Comparison of Axonal Transport of Cytoplasmic- and Particulate-Associated Tubulin in Rat Optic System

Abstract: Adult rats were injected intraocularly with [³⁵S]methionine and killed from 1 to 10 weeks later. Optic nerves, optic tracts, and superior colliculi were dissected and then homogenized and separated into soluble and particulate fractions by centrifugation. Radioactivity coelectrophoresing with tubulin in buffers containing sodium dodecyl sulfate was determined (in cytoplasmic fractions, preliminary enrichment was achieved by vinblastine precipitation). Accumulation of radioactive tubulin along the optic pathway occurred in parallel (and in approximately equal amounts) in cytoplasmic and particulate fractions. Transported tubulin peaked at approximately 2 and 4 weeks in the optic nerve and tract, respectively, corresponding to a transport rate of ～ 0.4 mm/ day. There was little diminution in the amount of transported tubulin between optic nerve and tract, suggesting tubulin was not degraded in the axon. Accumulation in the superior colliculus reached a plateau by 4 weeks at less than 20% of the peak in the optic nerve, indicating turnover of tubulin at the nerve endings. The α/β subunit labeling ratio (radioactivity distribution between the tubulin subunits) was 0.57 for both cytoplasmic- and particulate-transported tubulin. In contrast, this ratio was 0.69 for whole brain tubulin prepared by vinblastine precipitation of soluble material. Isoelectric focusing and two-dimensional gel electrophoresis showed that the subunit compositions (microheterogeneity of the α and β bands) of transported tubulins in the cytoplasmic and particulate fractions were very similar. However, some differences relative to whole brain tubulin were noted; a tubulin subunit not identifiable in whole brain tubulin preparations but present in both soluble- and particulate-transported tubulin was observed. Because of the compositional and metabolic similarities of transported tubulin in the soluble and particulate fractions, we conclude that they form a common metabolic pool. This suggests either that, at least for some membranes, the well-characterized tight association between particulate tubulin and membranes may be artifactual or else that an equilibrium exists between soluble and particulate tubulin.     

Membrane-bound tubulin: Resistance to cathepsin D and susceptibility to thrombin

In recent studies we found that cytoplasmic tubulin from brain was rapidly split by brain cathepsin D. Two pools could be established; the major portion was split at 18%/h, a minor portion at 2%/h, under our experimental circumstances. In the present work these experiments were extended to membrane-bound tubulin from brain. The membrane-bound form, in contrast to the cytoplasmic tubulin, was not degraded by cerebral cathepsin D under similar experimental conditions. This was not due to the presence of an inhibitory protein since added cytoplasmic tubulin was degraded. Several other protein components of membrane fractions (synaptosomal, mitochondrial) were degraded by cathepsin D, as measured on two-dimensional electropherograms. Thrombin degraded cytoplasmic tubulin, but the degradation products differed from those of cathepsin D degradation. Thrombin also hydrolyzed membrane-bound tubulin, but at a lower rate than the cytoplasmic form. Our results indicate great differences in the breakdown rate of a protein, which depend on its localization, in accord with the differences found in in vivo turnover rates.     

Multiple forms of tubulin in the cytoskeletal and flagellar microtubules of polytomella

The alga polytomella contains several organelles composed of microtubules, including four flagella and hundreds of cytoskeletal microtubules. Brown and co-workers have shown (1976. J. Cell Biol. 69:6-125; 1978, Exp. Cell Res. 117: 313-324) that the flagella could be removed and the cytoskeletans dissociated, and that both structures could partially regenerate in the absence of protein synthesis. Because of this, and because both the flagella and the cytoskeletons can be isolated intact, this organism is particularly suitable for studying tubulin heterogeneity and the incorporation of specific tubulins into different microtubule-containing organelles in the same cell. In order to define the different species of tubulin in polytonella cytoplasm, a (35)S- labeled cytoplasmic fraction was subjected to two cycles of assembly and disassembly in the presence of unlabeled brain tubulin. Comparison of the labeled polytomella cytoplasmic tubulin obtained by this procedure with the tubulin of isolated polytomella flagella by two-dimensional gel electrophoresis showed that, whereas the β-tubulin from both cytoplasmic and flagellar tubulin samples comigrated, the two α-tubulins had distinctly different isoelectic points. As a second method of isolating tubulin from the cytoplasm, cells were gently lysed with detergent and intact cytoskeletons obtained. When these cytoskeletons were exposed to cold temperature, the proteins that were released were found to be highly enriched in tubulin; this tubulin, by itself, could be assembled into microtubules in vitro. The predominant α-tubulin of this in vitro- assembled cytoskeletal tubulin corresponded to the major cytoplasmic α-tubulin obtained by coassembly of labeled polytomella cytoplasmic extract with brain tubulin and was quite distinct from the α-tubulin of purified flagella. These results clearly show that two different microtubule-containing organelles from the same cell are composed of distinct tubulins.     

Breakdown of brain tubulin by cerebral cathepsin D

The breakdown of cytoplasmic tubulin from brain (purified by ammonium sulfate fractionation and DEAE cellulose chromatography) by cathepsin D from brain (purified by ammonium sulfate fractionation and pepstatin Sepharose chromatography) was studied; changes in the intensity of tubulin gel bands were determined. The pH optimum of hemoglobin breakdown by cathepsin D was 3.2; the pH optimum for tubulin breakdown was 5.8; at pH 5.8 there was no significant hemoglobin breakdown by the enzyme. Tubulin breakdown had an apparent K_m of 1.8 × 10⁻⁵ M and a V_max of 0.56 μg tubulin (μg enzyme per min). The rate of breakdown was heterogeneous and studied on length of incubation; the major portion of tubulin was rapidly broken down and a smaller portion was more stable. The rate under our experimental conditions was 18%/h in the 1–4 h period and 2%/h after 4 h. This was not due to enzyme instability: after 4 h of inhibition freshly added tubulin was rapidly broken down, whereas freshly added enzyme did not increase the rate of breakdown. Thus breakdown heterogeneity was due to substrate (tubulin) heterogeneity. Pepstatin inhibited cathepsin D breakdown of tubulin at acid pH; at pH 7.6 it had no effect. Leupeptin was not inhibitory. We calculated that the cathepsin D content in brain, if fully active, could break down cytoplasmic tubulin with a half-life of 24 h, but it is likely that under in vivo conditions enzyme activity is greatly modified.     

Role of cytoplasmic dynein in the axonal transport of microtubules and neurofilaments

Recent studies have shown that the transport of microtubules (MTs) and neurofilaments (NFs) within the axon is rapid, infrequent, asynchronous, and bidirectional. Here, we used RNA interference to investigate the role of cytoplasmic dynein in powering these transport events. To reveal transport of MTs and NFs, we expressed EGFP-tagged tubulin or NF proteins in cultured rat sympathetic neurons and performed live-cell imaging of the fluorescent cytoskeletal elements in photobleached regions of the axon. The occurrence of anterograde MT and retrograde NF movements was significantly diminished in neurons that had been depleted of dynein heavy chain, whereas the occurrence of retrograde MT and anterograde NF movements was unaffected. These results support a cargo model for NF transport and a sliding filament model for MT transport.     

Characterization of the microtubule-activated ATPase of brain cytoplasmic dynein (MAP 1C)

We recently found that the brain cytosolic microtubule-associated protein 1C (MAP 1C) is a microtubule-activated ATPase, capable of translocating microtubules in vitro in the direction corresponding to retrograde transport. (Paschal, B. M., H. S. Shpetner, and R. B. Vallee. 1987b. J. Cell Biol. 105:1273-1282; Paschal, B. M., and R. B. Vallee. 1987. Nature [Lond.]. 330:181-183.). Biochemical analysis of this protein (op. cit.) as well as scanning transmission electron microscopy revealed that MAP 1C is a brain cytoplasmic form of the ciliary and flagellar ATPase dynein (Vallee, R. B., J. S. Wall, B. M. Paschal, and H. S. Shpetner. 1988. Nature [Lond.]. 332:561-563). We have now characterized the ATPase activity of the brain enzyme in detail. We found that microtubule activation required polymeric tubulin and saturated with increasing tubulin concentration. The maximum activity at saturating tubulin (Vmax) varied from 186 to 239 nmol/min per mg. At low ionic strength, the Km for microtubules was 0.16 mg/ml tubulin, substantially lower than that previously reported for axonemal dynein. The microtubule-stimulated activity was extremely sensitive to changes in ionic strength and sulfhydryl oxidation state, both of which primarily affected the microtubule concentrations required for half-maximal activation. In a number of respects the brain dynein was enzymatically similar to both axonemal and egg dyneins. Thus, the ATPase required divalent cations, calcium stimulating activity less effectively than magnesium. The MgATPase was inhibited by metavandate (Ki = 5-10 microM for the microtubule-stimulated activity), 1 mM NEM, and 1 mM EHNA. In contrast to other dyneins, the brain enzyme hydrolyzed CTP, TTP, and GTP at higher rates than ATP. Thus, the enzymological properties of the brain cytoplasmic dynein are clearly related to those of other dyneins, though the brain enzyme is unique in its substrate specificity and in its high sensitivity to stimulation by microtubules.     

An immunocytochemical method for the visualization of tubulin-containing structures in the egg of Xenopus laevis

Tubulin can be isolated and purified from Xenopus laevis eggs through modification of Olmstedt's (1970) tubulin isolation method, viz. by repeating the vinblastin precipitation step after resuspension of the sediment in a detergent-containing stabilizing medium. By this we overcome the deleterious influence of the yolk granules in the isolation procedure. From 11 of Xenopus laevis eggs 25 mg VB-paracrystals can be obtained. The apparent molecular weight of the purified tubulin is 52,800. Antiserum against the purified Xenopus VB-paracrystals, raised in 2 Chinchilla rabbits, cross-reacts in immunodiffusion tests in agar gels with rat brain tubulin and with tubulin isolated from Xenopus laevis eggs by the described procedure. Specific indirect fluorescence staining and appropriate control reactions reveal that cilia of Tetrahymena pyriformis, cytoplasmic networks in cultured mouse Leydig cells, as well as mitotic spindles and nuclear regions in paraffin sections of Xenopus laevis blastulae, react with the antibodies against Xenopus laevis egg tubulin as well as with monoclonal antibodies against pig brain tubulin. These results provide additional evidence for the view that tubulin antibodies are neither species nor tissue specific and show that under appropriate conditions tubulin containing structures can be visualized in paraffin sections.     

Griseofulvin interacts with microtubules both in vivo and in vitro

Immunofluorescence microscopy using monospecific tubulin antibody shows that in vivo griseofulvin interferes with the expression of both cytoplasmic and spindle microtubules in tissue culture cells in a concentration-dependent manner. In mouse 3T3 cells cytoplasmic microtubules are destroyed at a griseofulvin concentration of 5 × 10^?5m. At this concentration no increase of the mitotic index is observed but the cells are arrested in interphase, probably due to the destruction of cytoplasmic microtubules. Lowering the drug concentration to 10^?5m allows 3T3 cells to accumulate in c-mitotic (“colchicin-mitotic”) arrest. In HeLa cells the display of spindle microtubules observed in drug-arrested cells appears similar to that seen in normal metaphase cells only at lower griseofulvin concentrations. Higher drug concentrations induce c-mitotic arrest accompanied by an increasing loss of typical metaphase tubulin structures.In vitro polymerization experiments with brain tubulin using both light-scattering and electron microscopy show that in the presence of griseofulvin tubulin can aggregate rapidly in the cold. This behaviour is not found in the absence of the drug. Thus both in vivo and in vitro experiments show that griseofulvin, like other c-mitotic drugs, acts at the level of tubulin polymerization and that its effects are concentration dependent.     

Cytoplasmic gamma‐tubulin complex from brain contains nonerythroid spectrin

The newer member of the tubulin superfamily, γ‐tubulin, is known to mediate microtubule nucleation from the centrosome of eukaryotic cells with the aid of some other proteins. The major amount of γ‐tubulin is believed to be located in the centrosome before the onset of mitotic division. However, a considerable amount has been found in the cytoplasm in the form of a complex whose function is not well known. Microtubules are most abundant in brain tissues and brain microtubules have been extensively used in many in vitro studies. Thus, it is relevant to use brain tissue to characterize cytoplasmic γ‐tubulin complex. Here we show that cytoplasmic γ‐tubulin in brain tissues exists as a ring complex as in other tissues. Interestingly, along with the common members of the γ‐TuRC reported from several tissues and species, the purified brain cytoplasmic complex contains some high molecular weight proteins including α and β nonerythroid spectrin which are not found in other tissues. Immunohistochemical studies of brain tissue sections also show the co‐localization of γ‐tubulin and spectrin. The possible implications have been discussed. J. Cell. Biochem. 110: 1334–1341, 2010. © 2010 Wiley‐Liss, Inc.     

Visualization of assembled and disassembled microtubule protein by double label fluorescence microscopy

Indirect immunofluorescence with rhodamine labelled antibodies and fluoresceinated colchicine (FC) are used to simultaneously localize microtubules and soluble tubulin in cultured ovarian granulosa cells. FC labelled tubulin is most concentrated in regions of the cell occupied by antitubulin stained microtubule bundles. Pretreatment of granulosa cells with colchicine results in a central accumulation of FC and antibody labelled tubulin that coincides with the disposition of 10-nm filament cables. In contrast, the microtubule disrupting agent nocodazole produces a diffuse tubulin distribution as detected with both FC and antibody probes. Taxol treatment, which enhances microtubule assembly, results in a striking concentration of microtubule bundles associated with the nucleus that avidly bind FC. These results suggest that disassembled tubulin is preferentially associated with cytoplasmic microtubules and possibly other formed elements of the cytoskeleton.     

Genetic change may be caused by interference with protein-protein interactions

Several aprotic polar solvents were shown to induce mitotic aneuploidy in yeast: diethyl ketone, γ-valerolactone, pyridine, pivalinic acid nitrile, phenylacetonitrile and fumaric acid dinitrile. Only fumaric acid dinitrile also strongly induced other types of genetic effects including mitotic crossing-over, mitotic gene conversion and point mutation. The other substances only induced aneuploidy and this only over a very narrow dose range.

The treatment protocol used suggested that these chemicals acted via interference with tubulin assembly and disassembly causing a malfunctioning of spindle fiber microtubules. This hypothesis was tested using twice recycled porcine brain tubulin. Diethyl ketone, γ-valerolactone, pyridine and phenylacetonitrile inhibited GTP-promoted assembly of porcine brain tubulin in vitro in the concentration range needed for the induction of mitotic aneuploidy in yeast. Pivalinic acid nitrile accelerated tubulin aggregation whereas fumaric acid dinitrile had no effect even at concentrations 18 times higher than the lowest tested concentration effective in yeast.

The in vitro experiments with porcine brain tubulin further suggest that genetic change can result from interference with specific protein-protein interactions. Fumaric acid dinitrile was the only exception since it did induce aneuploidy but had no effects on the assembly of porcine brain tubulin. This could be caused either by interference with protein-protein interactions other than between molecules during assembly and disassembly of microtubules or species-specific differences in susceptibility between yeast spindle and porcine brain tubulin.     

Electron microscope demonstration of tubulin in cilia and basal bodies of rat tracheal epithelium by the use of an antitubulin antibody

It has been previously demonstrated that both cytoplasmic microtubules and the microtubules of cilia, flagella, and sperm tail contain tubulin. Although the morphology of cytoplasmic microtubules and that of axonemes differs in cells from which they have been isolated, the tubulin of the two structures shares physical and chemical properties. In some mammalian tissues, such as tracheal epithelium, cilia and basal bodies are difficult to isolate and characterize. The use of an enzyme- labeled immunoglobulin probe would facilitate identification and in situ localization of such proteins. Tubulin prepared from porcine brain by ion-exchange chromatography and from rat brain by the method of cyclic polymerization and depolymerization with subsequent disk gel electrophoresis with SDS were injected intravenously into rabbits. The animals were intermittently bled and the antisera extracted. The specificity of the antisera was proved by indirect immunofluorescence staining of the mitotic spindle, specific blocking of spindle staining by purified tubulin and not by other proteins, staining of 3T3 cytoplasmic microtubules, single line on immunoelectrophoresis, failure of control antisera to show any of these, and precipitation of antibody with all tubulin preparations and not with actin. We have shown by electron microscopy of ciliated cells of the tracheal epithelium stained with antitubulin by the indirect enzyme-labeled antibody method that the basal bodies, outer doublets, and central pair of the cilia contain tubulin. This indicates that tubulin in microtubules of cilia and basal bodies of rat tracheal epithelium is antigenically similar to tubulin extracted from cytoplasmic neurotubules of brains from the same species and from a different mammalian species. No other axonemal structures stained with the antitubulin. Three different preparations of tubulin from pigs and rats were used to immunize rabbits. All elicited similar antisera which gave identical staining patterns. The specificity of the staining was demonstrated by the absence of staining with immune serum absorbed with purified tubulin, the absence of staining with preimmune serum, and the absence of staining if any of the reagents were omitted during the staining reaction.     

Cytoplasmic dynein mediates adenovirus binding to microtubules

During infection, adenovirus (Ad) capsids undergo microtubule-dependent retrograde transport as part of a program of vectorial transport of the viral genome to the nucleus. The microtubule-associated molecular motor, cytoplasmic dynein, has been implicated in the retrograde movement of Ad. We hypothesized that cytoplasmic dynein constituted the primary mode of association of Ad with microtubules. To evaluate this hypothesis, an Ad-microtubule binding assay was established in which microtubules were polymerized with taxol, combined with Ad in the presence or absence of microtubule-associated proteins (MAPs), and centrifuged through a glycerol cushion. The addition of purified bovine brain MAPs increased the fraction of Ad in the microtubule pellet from 17.3% +/- 3.5% to 80.7% +/- 3.8% (P < 0.01). In the absence of tubulin polymerization or in the presence of high salt, no Ad was found in the pellet. Ad binding to microtubules was not enhanced by bovine brain MAPs enriched for tau protein or by the addition of bovine serum albumin. Enhanced Ad-microtubule binding was also observed by using a fraction of MAPs purified from lung A549 epithelial cell lysate which contained cytoplasmic dynein. Ad-microtubule interaction was sensitive to the addition of ATP, a hallmark of cytoplasmic dynein-dependent microtubule interactions. Immunodepletion of cytoplasmic dynein from the A549 cell lysate abolished the MAP-enhanced Ad-microtubule binding. The interaction of Ad with both dynein and dynactin complexes was demonstrated by coimmunoprecipitation. Partially uncoated capsids isolated from cells 40 min after infection also exhibited microtubule binding. In summary, the primary mode of Ad attachment to microtubules occurs though cytoplasmic dynein-mediated binding.     

Exploitation of microtubule cytoskeleton and dynein during parvoviral traffic toward the nucleus

Canine parvovirus (CPV), a model virus for the study of parvoviral entry, enters host cells by receptor-mediated endocytosis, escapes from endosomal vesicles to the cytosol, and then replicates in the nucleus. We examined the role of the microtubule (MT)-mediated cytoplasmic trafficking of viral particles toward the nucleus. Immunofluorescence and immunoelectron microscopy showed that capsids were transported through the cytoplasm into the nucleus after cytoplasmic microinjection but that in the presence of MT-depolymerizing agents, viral capsids were unable to reach the nucleus. The nuclear accumulation of capsids was also reduced by microinjection of an anti-dynein antibody. Moreover, electron microscopy and light microscopy experiments demonstrated that viral capsids associate with tubulin and dynein in vitro. Coprecipitation studies indicated that viral capsids interact with dynein. When the cytoplasmic transport process was studied in living cells by microinjecting fluorescently labeled capsids into the cytoplasm of cells containing fluorescent tubulin, capsids were found in close contact with MTs. These results suggest that intact MTs and the motor protein dynein are required for the cytoplasmic transport of CPV capsids and contribute to the accumulation of the capsid in the nucleus.     

Microtubule polarity in Sertoli cells: a model for microtubule-based spermatid transport

Bundles of microtubules occur adjacent to ectoplasmic specializations (ESs) that line Sertoli cell crypts and support developing spermatids. These microtubules are oriented parallel to the direction of spermatid movement during spermatogenesis. We propose a model in which ESs function as vehicles, and microtubules as tracks, for microtubule-based transport of spermatids through the seminiferous epithelium. Microtubule polarity provides the basis for the direction of force generation by available mechanoenzymes. As part of a more general study designed to investigate the potential role of microtubule-based transport during spermatogenesis, we have studied the polarity of cytoplasmic microtubules of Sertoli cells. Rat testis blocks were incubated in a lysis/decoration buffer, with and without exogenous purified bovine brain tubulin. This treatment results in the decoration of endogenous microtubules with curved tubulin protofilament sheets (seen as hooks in cross section). The direction of curvature of the hooks indicates microtubule polarity; that is, clockwise hooks are seen when viewing microtubules from the plus to the minus end. We found that, in Sertoli cells, most of the hooks were orientated in the same direction. Significantly, when viewed from the base of the epithelium, hooks pointed in a clockwise direction. The clockwise direction of dynein arms on axonemes of sperm tails, in the same section, provided an internal check of the section orientation. Electron micrographs of fields of seminiferous epithelium were assembled into montages for quantitative analysis of microtubule polarity. Our data indicate that Sertoli cell cytoplasmic microtubules are of uniform polarity and are orientated with their minus ends toward the cell periphery. These observations have significant implications for our proposed model of microtubule-based transport of spermatids through the seminiferous epithelium.     

An immunocytochemical method for the visualization of tubulin-containing structures in the egg of Xenopus laevis

Summary Tubulin can be isolated and purified from Xenopus laevis egges through modification of Olmstedt's (1970) tubulin isolation method, viz. by repeating the vinblastin precipitation step after resuspension of the sediment in a detergent-containing stabilizing medium. By this we overcome the deleterious influence of the yolk granules in the isolation procedure. From 1 l of Xenopus laevis eggs 25 mg VB-paracrystals can be obtained. The apparent molecular weight of the purified tubulin is 52,800. Antiserum against the purified Xenopus VB-paracrystals, raised in 2 Chinchilla rabbits, cross-reacts in immunodiffusion tests in agar gels with rat brain tubulin and with tubulin isolated from Xenopus laevis eggs by the described procedure. Specific indirect fluorescence staining and appropriate control reactions reveal that cilia of Tetrahymena pyriformis, cytoplasmic networks in cultured mouse Leydig cells, as well as mitotic spindles and nuclear regions in paraffin sections of Xenopus laevis blastulae, react with the antibodies against Xenopus laevis egg tubulin as well as with monoclonal antibodies against pig brain tubulin.These results provide additional evidence for the view that tubulin antibodies are neither species nor tissue specific and show that under appropriate conditions tubulin containing structures can be visualized in paraffin sections.     

Altered Time Course of mRNA Expression of Alpha Tubulin in the Central Nervous System of Hens Treated with Diisopropyl Phosphorofluoridate (DFP)

Diisopropyl phosphorofluoridate (DFP) produces organophosphorus-ester induced delayed neurotoxicity (OPIDN) in the hen, human and other sensitive species. We studied the effect of single dose of DFP (1.7 mg/kg/s.c.) on the expression of alpha tubulin which is one of the major sub-unit of tubulin polymers that constitute an important constituent of cellular architecture. The hens were sacrificed at different time points i.e. 1, 2, 5, 10, and 20 days. Total RNA was extracted from the following brain regions: cerebrum, cerebellum, and brainstem as well as spinal cord. Northern blots prepared using standard protocols were hybridized with alpha tubulin as well as with -actin and 28S RNA cDNA (controls) probes. The results indicate a differential /spatial /temporal regulation of alpha tubulin levels which may be the result of perturbed microtubule dynamics not only in the axons but also in perikarya of neurons in the CNS of DFP treated hens. In the highly susceptible tissues like brainstem and spinal cord the initial down-regulation of mRNA levels could be attributed to DFP induced stress response resulting in inhibited cell metabolism and or cell injury / cell death. Increase in levels of mRNA at 5 days and thereafter coincided with increased tubulin transport which may be due to increased phosphorylation of tubulins in both axons and perikarya and other intraaxonal changes resulting in impaired axonal transport. DFP induced decreased rate of tubulin polymerization resulting in increased levels of free tubulin monomers may be involved in the altered alpha tubulin mRNA expression at different time points by autoregulatory circuits. Cerebellum being the less susceptible tissue showed only a moderate decline at day 2, while the alpha tubulin remained at near control levels at day 1. Delayed down-regulation may be due to the co-ordinated up or down- regulation of different sub-types of alpha and beta tubulins as well as the differential response of specialised cell types in cerebellum. Continuous overexpression of alpha tubulin in cerebrum from the beginning may be its effective protective strategy to safeguard itself from neurotoxicity. Differential expression pattern observed could be due to the differential susceptibility and variability in the rate of axonal transport of different regions besides the tubulin heterogenity of CNS. Hence our results indicte differential expression of alpha tubulin is either one of the reasons for the development of OPIDN or the result of progressive changes taking place during OPIDN.     

CHANGES IN AMOUNT OF COLCHICINE-BINDING PROTEIN (TUBULIN) IN RABBIT BRAIN DURING DEVELOPMENT1

Colchicine binding was used as a measure of the levels of microtubule protein (tubulin) in several regions of rabbit brain during postnatal development. All regions studied showed a decrease in tubulin per mg of total protein; however, each region showed an increase in total tubulin from 1 day of age to adulthood. The net change in tubulin during development coincided with a proliferation of dendrites (which are rich in microtubules) and a decrease in microtubules from spindle apparatus, axons and astrocytes. We suggest that the total amount of tubulin changes in response to demands of the maturing brain cell for microtubules with different functional roles.     

Microtubule assembly in developing mammalian brain.

Microtubule protein was measured in mouse brain homogenates by quantitative colchicine binding. Neonatal animals contained more than twice the amount of brain tubulin as adult mice. The percentage of colchicine-binding protein which was polymerized was determined by extracting brain at room temperature into a medium designed to stabilize intact microtubules. Under identical conditions and tubulin concentrations, neonatal brain tubulin (colchicine-binding activity) had a greater proportion of the total extracted in an apparently polymerized state (pelletable by centrifugation) than did adult brain. A slight variation in the ratio of assembled to unassembled tubulin was observed with varying protein concentration (volume of extract), indicating that the values obtained may not reflect exactly the in vivo situation, because a rapid equilibration takes place upon homogenization. At all protein concentrations, the neonatal brain extracts contained a significantly greater proportion of assembled tubulin than did adult brain. This proportion began to fall at 5 days postnatal and reached the adult level at 30 days. The tubulin assembled/not assembled ratios were not altered by addition of nucleoside triphosphates, additional EGTA, or sulfhydryl protecting agents, and did not vary with preparation times of 30–90 min. The colchicine-binding reaction and decay of colchicine-binding activity with time were similar in extracts of different aged mouse brains, with neonatal slightly more stable than adult. Pools of tubulin from any age which were soluble at room temperature (unpolymerized) could not repolymerize well in vitro when incubated with GTP at 37 °C, whereas pools of tubulin which were sedimentable at room temperature (polymerized) could be redissolved at 0 °C and readily reassembled at 37 °C. The neonatal extract tubulin was thus more polymerization competent than the adult extracts; this correlates with a greater proportion of assembled tubulin in extracts at room temperature and possibly in vivo.     

Buffer conditions and non-tubulin factors critically affect the microtubule dynamic instability of sea urchin egg tubulin.

The dynamic instability of individual microtubules (Mts) in cytoplasmic extracts or assembled from highly purified sea urchin egg tubulin was examined using video-enhanced, differential-interference contrast (VE-DIC) light microscopy. Extract Mts (endogenous tubulin = 12.1 microM) displayed only plus-ended growth. The elongation velocity was 7.8 microns/min for an average duration of 1.3 min before switching (catastrophe) to rapid shortening, which occurred at 13.0 microns/min for an average duration of 0.5 min before switching (rescue) back to the elongation phase. These parameters are typical of interphase Mt dynamic instability. Surprisingly, Mts assembled from purified urchin egg tubulin in standard buffers were less dynamic that those reported for purified brain tubulin or Mts in the extract. Buffer parameters were changed in an attempt to mimic the extract Mt results. The pH buffer itself, Hepes or Pipes, drastically altered Mt dynamics but could not achieve high elongation velocity with high catastrophe frequencies. Calcium at 1 microM had negligible effects, while increasing pH from 6.9 to 7.2 stimulated elongation velocity. Finally, Mt dynamics of purified egg tubulin (11.9 microM) were assayed in ultrafiltrates (MW cut-off less than 30 kD) of the cytoplasmic extracts. Mts elongated slowly at 1.2 microns/min for 26 min before a catastrophe and rapid shortening at 11.8 microns/min. Rescue was less frequent than unfiltered extracts, minus-ended growth was observed, and self-assembly occurred at slightly higher tubulin concentrations. Therefore, the egg extracts and cytoplasm must contain non-buffer factors which stimulate elongation velocity by 6.5-fold without self-assembly, increase catastrophe frequency by 20-fold, and block minus-ended growth.