VI) exerted dose- and time-dependent negative effects on root growth rate, the mitotic index and microtubule (MT) organization during cell division cycle. Interphase MTs were more resistant than the mitotic ones, but when affected they were shorter, sparse and disoriented. The preprophase band of MTs became poorly organized, branched or with fragmented MTs, whilst neither a perinuclear array nor a prophase spindle was formed. Metaphase spindles converged to eccentric mini poles or consisted of dissimilar halves and were unable to correctly orient the chromosomes. Anaphase spindles were less disturbed, but chromatids failed to separate; neither did they move to the poles. At telophase, projecting, lagging or bridging chromosomes and micronuclei also occurred. Phragmoplasts were unilaterally developed, split, located at unexpected sites and frequently dissociated from the branched and misaligned cell plates. Chromosomal aberrations were directly correlated with MT disturbance. The morphology and distribution of endoplasmic reticulum was severely perturbed and presumably contributed to MT disassembly. Heavy callose apposition was also induced by Cr(VI), maybe in the context of a cellular defence reaction. Results indicate that MTs are one of the main subcellular targets of Cr(VI), MT impairment underlies chromosomal and mitotic aberrations, and MTs may constitute a reliable biomonitoring system for Cr(VI) toxicity in plants.

Combined zebrafish-yeast chemical-genetic screens reveal gene-copper-nutrition interactions that modulate melanocyte pigmentation

Hypopigmentation is a feature of copper deficiency in humans, as caused by mutation of the copper (Cu(2+)) transporter ATP7A in Menkes disease, or an inability to absorb copper after gastric surgery. However, many causes of copper deficiency are unknown, and genetic polymorphisms might underlie sensitivity to suboptimal environmental copper conditions. Here, we combined phenotypic screens in zebrafish for compounds that affect copper metabolism with yeast chemical-genetic profiles to identify pathways that are sensitive to copper depletion. Yeast chemical-genetic interactions revealed that defects in intracellular trafficking pathways cause sensitivity to low-copper conditions; partial knockdown of the analogous Ap3s1 and Ap1s1 trafficking components in zebrafish sensitized developing melanocytes to hypopigmentation in low-copper environmental conditions. Because trafficking pathways are essential for copper loading into cuproproteins, our results suggest that hypomorphic alleles of trafficking components might underlie sensitivity to reduced-copper nutrient conditions. In addition, we used zebrafish-yeast screening to identify a novel target pathway in copper metabolism for the small-molecule MEK kinase inhibitor U0126. The zebrafish-yeast screening method combines the power of zebrafish as a disease model with facile genome-scale identification of chemical-genetic interactions in yeast to enable the discovery and dissection of complex multigenic interactions in disease-gene networks.

Atrophy of Large Myelinated Motor Axons and Declining Muscle Grip Strength Following Mercury Vapor Inhalation in Mice

The effects of acute mercury vapor (Hg(0)) exposure on the peripheral motor system have not been previously addressed in the literature. Early case studies report that acute exposure in humans can cause symptoms resembling motor neuron disease (MND). Mercury granules can be histochemically demonstrated in the cytoplasm of murine motor neurons following Hg(0) exposure, suggesting it is transported from the neuromuscular junction (NMJ) to the cell body by retrograde axonal transport mechanisms. We considered the hypothesis that morphological damage to the peripheral motor axonal cytoskeleton possibly involving neurofilaments (NFs) follows Hg(0) exposure. Eight-week-old wild type (Wt) 129S/v mice were exposed to 500 microg/m(3) of Hg(0) for 4 h in an experimental vapor exposure chamber. Forelimb grip strength (FGS) was measured over 4-wk intervals prior to removal of the murine phrenic nerves (MPN) 7 mo postexposure. Autometallography of 7-microm-thick spinal-cord sections from Hg(0)-exposed mice confirmed the presence of mercury deposits in ventral horn motor neurons. The morphology of the myelinated motor axons was assessed by computer-assisted image analysis of 1-microm-thick resin cross sections of the MPN. The group exposed to Hg(0) showed a significant reduction in the mean axon caliber, p < .0001. Gaussian spectral analysis of axon diameter distribution showed atrophy principally to large myelinated fibers, a subpopulation of axons that is also affected in MND. This atrophic change was also accompanied by an increased irregularity in axon shape. FGS initially increased with age until 20 wk and then progressively decreased after 22 wk to 36 wk. In conclusion, Hg(0) exposure appears to reduce axon diameter, suggesting axon caliber-determining cytoskeletal components such as neurofilaments may be damaged by heavy metal-induced oxidative stress mechanisms, resulting in functional changes to motor units.

Differential protein expression profiles in anterior gills of Eriocheir sinensis during acclimation to cadmium

Using a proteomic approach, we characterized different protein expression profiles in anterior gills of the Chinese mitten crab, Eriocheir sinensis, after cadmium (Cd) exposure. Two experimental conditions were tested: (i) an acute exposure (i.e. 500 microg Cd l(-1) for 3 days) for which physiological, biochemical and ultrastructural damage have been observed previously; (ii) a chronic exposure (i.e. 50 microg Cd l(-1) for 30 days) resulting in physiological acclimation, i.e. increased resistance to a subsequent acute exposure. Two-dimensional gel electrophoresis (2-DE) revealed six protein spots differentially expressed after acute, and 31 after chronic Cd exposure. From these spots, 15 protein species were identified using MS/MS micro-sequencing and MS BLAST database searches. Alpha tubulin, glutathione S-transferase and crustacean calcium-binding protein 23 were down-regulated after an acute exposure, whereas another glutathione S-transferase isoform was up-regulated. Furthermore, analyses revealed the over-expression of protein disulfide isomerase, thioredoxin peroxidase, glutathione S-transferase, a proteasome subunit and cathepsin D after chronic exposure. Under the same condition, ATP synthase beta, alpha tubulin, arginine kinase, glyceraldehyde-3-phosphate dehydrogenase and malate dehydrogenase were down-regulated. These results demonstrate that acute and chronic exposure to waterborne Cd induced different responses at the protein expression level. Protein identification supports the idea that Cd mainly exerts its toxicity through oxidative stress induction and sulfhydryl-group binding. As a result, analyses showed the up-regulation of several antioxidant enzymes and chaperonins during acclimation process. The gill proteolytic capacity seems also to be increased. On the other hand, the clearly decreased abundance of several enzymes involved in energy transfer suggests that chronic metal exposure induced an important metabolic reshuffling.

Laser capture microdissection (LCM) and expression analyses of Glycine max (soybean) syncytium containing root regions formed by the plant pathogen Heterodera glycines (soybean cyst nematode)

Roots of soybean, Glycine max cv. Kent L. Merr., plants susceptible to the soybean cyst nematode (SCN), Heterodera glycines Ichinohe, were inoculated and allowed to develop feeding sites (syncytia) for 8 days. Root samples enriched in syncytial cells were collected using laser capture microdissection (LCM). RNA was extracted and used to make a cDNA library and expressed sequence tags (ESTs) were produced and used for a Gene Ontology (GO) analysis. RT-PCR results indicated enhanced expression of an aquaporin (GmPIP2,2), alpha-tubulin (GmTubA1), beta-tubulin (GmTubB4) and several other genes in syncytium-enriched samples as compared to samples extracted from whole roots. While RT-PCR data showed increased transcript levels of GmPIP2,2 from LCM tissue enriched in syncytial cells, in situ hybridization showed prominent GmPIP2,2 hybridization to RNA in the parenchymal cells tightly juxtaposed to the syncytium. Immunolocalization indicated stronger alpha-tubulin signal within the syncytium as compared to surrounding tissue. However, alpha-tubulin labeling appeared diffuse or clumped. Thus, LCM allowed for the isolation of tissue enriched for syncytial cells, providing material suitable for a variety of molecular analyses.

Disturbed microtubule function and induction of micronuclei by chelate complexes of mercury(II)

Interactions of mercury(II) with the microtubule network of cells may lead to genotoxicity. Complexation of mercury(II) with EDTA is currently being discussed for its employment in detoxification processes of polluted sites. This prompted us to re-evaluate the effects of such complexing agents on certain aspects of mercury toxicity, by examining the influences of mercury(II) complexes on tubulin assembly and kinesin-driven motility of microtubules. The genotoxic effects were studied using the micronucleus assay in V79 Chinese hamster fibroblasts. Mercury(II) complexes with EDTA and related chelators interfered dose-dependently with tubulin assembly and microtubule motility in vitro. The no-effect-concentration for assembly inhibition was 1 microM of complexed Hg(II), and for inhibition of motility it was 0.05 microM, respectively. These findings are supported on the genotoxicity level by the results of the micronucleus assay, with micronuclei being induced dose-dependently starting at concentrations of about 0.05 microM of complexed Hg(II). Generally, the no-effect-concentrations for complexed mercury(II) found in the cell-free systems and in cellular assays (including the micronucleus test) were identical with or similar to results for mercury tested in the absence of chelators. This indicates that mercury(II) has a much higher affinity to sulfhydryls of cytoskeletal proteins than to this type of complexing agents. Therefore, the suitability of EDTA and related compounds for remediation of environmental mercury contamination or for other detoxification purposes involving mercury has to be questioned.

Organization-dependent effects of toxic bivalent ions microtubule assembly and glycolysis

The effects of bivalent ions on tubulin dynamics and the upper phase of glycolysis were investigated at different organization levels in vitro. Cu2+, Cd2+, Hg2+ and CrO4(2-) inhibit the tubulin polymerization at an IC50 of 14-24 microM with high cooperativity and also induce microtubule disassembly. The apparent binding constants of the ions to tubulin, estimated by fluorescence quenching, vary between 6 and 28 microM. BIAcore measurements for tubulin-tubulin interaction suggest that the presence of Cu2+ affects neither koff nor kon, but the amount of the bound tubulin. While the inhibitory effect of Cu2+ on tubulin polymerization is partially abolished by cross-linking of microtubules with substoichiometric amounts of phosphofructokinase or decoration of tubules with cytosolic proteins, in the presence of kinase but not with cytosolic proteins the tubules are resistant to CrO4(2-). No inhibitory effect of Cu2+ or CrO4(2-) on microtubule assembly was detected in the MAP-containing cytosolic fraction. Electron microscopy revealed that tubules assembled in the presence of Cu2+ or CrO4(2-) ions contain aggregates of thread-like oligomers that are less conspicuous in the presence of cytosolic proteins. Cu2+, Cd2+, and Hg2+ inhibit the glycolytic flux in the cytosolic fraction characterized at equilibrium by an IC50 of 10-14 microM with high cooperativity. Tubulin diminishes the inhibitory effect of the cations. These data indicate that the responses elicited by the bivalent ions are highly dependent on the supramolecular organization of the systems.

Combined enhancement of microtubule assembly and glucose metabolism in neuronal systems in vitro: decreased sensitivity to copper toxicity

Brain cell-free extract greatly stimulates the polymerization rate of purified tubulin with a reduction of the nucleation period and without a significant alteration of the final assembly state. This effect is mimicked by neuroblastoma extract at 10-fold lower extract concentration, but not by excess muscle extract. Copper inhibits microtubule assembly in vitro but in the presence of brain extract the copper effect is suspended. Electron microscopic images showed that intact microtubules are formed and decorated by cytosolic proteins in the absence and presence of copper, while the copper alone induces the formation of S-shaped sheets and oligomeric threads. The flux of triosephosphate formation from glucose is enhanced by microtubules in brain extract, but not in muscle extract. Copper inhibits the glycolytic flux; however, the presence of microtubules not only suspends the inhibition by copper but the activation of glycolysis by microtubules is also preserved. We conclude that the organization of neuronal proteins modifies both the rates of microtubule assembly and glycolysis, and reduces their sensitivities against the inhibition caused by copper.

Probing the ATP binding site of tubulin with thiotriphosphate analogues of ATP

Tubulin assembly studies with GTP alpha S diastereoisomers have shown that there is stereoselectivity at the alpha-phosphate binding region of tubulin. GTP alpha S(Sp) bound tighter than GTP alpha S(Rp) and promoted nucleation and assembly better than GTP and GTP alpha S(Rp). ATP and dATP have been reported to bind weakly to tubulin and to be less effective than GTP and dGTP in promoting tubulin assembly. This study was done to learn if ATP alpha S(Sp) and dATP alpha S(Sp) are good promoters of tubulin assembly and to compare these ATP thiotriphosphate analogues to the corresponding GTP analogues in tubulin assembly. Studies were also done with ATP alpha S(Rp), GTP, ATP beta S(Sp) and ATP gamma S. At least three cycles of tubulin (25 microM) assembly-disassembly were found with 1 mM ATP alpha S(Sp) and dATP alpha S(Sp) and both nucleotides were incorporated and hydrolyzed in the polymers. Less dATP alpha S(Sp) (25 microM) than ATP alpha S(Sp) (100 microM) promoted assembly to 50% of the maximum value. The critical concentrations (Cc) for assembly with 1 mM nucleotide were low for ATP alpha S(Sp) (3 microM) and dATP alpha S(Sp) (2 microM) and compared favorably with GTP (5 microM), GTP alpha S(Sp) (2 microM) and dGTP alpha S(Sp) (1 microM). Both 1 mM ATP and dATP were poor promoters of tubulin assembly and were not detected in the polymers. The predominant structures induced by 1 mM (ATP alpha S(Sp) and dATP alpha S(Sp) were bundles of sheets and microtubules, which were more stable to the cold and to Ca(II) than microtubules assembled with GTP, ATP or dATP. ATP alpha S(Rp) (1 mM) did not promote assembly suggesting that there is stereoselectivity at the ATP alpha S alpha-phosphate binding region of tubulin as there is with GTP alpha S diastereoisomers. ATP alpha S(Sp) and dATP alpha S(Sp) mimic GTP alpha S(Sp) and dGTP alpha S(Sp) in tubulin assembly since all four nucleotides promote bundles of tubulin in buffer with glycerol, and the deoxy nucleotides have lower Cc, shorter lags and faster rates for tubulin assembly.

Effects of fluoro-doxorubicin (ME2303) on microtubules: influence of different classes of microtubule-associated proteins

Anthracyclines are among the most useful agents for the treatment of neoplastic disease, but their clinical use is limited by progressive cardiomyopathy. A few studies have suggested the role of microtubules for the understanding of this toxicity. By using kinetic and structural studies, we demonstrate the disorganizing action of fluoro-doxorubicin, a novel anthracycline, on the microtubule system. Microtubules have a rich and complex composition in relation to their numerous functions in cells. In the present study, we investigate the role of two major microtubule-associated protein (MAP) families, Tau and MAP2. Both MAP families are responsible for the properties of different classes of microtubules. We show the differential effect of fluoro-doxorubicin on these two classes of microtubules. Furthermore, we show that fluoro-doxorubicin is able to affect the capacity of purified tubulin to form normal microtubules. This study confirms that anthracyclines may interfer with the microtubule organization. We suggest that some classes of microtubules, with regard to their MAP composition, may be affected more specifically in cardiac myocytes.

Regulation of cytoplasmic tubulin carboxypeptidase activity in vitro by cations and sulfhydryl-modifying compounds

alpha-tubulin subunits within microtubules (MTs) can be post-translationally detyrosinated by a tubulin-specific carboxypeptidase (TCP) activity to form biochemically distinct MTs. Attempts to characterize and purify TCP have suffered from the inability to detect low levels of activity and to distinguish TCP from other, competing enzyme activities. We recently developed an assay for TCP [Webster et al. (1992) Biochemistry 31:5849] that uses taxol-stabilized MTs as the substrate. In this study, we exploited the increased sensitivity and specificity of this new assay to explore the effects of various agents that might act to either stimulate or inhibit this enzyme in vitro. We tested a variety of both monovalent and divalent cations for their ability to affect TCP, and tested whether the cations were affecting the enzyme, the substrate, or both. We found that TCP displayed salt-sensitive binding to MTs, characteristic of other, more well characterized MT-associated proteins. While both calcium and magnesium stimulated TCP activity over a narrow concentration range (2-10 mM), they inhibited activity at higher concentrations. Other divalent cations tested, including zinc, copper, and cobalt, inhibited TCP at virtually all concentrations tested, but to different levels (zinc > copper > cobalt). Most of the zinc-induced TCP inhibition was attributed to the interference with the normal binding of TCP to MTs. In addition, we examined the involvement of free sulfhydryl groups (which are important for the activities of many types of enzymes) in TCP activity by the addition of sulfhydryl-modifying compounds during the assay, and found that their addition reduced TCP activity mainly (but not solely) by their action on the extract that contained the TCP. Finally, we tested the ability of DL-benzylsuccinic acid, a potent inhibitor of carboxypeptidase A, to inhibit TCP. While carboxypeptidase A has been found, in other studies, to be inhibited by micromolar concentrations, TCP was affected only at concentrations above 20 mM, adding another proof that carboxypeptidase A and TCP are distinct enzyme activities.

Zinc, copper and selenium in reproduction

Of the nine biological trace elements, zinc, copper and selenium are important in reproduction in males and females. Zinc content is high in the adult testis, and the prostate has a higher concentration of zinc than any other organ of the body. Zinc deficiency first impairs angiotensin converting enzyme (ACE) activity, and this in turn leads to depletion of testosterone and inhibition of spermatogenesis. Defects in spermatozoa are frequently observed in the zinc-deficient rat. Zinc is thought to help to extend the functional life span of the ejaculated spermatozoa. Zinc deficiency in the female can lead to such problems as impaired synthesis/secretion of (FSH) and (LH), abnormal ovarian development, disruption of the estrous cycle, frequent abortion, a prolonged gestation period, teratogenicity, stillbirths, difficulty in parturition, pre-eclampsia, toxemia and low birth weights of infants. The level of testosterone in the male has been suggested to play a role in the severity of copper deficiency. Copper-deficient female rats are protected against mortality due to copper deficiency, and the protection has been suggested to be provided by estrogens, since estrogens alter the subcellular distribution of copper in the liver and increase plasma copper levels by inducing ceruloplasmin synthesis. The selenium content of male gonads increases during pubertal maturation. Selenium is localized in the mitochondrial capsule protein (MCP) of the midpiece. Maximal incorporation in MCP occurs at steps 7 and 12 of spermatogenesis and uptake decreases by step 15. Selenium deficiency in females results in infertility, abortions and retention of the placenta. The newborns from a selenium-deficient mother suffer from muscular weakness, but the concentration of selenium during pregnancy does not have any effect on the weight of the baby or length of pregnancy. The selenium requirements of a pregnant and lactating mother are increased as a result of selenium transport to the fetus via the placenta and to the infant via breast milk.

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.

Effects of potential aneuploidy inducing agents on microtubule assembly in vitro

The present study was carried out with the 10 known or suspected spindle poisons of the Commission of the European Communities program to study aneuploidy induction. We have investigated these substances on the assembly of isolated bovine microtubules at 10, 100 and 1000 microM and studied morphology by electron microscopy. The substances could be grouped into two categories, strong and weak inhibitors. Colchicine, vinblastine and thimerosal were strong inhibitors; cadmium chloride, thiabendazole, chloral hydrate, hydroquinone, diazepam and econazole were weak inhibitors, the latter three causing aberrant forms visible on electron microscopy. Pyrimethamine did not inhibit the assembly of microtubules, but produced aberrant forms.

Aging of tubulin at neutral pH: the destabilizing effect of vinca alkaloids

The effect of the vinca alkaloid drugs, vincristine, vinblastine, catharanthine, and vindoline, on the aging process of tubulin has been examined. It was found that addition of vincristine or vinblastine accelerated by a factor of 3-3.5 the transformation of tubulin from the 5.8 S alpha-beta-tubulin dimer to paucidisperse polymers, with an average sedimentation coefficient of 9 S, previously observed in the absence of drugs (V. Prakash and S. N. Timasheff, 1982, J. Mol. Biol. 160, 499-515). This transformation of tubulin from 5.8 S to "9 S" followed pseudo-first-order kinetics whether the starting protein was predominantly dimeric (i.e., at low drug concentration) or self-associated into the reversible linear polymers induced by the vinca alkaloid drugs at high drug concentration (G. C. Na and S. N. Timasheff, 1980, Biochemistry 19, 1355-1365; V. Prakash and S. N. Timasheff, 1985, Biochemistry 24, 5004-5010). Identical kinetics were found in a fluorescence examination of the loss by tubulin of its ability to bind colchicine specifically, indicating that the rate determining step is a protein conformational change that induces a major change in the far uv circular dichroism spectrum of tubulin. The found lack of an effect of dithiothreitol on the aging and aggregation processes is consistent with the irreversible aggregation being due to the intermolecular coalescence of nonpolar patches on the protein. The observations that vincristine binds to aged tubulin and that the aging of tubulin is accompanied by quenching of the tryptophan fluorescence similar to that which occurs on the binding of the vinca drugs has led to the proposal that the vinca alkaloids stabilize the aged conformation of the protein by interacting with nonpolar regions that may be related to the aggregation sites.

Sulfhydryl groups of Mimosa pudica tubulin implicated in colchicine binding and polymerization in vitro

The important characteristic of novel Mimosa pudica tubulin is its ability to bind colchicine only when dithiothreitol is included in the isolation buffer, indicating the involvement of sulfhydryl groups in colchicine binding. Modification of sulfhydryl groups by a sulfhydryl modifying agent also affects the normal assembly of tubulin into microtubules, as revealed by electron microscopic and spectrophotometric studies. The number of free sulfhydryl groups present in tubulin protein responsible for both colchicine binding and polymerization has been found to be 4, distributed in alpha and beta subunits, and is distinctly different from the number reported for animal tubulin.

Highly variable effects of beryllium and beryllium fluoride on tubulin polymerization under different reaction conditions: comparison of assembly reactions dependent on microtubule-associated proteins, glycerol, dimethyl sulfoxide, and glutamate

Carlier et al. (1988, Biochemistry 27, 3555-3559; 1989, Biochemistry 28, 1783-1791) described enhancement of tubulin polymerization and stabilization of glycerol-induced microtubules by BeF3- (by addition of both BeSO4 and NaF to reaction mixtures). We were able to confirm the stabilization of glycerol-induced polymer reported by these workers, provided Mg2+ was also present in the reaction. When we examined polymerization dependent on microtubule-associated proteins (MAPs), however, we obtained very different results. BeF3- had no significant effect on this reaction, or the polymer formed, under any condition examined. Lower concentrations of BeSO4 alone, in contrast to a negligible effect in glycerol, enhanced polymerization with MAPs provided the concentrations of both Mg2+ and GTP were low; and Be2+ stabilized the polymer, if the GTP concentration was low, at both low and high Mg2+ concentrations. Higher concentrations of BeSO4 precipitated tubulin, an effect which was not affected by Mg2+, partially prevented but not reversed by MAPs, and prevented or reversed by either NaF or nucleotides at adequate concentrations. These results suggest that Be2+ binds at site(s) distinct from Mg2+ site(s), and that partial occupancy of these site(s) at lower Be2+ concentrations enhances tubulin polymerization and polymer stability, while extensive occupancy at higher Be2+ concentrations results in tubulin precipitation. Effects of Be2+ and BeF3- on polymerization dependent on dimethyl sulfoxide or glutamate were also evaluated. The dimethyl sulfoxide system displayed properties similar to those of the glycerol system, while the glutamate system was similar to the MAPs system.

Tubulin sulfhydryl groups as probes and targets for antimitotic and antimicrotubule agents

The sulfhydryl groups of tubulin are highly reactive entities. The reactivity of the sulfhydryl groups is sensitive to the presence of tubulin ligands, making these groups excellent probes for the interaction of tubulin with ligands. When tubulin is reacted with N,N'-ethylenebis-(iodoacetamide), two intrachain cross-links form in the beta subunit. Formation of one of these cross-links is completely blocked by colchicine, podophyllotoxin, and nocodazole; formation of the other is blocked completely by maytansine, phomopsin A and GTP and partly by Vinca alkaloids. Different ligands also differ in their effect on the rate of alkylation of tubulin with iodo[14C]acetamide, with vinblastine and phomopsin A being strong inhibitors and maytansine having very little effect. Oxidation of certain key sulfhydryl groups can inhibit microtubule assembly. One of these sulfhydryl groups appears to be cys239, but there are others not yet identified. Sulfhydryl-oxidizing agents also interfere with microtubule-mediated processes in vivo, raising the question of the existence of a physiological regulator of microtubule assembly. Potential physiological regulators have been examined to see if they can control microtubule assembly in vitro at their physiological concentrations. Of the ones that have been examined, thioredoxin and thioredoxin reductase are much better candidates for being physiological regulators than are either cystamine or glutathione.

Studies on the mechanisms of Ni2(+)-induced cell injury: I. Effects of Ni2+ on microtubules

Cytoskeletal perturbations have been associated with exposures to a variety of toxic agents as well as a number of human pathological conditions. We have observed dramatic alterations in the organization of microtubules (MT), a major component of the cytoskeleton, in 3T3 cells exposed to Ni2+. Severe perinuclear bundling and aggregation of MT occurred in both a time- and dose-dependent fashion, and this MT damage was reversible upon removal of Ni2+ from the culture media. To understand the mechanism of the Ni2(+)-induced MT change, we investigated the effect of Ni2+ (0.01 to 3.0 mM) on in vitro tubulin polymerization. Ni2+ at lower concentrations (0.01 to 1.0 mM) had little or no significant effect on the kinetics of MT polymerization. In contrast, in the presence of 1.5 to 2.0 mM Ni2+, a significant promoting effect on both the rate and the final extent of polymerization was observed. However, at Ni2+ concentrations higher than 2.0 mM, such stimulatory effect on the rate and the final extent of tubulin polymerization declined. Furthermore, the promoting effects of Ni2+ on MT polymerization were accompanied by a significant decrease in the lag period. Electron microscopic examination of samples of the polymerization product showed that MT, polymerized in the presence of 2.0 mM Ni2+, appeared more numerous and shorter (1.10 +/- 1.02 microns) than those of control (3.81 +/- 2.29 microns; p less than 0.005). This was probably a direct result of an increase in the number of initiation centers in the presence of Ni2+ as a consequence of the decreased critical concentration (7%, p less than 0.05) necessary for polymerization to occur. Our results suggest that Ni2+ may exert its toxic effect on MT in cultured cells by altering the normal kinetics of MT polymerization.

Structural diversity and dynamics of microtubules and polymorphic tubulin assemblies

Tubulin, the main protein of microtubules (MTs), has the potency of forming a variety of other assembly products in vitro: rings, ring-crystals, C- and S-shaped ribbons, 10 nm fibres, hoops, sheets, heaped sheets, MT doublets, MT triplets, double-wall MTs, microtubules, curled ribbons, and paracrystals. The supramolecular subunits of all of them are the protofilaments which might be arranged either parallel to the axis (e.g., in MTs, ribbons) or curved (e.g., in hoops, microtubules). There is strong evidence that in the second case the protofilaments have an inside-out orientation compared to MTs. All assembly products mentioned are described structurally and their relevance to the in vivo situation is considered. Moreover, MTs and the other assemblies undergo permanent changes. These dynamics occurring in both individual assemblies and assembly populations are discussed from the structural point of view.

Chemical modification of thiol group(s) in protein: application to the study of anti-microtubular drugs binding

1. Different chemical procedures such as performic oxidation, carboxymethylation, carboxyethylation, aminoethylation, cyanylation, acylation, arylation etc. and addition of thiols to activated double bonds, titration of thiols with DTNB (Dithiobis-Nitro-Benzoate) and the reaction of thiols with organomercurials and the titration with p-chloro-mercuri-benzoate (PCMB) etc. are cited and discussed. Their chemical reactions are shown in the figures. 2. We describe in this paper that several chemicals interfere with microtubule assembly by combining with sulfhydryl residues. Reagents such as Cytochalasin-A and B, ethylacetylacrylate, FDNB (fluorodinitrobenzene), NEM (N-ethyl-maleimide), diamide, EBI (ethylene-bis-iodoacetamide, ethacrynic acid, methal ions, methylmercury, triethyllead ion and CDDP (cis-dichlorodiammine-platinum-II) are cited and their mechanisms are discussed.

Effect of 6-hydroxydopamine on polymerization of tubulin. Protection by superoxide dismutase, catalase, or anaerobic conditions

Microtubular protein (tubulin) isolated from porcine brain was subjected to selected oxidative stresses, including incubation with the neurotoxin 6-hydroxydopamine (6-OHDA) under aerobic and anaerobic conditions. The functional capacity of the tubulin was determined on the basis of its ability to form microtubules as measured by alterations in the viscosity of the test mixtures, and confirmed by electron microscopy. 6-OHDA completely inhibited formation of microtubules at concentrations as low as 10 mM. Assembled microtubules were half as susceptible to destruction by 6-OHDA as unaggregated tubulin. Anaerobic conditions or the presence of catalase, superoxide dismutase, or a mixture of superoxide dismutase and catalase provided partial protection against 6-OHDA-induced destruction. In control reactions, tubulin-containing solutions incubated for up to 8 hr at ambient oxygen tensions, also showed significant decreases in ability to polymerize. Anaerobic conditions provided partial protection against this loss of function. In contrast, ascorbate accelerated the loss of activity upon standing, while glutathione or dithiothreitol offered no protection.

In vitro mechanism study of microtubule assembly inhibition by cis-dichlorodiammine-platinum(II)

The inhibitions of microtubule protein (MTP) and tubulin 6S polymerizations by cis-dichlorodiammine-platinum(II) (CDDP) have been investigated by turbidity measurements and electron microscopy. For 2.5 X 10(-4) M CDDP after 40 min contact time at 27 degrees, the inhibition was 60% for MTP (1.2 mg/ml) and nearly 90% for tubulin 6S (1.2 mg/ml). Microtubules were not present after a 1 hr contact time at 27 degrees with 2.5 X 10(-4) M CDDP. Free sulfhydryl group determinations with 5,5'-dithio-bis-(2-nitrobenzoate) (DTNB) showed that 20.10 (+/- 0.05) sulfhydryl groups were found per tubulin dimer. In the presence of excess CDDP, this number was reduced to 17.74 (+/- 0.05) after a 1 hr contact time at 27 degrees. By using CDDP-tubulin dialysis assays, the CDDP-tubulin complex formation was found to be an irreversible reaction through a covalent binding at the sulfhydryl group sites. By the DEAE filter paper method, CDDP was shown to slightly decrease vinca-alkaloid and colchicine bindings to tubulin likely by inducing a conformational change of the protein.

The effects of methyl mercury binding to microtubules

The effects of methyl mercury hydroxide (MeHg) on the in vitro polymerization and depolymerization of microtubules were studied. Polymerization was totally inhibited at 3.0 X 10(-5) M MeHg and depolymerization occurred at concentrations above 1.0 X 10(-5) M MeHg, reaching a maximal rate of -0.33%/min at 5.0 X 10(-5) M MeHg. At or above 1.0 X 10(-4) M MeHg, a mercury-protein aggregate formed in both the polymerization and depolymerization systems. Fifteen free sulfhydryl groups per tubulin dimer were determined, and MeHg bound to all 15. When MeHg bound to only 2 free sulfhydryl groups per dimer, it inhibited polymerization. MeHg bound to free sulfhydryl groups exposed uniquely on the surface of microtubules, as well as those free sulfhydryl groups exposed on the ends. These results show MeHg in vitro to be a potent microtubule assembly inhibitor at ratios stoichiometric with the tubulin dimer. The effects of MeHg on microtubules are presumably mediated through MeHg binding to free sulfhydryl groups both on the ends and on the surface of microtubules. The presence of binding sites (free sulfhydryl groups) on the microtubule surface suggests multiple classes of binding sites for MeHg.

A proposed membrane model for generation of sodium currents in squid giant axons

An experimental review to show that axonal undercoat and cytoskeletal structures underneath the axolemma of squid giant axons play an important role in generating sodium currents is presented. Correspondingly, two alternative membrane models are proposed; one is that the undercoat and cytoskeletal structures support the functioning of sodium channels and the other is that they are directly incorporated with the molecular mechanism of generating sodium currents. This latter model is probable in squid giant axons. The model of direct participation of the underlying cytoskeleton in the sodium activation mechanism modifies the sodium activation gating kinetics in the Hodgkin-Huxley scheme; that is, the transition velocities between the open and closed states of the activation gate depend not only on membrane potentials but also on the time after the onset of application of a potential step.

Effects of methylmercury and some metal ions on microtubule networks in mouse glioma cells and in vitro tubulin polymerization

Mercury compounds and some other metal ions were investigated with respect to their effect on in vitro tubulin polymerization and on cellular microtubules in mouse glioma. In vitro tubulin polymerization was completely inhibited by 2.5 X 10(-5) M Hg2+, 5 X 10(-5) M CH3Hg+, 2 X 10(-4) M Cr3+, 2.5 X 10(-4) M Cu2+, and 5 X 10(-4) M Cd2+. Zn2+ did not affect the polymerization up to 5 X 10(-4) M. Indirect immunofluorescence study with rabbit antiporcine tubulin antibody revealed that methylmercury disrupted the microtubule network at an early stage of growth inhibition. On the other hand, in the presence of Cd2+, Cu2+, and Cr3+ at their growth inhibitory concentrations, no effects on microtubule networks were observed for the first 1 hr. These results indicate that only methylmercury affects cellular microtubules, while other ions seem to interfere with other sites in the cells, although these ions showed the ability to depress in vitro tubulin polymerization.

Changes in hepatic glutathione concentration modify cadmium-induced hepatotoxicity

Cd has a strong affinity for sulfhydryl groups and is hepatotoxic. Thus, to further understand the mechanism of Cd-induced liver injury, the effect of increased and decreased hepatic glutathione (GSH) concentration on Cd-induced liver injury was examined. Liver GSH was lowered by pretreating rats with phorone (250 mg/kg, ip) or diethyl maleate (0.85 mg/kg, ip) 2 hr prior to challenge with various doses of Cd. Ten hours after Cd (1) 40-80% of the rats pretreated with phorone or diethyl maleate and challenged with 1.0-2.0 mg Cd/kg died whereas no mortality was observed in the control group; (2) plasma enzyme activities of alanine (ALT) and aspartate (AST) aminotransferase and sorbitol dehydrogenase (SDH) were markedly increased in phorone and diethyl maleate-pretreated rats challenged with Cd (0.7-2.0 mg/kg) versus control rats; and (3) moderate changes in liver histology were observed in corn oil pretreated and Cd challenged rats, while prior depletion of GSH potentiated histopathologic changes in liver produced by Cd alone. Another group of rats received cysteine (1.9 g/kg, po) 3 hr prior to injection of a lethal dose of Cd. Cysteine pretreatment increased liver GSH levels by 22% 3 hr after administration and attenuated Cd-induced liver injury as evidenced by marked decreases in plasma ALT, AST, and SDH activities. Pathological changes in liver were also reduced. These data indicate that liver reduced GSH concentration is important in modulating Cd-induced hepatotoxicity.

Possible treadmilling in zinc(II)-induced sheet polymers of bovine brain microtubule protein

We have examined the ability of zinc(II)-induced sheet polymers, formed from thrice-cycled bovine brain microtubule protein prepared in the absence of glycerol, to exchange with tubulin subunits at steady state. By a rapid filtration assay in which labeled GTP was used as a marker for tubulin addition and loss, we found that steady-state sheet polymers, formed in 0.5 mM-ZnCl2, 1 mM-dithiothreitol, and 100 mM-2-(N-morpholino)ethanesulfonic acid (pH 6.75) in the presence of a GTP-regenerating system at 37 degrees C, incorporated the label in a time-dependent manner to a maximum level. The steady-state uptake of label was inhibited by colchicine, podophyllotoxin and vinblastine. In pulse-chase experiments, we observed that label added onto sheet polymers in a short pulse was retained for a period equal to that required by the polymers to become fully labeled in a continuous pulse; thereafter, the label was lost gradually to a baseline level. An average of 82% of the label was retained in the sheet polymers after a "cold" chase of equal duration to the time of the pulse. Sheet polymers assembled from microtubule protein prepared in the presence of glycerol gave similar results. Using a double-labeling procedure to analyze tubulin addition and loss simultaneously, we found that the rates of steady-state addition and loss were similar. Sheet polymers retained their structural integrity throughout these experiments, as determined by electron microscopy. We believe that the data are consistent with a "treadmilling" mechanism of polymerization and depolymerization, analogous to that documented to occur in steady-state microtubules in vitro. Such a mechanism is discussed in the context of recent findings from structural studies, and a model consistent with established structural data is offered.

Stimulation of tubulin-dependent ATPase activity in microtubule proteins from porcine brain by taxol

Taxol, an antimitotic agent that induces microtubule assembly, stimulated tubulin-dependent Mg2+-ATPase activity of microtubule-associated proteins (MAPs). A concentration-dependent increase in the rate of ATP hydrolysis was observed. Taxol acted through its binding to the tubulin molecule on MAP ATPase, and maximal stimulation, which was found at approximately equal concentrations of taxol and tubulin, reached about 140% of the original level in the absence of taxol. Taxol enhanced ATP hydrolysis by a mixture of MAPs and tubulin, and this continued at a steady linear rate even when the polymerization had approached a plateau. In the presence of taxol, a large portion of ATPase activity and protein was recovered in the pellet after centrifugation at 70,000 g for 60 min at 25 degrees C. Both colchicine and podophyllotoxin inhibited taxol-stimulated ATPase activity via the same mechanism by which they inhibited taxol-induced microtubule polymerization. The stimulation by taxol was not found in the presence of Ca2+ alone but required Mg2+. We conclude that tubulin effectively stimulates Mg2+-ATPase activity of MAPs under conditions that induce tubulin polymerization.

Axonal microtubules necessary for generation of sodium current in squid giant axons: I. Pharmacological study on sodium current and restoration of sodium current by microtubule proteins and 260K protein

Effects of the reagents suppressing or supporting axoplasmic microtubule assembly were studied on the Na ionic current of squid giant axons by perfusing the axon internally with the solution containing the reagent. Among the reagents suppressing the assembly, colchicine, vinblastine, podophyllotoxin, sulfhydryl reagents such as DTNB and NEM, and chaotropic anions such as iodide and bromide, were examined. These reagents reduced maximum Na conductance and shifted the voltage dependence of steady-state Na activation in a depolarizing direction along the voltage axis. They also made the voltage dependence less steep, but did not affect sodium inactivation appreciably. Effects on Na ionic current of reagents which support microtubule assembly (Taxol, DMSO, D2O and temperature) were opposite the effects of those agents suppressing assembly. At the same time, we demonstrated that after Na currents were partially reduced, they could be restored by internally perfusing the axon with a solution containing microtubule proteins, 260K proteins and cAMP under conditions favorable for microtubule assembly. For full restoration, it was found that the following conditions were necessary: (1) The microenvironment within the axon is suitable for microtubule assembly. (2) Tubulins incorporated into microtubules are fully tyrosinated at their C-termini. (3) A peripheral protein having a molecular weight of 260,000 daltons (260K protein) is indispensable. These results suggest that axoplasmic microtubules and 260K proteins in the structure underlying the axolemma play a role in generating Na currents in squid giant axons.

Tubulin-zinc interactions: binding and polymerization studies

The binding of Zn2+ to tubulin and the ability of this cation to promote the polymorphic assembly of the protein were examined. Equilibrium binding showed the existence of more than 60 potential Zn2+ binding sites on the dimer, including a number of high-affinity sites. The number of high-affinity sites, estimated by using a standard amount of phosphocellulose to remove more weakly bound Zn2+, reached a maximum of 6-7.5 with increasing levels of Zn2+ in the incubation solution. The number also increased with time of incubation at a single Zn2+ concentration. It is suggested that tubulin is slowly denatured in the presence of Zn2+, exposing more binding sites. Cu+ and Cd2+ were effective inhibitors of Zn2+ binding; Mg2+, Mn2+, and Co2+ were much less effective, and Ca2+ was without effect. Zn2+ does not replace the tightly bound Mg2+. GTP reduces the amount of Zn2+ binding under equilibrium conditions and the amount bound to high-affinity sites. Zinc-induced protofilament sheets are produced at a Zn2+/tubulin ratio of 5 in the presence of 0.5 mM GTP, conditions where about two to three Zn2+ ions would be bound to the dimer. At higher GTP concentrations, less assembly occurred, and the products were narrower sheets and microtubules. Zn2+-tubulin, isolated from phosphocellulose, will not assemble unless Mg2+ and dimethyl sulfoxide (Me2SO) or more Zn2+ is added. Broad protofilament sheets, formed from Zn2+-tubulin in the presence of Mg2+ and Me2SO, contain slightly more than one Zn2+ per dimer. It is concluded that Zn2+ stimulates tubulin assembly by binding directly to the protein, not via a ZnGTP complex.

Zinc binding to tubulin

1. Zinc binding to tubulin was studied by incubating microtubules with 65Zn and measuring the 65Zn retained with tubulin on DEAE Sephadex. 2. Data showed two classes of binding site, one of very low affinity and a second class binding 0.86 g-atoms Zn/mol tubulin with a dissociation constant of approx. 110 microM. 3. Binding of zinc to the higher affinity site was 50% inhibited by 2 mM N-ethyl maleimide.

Interaction of Ni2+ with the tubulin-microtubule system

In vitro polymerization of purified goat brain tubulin is stimulated at low Ni2+ concentration, whereas at high nickel concentration (greater than 1 . 10(-4)) polymerization is inhibited. Ni2+, over the concentration range of 1 . 10(-4)-1 . 10(-3) M, enhances the rate of colchicine binding to tubulin, although in its presence the colchicine binding site of tubulin is degraded at a much faster rate at 37 degrees C. Finally, incubation of tubulin with Ni2+ at 37 degrees C gradually alters the native conformation of the protein, as revealed by the quenching of intrinsic tryptophan fluorescence.

Zinc-stimulated microtubule assembly and evidence for zinc binding to tubulin

1. Microtubule reassembly was studied in supernatant fluids from rat brain. Tubulin in extracts from zinc-deficient animals showed an impaired ability to repolymerize compared to extracts from controls; 10 microM zinc stimulated reassembly of tubulin in extracts from zinc-deficient animals. 2. Low zinc concentrations (250-900 microM zinc in the presence of 1 mM EGTA) stimulated reassembly of tubulin in brain extracts from control rats; similar concentrations of nickel had no effect whilst cobalt was inhibitory. In the absence of EGTA 20-40 microM zinc stimulated reassembly in brain extracts from normal rats. 3. Zinc-induced changes in reassembly were associated with changes in the free sulphydryl group content of the assembled crude microtubule protein; increased assembly was associated with a higher free sulphydryl group content, decreased assembly with a lower content. 4. 65Zn was found to bind to tubulin. This binding was partly inhibited by N-ethylmaleimide.

Spatial separation of the two essential thiol groups and the binding site of the exchangeable GTP in brain tubulin. A spin label study

The assembly of microtubules from tubulin prepared without glycerol was inhibited by blocking the two most reactive sulfhydryl groups of the eight free sulfhydryl groups present per tubulin dimer. The assembly was also inhibited by Cu2+ ions in a redox-reaction with the two most reactive sulfhydryl groups. These two sulfhydryl groups had almost the same reactivity towards N-ethylmaleimide and p-chloromercuribenzoate, in spite of the fact that they are located on different subunits of tubulin. It was not possible to label just one single sulfhydryl group at a time by N-ethylmaleimide, and it was not possible to decide whether one or two free sulfhydryl group(s) are needed for assembly. The EPR technique based on the interaction of spin labels with transition metals was used for the study of the distance between the two most reactive sulfhydryl groups and the sites of exchangeable GTP and Mg2+, respectively. The sulfhydryl groups were spin labelled with a nitroxide derivative of N-ethylmaleimide. Cr(III)GTP was used as a paramagnetic substitute for GTP, and Mn2+ for Mg2+. It was found that: a. The exchange of GTP and the total content of GTP were not affected by modification of the sulfhydryl groups. b. The binding sites of the exchangeable GTP and Mg2+ are located 10 A, at least, from the two most reactive sulfhydryl groups. c. The distance between the spin labels introduced on the two most reactive sulfhydryl groups was larger than 17 A. The findings indicate that there is no direct interaction between exchangeable GTP and the two most reactive sulfhydryl groups.

Hepatic copper in Indian childhood cirrhosis

Forty-three liver biopsies histologically diagnosed as Indian childhood cirrhosis were studied with the object of investigating accumulation of copper and copper-associated protein in the hepatocytes as demonstrated by the rhodanine and orcein stains respectively. The findings reveal that, in almost all cases, there was an increased accumulation of copper and copper-associated protein, accompanied by the presence of numerous Mallory bodies. It is postulated that the accumulation of copper in the hepatocytes might be the result of a metabolic defect and might be aetiologically related to the liver cell injury and the subsequent development of Indian childhood cirrhosis.