Biochemical determination of tubulin-microtubule equilibrium in cultured cells.

The relative amount of free and microtubule-associated tubulin in tissue culture cells was determined by colchicine binding. Both microtubules and tubulin were stabilized in a dilute homogenate containing 50% glycerol and 5% dimethylsulfoxide. Microtubules were separated by sedimentation at 100,000g for 10 min in a benchtop ultracentrifuge and then depolymerized to tubulin. Colchicine binding to free tubulin could be performed only after dilution of the organic solvents present to prevent a 70% reduction in apparent affinity of tubulin for colchicine. Tubulins purified from rat brain, human skin fibroblasts, and rat GH₃ cells were each homogeneous and similar in molecular weight, affinity for DEAE-cellulose, and apparent affinity for colchicine. Microtubules contained 34–41% of tissue culture cell tubulin. Colchicine (10^?6 to 10^?5m) and incubation at 4°C reduced microtubule-derived tubulin to less than 6% of expected.     

Interaction of anthelmintic benzimidazoles with AscarisSuum embryonic tubulin

The ability of mebendazole and fenbendazole to bind to tubulin in cytosolic fractions from 8-day Ascaris suum embryos was determined by inhibition studies with [³H]colchicine. Colchicine binding in the presence of 1·10^?6 M mebendazole was completely inhibited during a 6 h incubation period at 37°C. Inhibition of colchicine binding to A. suum embryonic tubulin by mebendazole and fenbendazole appeared to be noncompetative. The inhibition constants of mebendazole and fenbendazole for A. suum embryonic tubulin were 1.9·10^?8 M and 6.5·10^?8 M, respectively. Mebendazole and fenbendazole appeared to be competitive inhibitors of colchicine binding to bovine brain tubulin. The inhibition constants of mebendazole and fenbendazole for bovine brain tubulin were 7.3·10^?6 M and 1.7·10^?5 M, respectively. These values are 250–400 times greater than the inhibition constants of fenbendazole and mebendazole for A. suum embryonic tubulin. Differential binding affinities between nematode tubulin and mammalian tubulin for benzimidazoles may explain the selective toxicity. The importance of tubulin as a receptor for anthelmintic benzimidazoles in animal parasitic nematodes is discussed.     

Role of B-ring of colchicine in its binding to Zn(II)-induced tubulin-sheets

Colchicine-tubulin dimer comPlex, a Potent inhibitor of normal microtubule assembly undergoes extensive self-assembly in the Presence of 1 X 10^-4 M zinc sulPhate. Polymers assembled from colchicine-tubulin dimer comPlexes are sensitive to cold. Although colchicine can be accomodated within the Polymeric structure, the drug cannot bind to tubulin subunits in the intact Polymers. This is evidenced by the fact that (a) the colchicine binding activity of tubulin is lost when allowed to Polymerize with zinc sulPhate, (b) the loss in colchicine binding could be Prevented by Preincubation of tubulin with 1 X 10^-3 M CaCl₂ or 1 X 10^-5 M vinblastine sulPhate and finally (c) no loss in colchicine binding activity is found when tubulin is kePt at a concentration far below the critical concentration for Polymerization. Unlike colchicine, its B-ring analogues desacetamido colchicine (devoid of the B-ring subtituent) and 2-methoxy-5-(2′, 3′, 4′-trimethoxyPhenyl) troPone (devoid of the B-ring) can bind to tubulin subunits in the intact Polymers. Thus we conclude that the colchicine binding domain on the tubulin molecule is mostly (if not comPletely) exPosed in the Zn(II) -induced Polymers and the B-ring substituent Plays a major role in determining the binding ability of a colchicine analogue to tubulin in the intact Zn(II) -induced sheets.     

Specific affinity labelling of tubulin with bromocolchicine

Bromocolchicine, synthesized by substituting tho N-acetyl moiety of colchicine with a reactive bromoacetyl group, was found to be an affinity label for tubulin. Binding of [³H]colchicine to tubulin was competitively and irreversibly inhibited by bromocolchicine with a K_i value of 2.3 × 10^?5m. The affinity label could not be displaced by precipitating the protein with trichloroacetic acid and is thus covalently bound. Autoradiographs of brain high-speed supernatant proteins after their electrophoretic separation on sodium dodecyl sulphate/polyacrylamide gels showed that [³H]bromocolchicine reacted with four proteins, of which tubulin was one.Labelling of two of these proteins could be prevented by pretreatment of the brain extracts with α-bromoacetic acid, after which 70% of the covalently bound label was specifically located in the tubulin band. Up to 1.6 mol of affinity label could be bound per mol of tubulin, while under our experimental conditions 1 mol of protein bound irreversibly only 0.2 mol of [³H]colchicine. Autoradiography of sodium dodecyl sulphate/urea-polyacrylamide gels, which separate the subunits of tubulin, showed about 30% [³H] bromocolchicine bound to the α-subunit of tubulin and 70% to tho β-subunit.The irreversible binding site of colchicine was localized to the α-subunit, as labelling of only this subunit was inhibited by colchicine at high affinity label concentrations. At lower concentrations, colchicine inhibited the labelling of both subunits.Bromoacetic acid did not inhibit the reaction of the affinity label with the tubulin subunits, but increased the inhibition of [³H]bromocolchicine binding at lower concentrations of the affinity label in brain extracts preincubated with cold colchicine. This is interpreted to show a conformational change which takes place in the two subunits of tubulin upon binding of colchicine and results in the exposure of some of the binding sites of [³H]bromocolchicine to bromoacetic acid.     

THE MECHANISM OF ACTION OF COLCHICINE : Colchicine Binding Properties of Sea Urchin Sperm Tail Outer Doublet Tubulin

The thermal depolymerization procedure of Stephens (1970. J. Mol. Biol. 47:353) has been employed for solubilization of Strongylocentrotus purpuratus sperm tail outer doublet microtubules with the use of a buffer during solubilization which is of optimal pH and ionic strength for the preservation of colchicine binding activity of chick embryo brain tubulin. Colchicine binding values were corrected for first-order decay during heat solubilization at 50°C (t_½ = 5.4 min) and incubation with colchicine at 37°C in the presence of vinblastine sulfate (t_½ = 485 min). The colchicine binding properties of heat-solubilized outer doublet tubulin were qualitatively identical with those of other soluble forms of tubulin. The solubilized tubulin (mol wt, 115,000) bound 0.9 ± 0.2 mol of colchicine per mol of tubulin, with a binding constant of 6.3 x 10⁵ liters/mol at 37°C. The colchicine binding reaction was both time and temperature dependent, and the binding of colchicine was prevented in a competitive manner by podophyllotoxin (K_i = 1.3 x 10^-6 M). The first-order decay of colchicine binding activity was substantially decreased by the addition of the vinca alkaloids, vinblastine sulfate or vincristine sulfate, thus demonstrating the presence of a vinca alkaloid binding site(s) on the outer doublet tubulin. Tubulin contained within the assembled microtubules did not decay. Intact outer doublet microtubules bound less than 0.001 mol of colchicine per mol of tubulin contained in the microtubules, under conditions where soluble tubulin would have bound 1 mol of colchicine per mol of tubulin (saturating concentration of colchicine, no decay of colchicine binding activity). The presence of colchicine had no effect on the rate of solubilization of outer doublet microtubules during incubation at 37°C. Therefore, the colchicine binding site on tubulin is blocked (not available to bind colchicine) when the tubulin is in the assembled outer doublet microtubules.     

Resistance of Rosa microtubule polymerization to colchicine results from a low-affinity interaction of colchicine and tubulin

The inhibition of the polymerization of tubulin from cultured cells of rose (Rosa. sp. cv. Paul's scarlet) by colchicine and the binding of colchicine to tubulin were examined in vitro and compared with data obtained in parallel experiments with bovine brain tubulin. Turbidimetric measurements of taxol-induced polymerization of rose microtubules were found to be sensitive and semiquantitative at low tubulin concentrations, and to conform to some of the characteristics of a nucleation and condensation-polymerization mechanism for assembly of filamentous helical polymers. Colchicine inhibited the rapid phase of polymerization at 24°C with an apparent inhibition constant (K _i) of 1.4·10^-4 M for rose tubulin and an apparent K _i=8.8·10^-7 M for brain tubulin. The binding of [³H]colchicine to rose tubulin to form tubulin-colchicine complex was mildly temperature-dependent and slow, taking 2–3 h to reach equilibrium at 24°C, and was not affected by vinblastine sulfate. The binding of [³H]colchicine to rose tubulin was saturable and Scatchard analysis indicated a single class of low-affinity binding sites having an apparent affinity constant (K) of 9.7·10² M^-1 and an estimated molar binding stoichiometry (r) of 0.47 at 24°C. The values for brain tubulin were K=2.46·10⁶ M^-1 and r=0.45 at 37°C. The binding of [³H]colchicine to rose tubulin was inhibited by excess unlabeled colchicine, but not by podophyllotoxin or tropolone. The data demonstrate divergence of the colchicine-binding sites on plant and animal tubulins and indicate that the relative resistance of plant microtubule polymerization to colchicine results from a low-affinity interaction of colchicine and tubulin.Abbreviations MT microtubule - TC tubulin-colchicine complex     

Human lymphocyte tubulin: Purification and characterization in normal and leukemic cells

Tubulin has been purified from human blood and tonsil lymphocytes. Using gel filtration, the molecular weight of human lymphocyte tubulin was estimated to be 119 000. The proteins was shown to consist of two subunits, with molecular weights of 61 000 and 58 000 comparable to the α and β polypeptides of human brain tubulin. A partial identity reaction was observed between lymphocyte tubulin and human tubulin when tested by double immunodiffusion against a rabbit anti-human brain tubulin antibody. In the presence of GTP, the purified protein polymerized to form microtubules. Tubulin was localized to the cell's juxtacentriolar region by immunofluorescence and electron microscopy. When assayed by a colchicine-binding assay corrected for time decay, the binding affinity was 1.50 ± 0.86 · 10⁶M^?1 and a level in normal lymphocytes of 1.21 · 10^?2 ± 0.79 g/g of soluble protein was determined. Since chronic lymphocytic leukemia lymphocytes have an anomalous capping behavior as well as an unusual susceptibility to colchicine toxicity, the properties and levels of tubulin were determined in these cells. Similar values were obtained for the level, decay rate, molecular weight, and K_a for colchicine as for normal lymphocytes. Chronic lymphocytic leukemia lymphocyte tubulin polymerized in a normal fashion. It thus appears that a decrease in the quantity or function of tubulin does not account for these anomalies in the chronic lymphocytic leukemia lymphocyte.     

Polymerization of tubulin in the presence of colchicine or podophyllotoxin. Formation of a ribbon structure induced by guanylyl-5'-methylene diphosphonate

GTP-dependent in vitro polymerization of rat brain microtubular protein is inhibited to 50% by substoichiometric concentrations of the antimitotic drugs colchicine (0.12 mol/mol of tubulin) and podophyllotoxin (0.14 mol/mol of tubulin). Substitution of pp(CH₂)pG² for GTP, however, results in an extensive microtubular protein polymerization at such concentrations. In the presence of pp(CH₂)pG, suprastoichiometric concentrations of podophyllotoxin (19 mol/mol of tubulin) are required to inhibit the polymerization process by 50%. Colchicine is very ineffective since 3 × 10⁵ moles/mole of tubulin are required to give a 50% inhibition. Electron microscopical analysis shows that the polymers formed by microtubular protein in the presence of suprastoichiometric concentrations of drugs are not the normal short microtubules typical of pp(CH₂)pG-driven polymerization, but are ribbons with three or four protofilaments. The colchicine content of the harvested ribbons has been measured directly and found to be approximately 0.8 moles colchicine/mole of tubulin. Treatment of microtubular protein with substoichiometric concentrations of drugs results in an increase in the number of protofilaments forming the ribbons. Many of the ribbons can close into morphologically normal microtubules when microtubular protein is treated with only 0.05 moles of either colchicine or podophyllotoxin per mole of tubulin.     

Glutamine synthetase cascade: enrichment of uridylyltransferase in Escherichia coli carrying hybrid ColE1 plasmids

Colchicine-binding properties of the total cytoplasmic pool of tubulin from rat liver were evaluated in tubulin-stabilizing (TS) supernates. Microtubules were separated from free tubulin using a microtubule-stabilizing solution (MTS) and ultracentrifugation. [³H]Colchicine-binding properties of microtubule-derived tubulin were investigated in supernates prepared after resuspension of MTS pellets in TS. In TS buffer at 37 °C the colchicine-binding activity of the total cytoplasmic pool of tubulin decayed with $\text{T}\text{1}\text{2}$ of 3.39 h. Resuspended pellet tubulin decayed much more rapidly under the same conditions with a $\text{T}\text{1}\text{2}$ of 0.72 h. This rapid time decay of microtubule-derived tubulin was found to be at least partially attributable to prior microtubule-stabilizing solution exposure. Since tartrate has been reported to increase the rate of colchicine binding to tubulin, sodium tartrate (150 mm) was added to our colchicine-binding system. This addition increased the detectable [³H]colchicine binding by 10% in the total cytoplasmic preparation and by 85% in the resuspended pellet preparation. Addition of tartrate (150 mm) also resulted in a 105% increase in the $\text{T}\text{1}\text{2}$ for total cytoplasmic tubulin and a 412% increase for microtubule derived tubulin. Total cytoplasmic supernates of liver bound [³H]colchicine linearly over a wide range of tissue concentrations. However, resuspended microtubule-stabilizing solution pellet supernates in tubulin-stabilizing solution showed some increase in colchicine binding per tissue weight in the more dilute samples. Our data which demonstrate differences in colchicine-binding properties for total cytoplasmic and microtubule-derived pools of tubulin suggest that present assays for hepatic tubulin polymerization which assume identical binding properties should be interpreted with caution.     

The binding of vincristine, vinblastine and colchicine to tubulin

Preparations of tubulin were examined for their ability to bind vincristine, vinblastine, and colchicine, as measured by adsorption on DEAE impregnated filter paper. Vincristine and vinblastine were found to bind very rapidly with tubulin (<5 min), while colchicine took considerably longer (>4 hr). When varying concentrations of the alkaloids were employed, and the data examined on a Scatchard plot, it was found that colchicine had an association constant of 1.8 × 10⁶ liters/mole, while vinblastine and vincristine had constants of 6.0 × 10⁶ liters/mole and 8.0 × 10⁶ liters/mole respectively. In addition, it was found that the ratio of molar binding of colchicine was always twice that of vinblastine or vincristine.     

In vitro assembly of microtubule proteins from myxamoebae of Physarum polycephalum

Microtubule protein of >95% purity has been isolated by self-assembly from concentrated cell extracts of myxamoebae of Physarum polycephalum. Ninety-eight percent of the amoebal microtubule protein was tubulin. Both a and β subunits of amoebal tubulin were different from neurotubulin α and β subunits, but very similar to those of Tetrahymena ciliary tubulin. The non-tubulin components, which co-purified with tubulin through three assembly cycles, were essential to microtubule formation and contained several polypeptides including some of apparent molecular weights 49000, 57000 and 59000. Purified amoebal microtubule protein formed microtubules on warming in the absence of glycerol which were cold- and Ca²⁺-labile. In vitro, microtubule assembly was inhibited by vinblastine, benzimidazole derivatives and griseofulvin, but not by 10^?4 M colchicine. Amoebal tubulin had a much lower affinity than neurotubulin for colchicine.     

Tubulin and microtubules from bovine kidney: purification, properties, and characterization of ligand binding.

Tubulin was purified from bovine renal medulla by in vitro assembly of microtubules in the presence of dimethyl sulfoxide and glycerol. Light scattering measurements of the polymerization process demonstrate that dimethyl sulfoxide and glycerol decrease the critical concentration of tubulin required for polymerization. The minimum concentration of tubulin from bovine renal medulla is about 1% of the total soluble protein. Assembly occurs in the absence of detectable amounts of high-molecular weight proteins or τ-protein. Microtubules polymerized in the absence and presence of 10% dimethyl sulfoxide and 4 m glycerol are similar morphologically as detected by electron microscopy. Molecular weights of α- and β-tubulin from bovine renal medulla are 54,000 ± 700 and 52,000 ± 800, respectively, as determined by electrophoresis on polyacrylamide gels in the presence of sodium dodecyl sulfate. Colchicine-binding activity of renal medullary tubulin decays in an apparent first-order process which is temperature dependent. The half-time of decay in buffer is 5.1 h and addition of 5 μm vinblastine sulfate increases the half-time of decay to 10.9 h at 37 °C. Calculations based on measurements of the rate of decay of colchicine-binding activity at different temperatures indicates that vinblastine sulfate stabilizes the binding activity by decreasing the entropy of activation of the decay process. Colchicine decreases the rate of decay about 3.5-fold both in the absence and presence of vinblastine sulfate at 37 °C. Values of the apparent colchicine-binding constant, K_A, of bovine renal medullary tubulin are 5.9 × 10⁶ and 7.8 × 10⁶m^?1 at 37 °C in the absence and presence of vinblastine sulfate. Vinblastine sulfate decreases the rate of decay and increases the apparent binding constant of colchicine binding. Lumicolchicine does not affect the binding of colchicine. Podophyllotoxin apparently competitively inhibits the binding of colchicine; the apparent K_i for podophyllotoxin is 4.0 × 10^?7m at 37 °C. Thus, tubulin from bovine renal medulla has ligand-binding characteristics which exhibit differences and similarities to the corresponding characteristics of the brain tubulin. These biochemical properties of the colchicine-binding activity of bovine renal medullary tubulin support previous physiologic studies which demonstrate that microtubules are required for the function of vasopressin in mammalian kidneys.     

Microtubule proteins in axolotl eggs and developing embryos

Tubulin from eggs and embryos of the Mexican axolotl was characterized by electrophoresis and colchicine binding. In urea-polyacrylamide gel electrophoresis, soluble axolotl egg tubulin migrated as two bands, identical to tubulins from sea urchin sperm and Drosophila eggs. However, in SDS-containing gels, on which the α and β subunits of standard tubulins were well resolved, axolotl egg tubulin migrated as a single band with an apparent molecular weight of 53,500. The method of disruption of the eggs affected both yield of tubulin from vinblastine sulfate precipitates and stability of the colchicine binding activity. The colchicine binding activity of soluble tubulin from gently disrupted eggs was specific and of high affinity, with properties similar to those reported for other tubulins. The tubulin pool in unfertilized eggs was determined to be approximately 2 μg/egg; the level decreased 20% after initiation of cleavage and then remained constant through development to postneurula stages. The colchicine binding activity of soluble tubulin from embryos was much less stable than that of unfertilized eggs and decreased further during development. No differences were found in properties of tubulin from eggs of several strains of normally pigmented axolotls; however, tubulin from albino eggs showed slightly different properties in both electrophoresis and colchicine binding. The colchicine binding activity of soluble tubulin accounts for only half the total activity in axolotl eggs; they possess, in addition, a particulate nontubulin colchicine binding activity.     

Characterization of a colchicine receptor protein in rat epididymal adipose tissue

Colchicine was found to be taken up by adipose tissue and therein to bind to a soluble macromolecule not sedimented by centrifugation for 2 h at 100 000 × g. A similar binding occurred when soluble extracts of adipose tissue were incubated with colchicine. The binding reaction is temperature dependent and shows a pH optimum between 6.8 and 7.0. Double reciprocal plots of colchicine concentration versus amounts of colchicine bound to protein in the steady state disclosed an apparent Km of 0.250 to 1.5 ωM. The colchicine binding activity of soluble tissue extracts decreased when the extracts were incubated at 37°C. Addition of guanosine triphosphate and Mg²⁺ retarded the loss of colchicine binding activity. The molecular weight of the colchicine complex was estimated to be 115 000 and its sedimentation coefficient 5.8 S. All of these characteristics are remarkably similar to those of the protein tubulin which has been isolated from other tissues. Since it is now well known that tubulin is a protein subunit of cytoplasmic microtubules, it is suggested that the previously reported metabolic effects of colchicine on adipose tissue result from the dissolution of microtubules by colchicine.     

Purification and characterization of tubulin from mung bean (Vigna radiata)

Tubulin has been purified from mung bean seedling by Zn²⁺-induced polymerization. Both α- and β-subunits of mung bean tubulin are different from those of brain tubulin in electrophoretic mobility, colchicine binding and peptide map. Heterogeneity of mung bean tubulin has also been documented suggesting diversification of tubulin despite its conserved nature in general.     

Synthesis and Turnover of Embryonic Sea Urchin Ciliary Proteins during Selective Inhibition of Tubulin Synthesis and Assembly

When ciliogenesis first occurs in sea urchin embryos, the major building block proteins, tubulin and dynein, exist in substantial pools, but most 9+2 architectural proteins must be synthesized de novo. Pulse-chase labeling with [³H]leucine demonstrates that these proteins are coordinately up-regulated in response to deciliation so that regeneration ensues and the tubulin and dynein pools are replenished. Protein labeling and incorporation into already-assembled cilia is high, indicating constitutive ciliary gene expression and steady-state turnover. To determine whether either the synthesis of tubulin or the size of its available pool is coupled to the synthesis or turnover of the other 9+2 proteins in some feedback manner, fully-ciliated mid- or late-gastrula stage Strongylocentrotus droebachiensis embryos were pulse labeled in the presence of colchicine or taxol at concentrations that block ciliary growth. As a consequence of tubulin autoregulation mediated by increased free tubulin, no labeling of ciliary tubulin occurred in colchicine-treated embryos. However, most other proteins were labeled and incorporated into steady-state cilia at near-control levels in the presence of colchicine or taxol. With taxol, tubulin was labeled as well. An axoneme-associated 78 kDa cognate of the molecular chaperone HSP70 correlated with length during regeneration; neither colchicine nor taxol influenced the association of this protein in steady-state cilia. These data indicate that 1) ciliary protein synthesis and turnover is independent of tubulin synthesis or tubulin pool size; 2) steady-state incorporation of labeled proteins cannot be due to formation or elongation of cilia; 3) substantial tubulin exchange takes place in fully-motile cilia; and 4) chaperone presence and association in steady-state cilia is independent of background ciliogenesis, tubulin synthesis, and tubulin assembly state.     

发育中小鼠和鸡胚脑微管蛋白的合成与甲状腺功能间的关系

利用 ³H-秋水仙碱与微管蛋白间的特异结合及DEAE纤维素对微管蛋白的离子交换作用,连续测定小鼠、鸡胚脑发育过程中的脑微管蛋白的合成变化。结果表明脑微管蛋白的合成速度均在其脑发育的临界期时达到最高峰。此时恰是甲状腺功能逐渐完善的时期。当小鼠进入育龄期时,雌雄鼠脑微管蛋白含量差异显著。可能说明性激素对微管蛋白的合成有重要影响。     

Hydropathic analysis and biological evaluation of stilbene derivatives as colchicine site microtubule inhibitors with anti-leukemic activity

The crucial role of the microtubule in cell division has identified tubulin as a target for the development of therapeutics for cancer; in particular, tubulin is a target for antineoplastic agents that act by interfering with the dynamic stability of microtubules. A molecular modeling study was carried out to accurately represent the complex structure and the binding mode of a new class of stilbene-based tubulin inhibitors that bind at the αβ-tubulin colchicine site. Computational docking along with HINT (Hydropathic INTeractions) score analysis fitted these inhibitors into the colchicine site and revealed detailed structure–activity information useful for inhibitor design. Quantitative analysis of the results was in good agreement with the in vitro antiproliferative activity of these derivatives (ranging from 3?nM to 100?μM) such that calculated and measured free energies of binding correlate with an r² of 0.89 (standard error ± 0.85?kcal mol^?1). This correlation suggests that the activity of unknown compounds may be predicted.     

Fluorescent deacetylcolchicine: New aspects of its activity and localization in PtK-1 cells

PtK-1 cells have been used to localize structures which are decorated by deacetylcolchicine conjugated with fluorescein isothiocyanate (FDC). This colchicine derivative competitively inhibits [³H]colchicine binding to soluble tubulin, is able to depolymerize microtubules (MTs) assembled in vitro, and inhibits cell growth by arresting colchicine-sensitive cells in mitosis. Fixed cells were incubated with FDC (10^?5 M), and/or with tetramethyl rhodamine-labelled anti-tubulin antibodies using the indirect immunofluorescence technique. In double label microscopy the cells show corresponding fluorescence of MTs after incubation with anti-tubulin antibodies and FDC. This can be demonstrated most clearly with cells in mitosis which are preincubated with the microtubule-stabilizing agent taxol. FDC binding is decreased, but not completely blocked, by preincubation of fixed cells with unlabelled colchicine (10^?4 M). Trimethyl colchicinic acid (TMCA) conjugated with FITC, a colchicine derivative which does not bind to soluble tubulin, and FITC alone, inactivated by methylamine, do not bind to MTs. These results demonstrate that FDC is able to decorate and to depolymerize sensitive MTs, indicating a direct action of the drug on these structures. Furthermore, the labelling of other cellular structures by FDC, possibly membrane systems as well as chromatin, is compared with recent data.     

Surface biochemical changes accompanying primary infection with Rous sarcoma virus. I. Electrokinetic properties of cells and cell surface glycoprotein:glycosyl transferase activities

A special class of polysomes synthesizing tubulin was determined using embryos of the sea urchin, Hemicentrotus pulcherrimus. Three criteria were established for identification of polysomes carrying nascent tubulin, i.e., nascent tubulin on polysomes should have (i) colchicine binding activity, (ii) precipitability with vinblastine and (iii) coincidence in mobility by electrophoresis with tubulin. Two classes of polysomes had polypeptides which accorded with the three criteria. One was tetramers and the other was composed of 15–20 ribosomes. From data reported previously on the molecular weight and amino acid composition of completed microtubule proteins, it was suggested that the class of polysomes composed of 15–20 ribosomes constituted the polysome-synthesizing tubulin of sea urchin embryos. The nature of the nascent polypeptides carried by the tetramer polysomes having colchicine binding activity and precipitability with vinblastine could not be clarified.