Role of the cytoskeleton in laminin induced mammary gene expression

The differentiation of rat mammary epithelial cells is characterized both by morphologic changes and by the expression of a group of milk protein genes. We have previously shown that by culturing these cells on the basement membrane glycoprotein laminin, the synthesis of the milk proteins, transferrin, alpha-casein, and alpha-lactalbumin is induced. In order to determine if this effect is mediated through the cytoskeleton, we have treated these cells with cytochalasin D and colchicine. Treatment with cytochalasin D or colchicine for 24 h inhibits the accumulation of alpha-casein, transferrin, and alpha-lactalbumin without significant effect on general protein synthesis. Pulse chase studies show that cytochalasin D does not alter the intracellular turnover of alpha-casein or transferrin. Additionally, treatment with cytochalasin D causes an early (within 1 h) increase in secretion of alpha-casein and transferrin suggesting that the actin cytoskeleton provides a meshwork for secretory vesicles. The disruption of this network enhances the secretion of preformed proteins. However, long term (24 h) treatment with cytochalasin D inhibits synthesis of these milk proteins. Northern blot analysis indicates that treatment with cytochalasin D or colchicine inhibits the laminin induced increase in alpha-casein, alpha-lactalbumin, and transferrin mRNAs. These studies indicate that the major effect of the cytoskeleton on laminin induced milk protein gene expression occurs at the level of accumulation of mRNAs for these proteins. We conclude that the expression of laminin induced milk protein gene expression in primary rat mammary cultures depends on the integrity of the actin and microtubule cytoskeleton.     

ON NEUROFILAMENT and NEUROTUBULE PROTEINS FROM HUMAN AUTOPSY TISSUE

Abstract— Neurofilaments and neurotubules are the principal fibers of the mature normal neuron. In this study the protein subunits of these neurofibrils were isolated from human autopsy tissue, and compared by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and by two dimensional peptide maps of the tryptic digest of these proteins labelled with ¹²⁵I. The α and the β monomers of neurotubule are related but distinct in their peptide maps, while the major neurofilament protein subunit (molecular weight, 50,000) is remarkably similar to β tubulin. The neurofilament fraction binds colchicine, but the specificity is not yet determined. Neurotubule and neurofilament are also similar in having minor proteins which coelectrophorese on the gels. These results suggest that neurofilament and neurotubule may share one or more protein subunits.     

The effect of colchicine on the transport of axonal protein in the chicken

1. Small doses (1-10mug) of colchicine injected into the ventral horn of the spinal cord of the chicken caused paralysis in the legs. 2. Colchicine had no effect on the incorporation of leucine into proteins of the spinal cord but markedly decreased the total amount of protein flowing into the axons of the sciatic nerve. 3. This axonal flow of protein proceeded at two rates: a high rate (300mm/day) and a low rate (2mm/day). Although both groups of proteins were affected, the slow transport of protein was more profoundly blocked by colchicine. 4. The results suggest that axonal flow is dependent on the neurotubular system in the axon.     

Major non-histone proteins of bovine lymphocyte chromatin : Identification of tubulin and actin

Bovine lymphocyte chromatin contains a protein capable of binding colchicine suggesting that it is tubulin. Polyacrylamide gel electrophoresis of the chromatin proteins in the presence of sodium dodecyl sulfate (SDS) shows the presence of proteins co-migrating with tubulin and actin respectively. These two proteins are among the major protein constituents of the chromatin.     

Fate of secretory proteins trapped in oocytes of Xenopus laevis by disruption of the cytoskeleton or by imbalanced subunit synthesis

The effects of imbalanced subunit synthesis, temperature, colchicine, and cytochalasin on the secretion from Xenopus laevis oocytes of a variety of avian and mammalian proteins were investigated; these proteins were encoded by microinjected messenger RNA. Cytochalasin and colchicine together severely reduced secretion in a temperature- independent manner, the exact reduction varying among the different proteins. In contrast cytochalasin alone had no effect, whereas colchicine alone caused a smaller, temperature-dependent reduction. The synthesis and subcellular compartmentation of these proteins were unaffected by the drug treatments; however, the proteins did not accumulate in the drug-treated oocytes but were degraded. The rate of degradation of each protein was similar to its rate of exocytosis from untreated oocytes. A similar result was obtained without recourse to drugs by studying the fate of immunoglobulin light chains trapped in oocytes by a deficiency in heavy chain synthesis. These results are discussed in terms of the disruptive effects, as revealed by electron microscopy, of the drug treatments on the cytoskeleton of the oocyte.     

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.     

Multiple drug-resistant human KB carcinoma cells independently selected for high-level resistance to colchicine, adriamycin, or vinblastine show changes in expression of specific proteins

We have established four cell lines derived from the human KB carcinoma cell line which express high-level multiple drug resistance. One of these lines was selected for resistance to colchicine, one was selected for resistance to colchicine in the presence of the tumor promoter, mezerein, one for resistance to vinblastine, and one for resistance to adriamycin. All of these cell lines are cross-resistant to the other selective agents. The development of multidrug resistance in these cultured human carcinoma cells is associated with a limited number of specific protein alterations revealed by high resolution two-dimensional gel electrophoresis and Western blot analysis. These protein alterations in multidrug-resistant lines include the decreased prevalence of members of a family of proteins of molecular mass 70,000 to 80,000 daltons, pI 4.8-5.0, the increased synthesis of a protein of molecular mass 21,000 daltons, pI 5.0, in the colchicine-resistant cell lines only, and the increased expression of a 170,000-dalton protein in membrane preparations from all of the resistant cells. The loss of the 70,000- to 80,000-dalton proteins in the multidrug-resistant lines, which can also be demonstrated by immunoprecipitation of these proteins with specific antisera, is associated with a loss of translatable mRNA for these proteins. These studies suggest that only a limited number of protein changes occur in multidrug-resistant cell lines.     

Drug resistance and membrane alteration in mutants of mammalian cells.

Independent colchicine-resistant (CHR) mutants of Chinese hamster ovary cells displaying reduced permeability to colchicine have been isolated. A distinguishing feature of these membrane-altered mutants is their pleiotropic cross-resistance to a variety of unrelated compounds. Genetic characterization of the CHR lines indicate that colchicine resistance and cross-resistance to other drugs are of a dominant nature in somatic cell hybrids. Revertants of CHR have been isolated which display decreased resistance to colchicine and a corresponding decrease in resistance to other drugs. These results strongly suggest that colchicine resistance and the pleiotropic cross-resistance are the result of the same mutation(s). Biochemical studies indicate that although colchicine is transported into our cells by passive diffusion, no major alterations in the membrane lipids could be detected in mutant cells. However, there appears to be an energy-dependent process in these cells which actively maintains a permeability barrier against colchicine and other drugs. The CHR cells might be altered in this process. A new glycoprotein has been identified in mutant cell membranes which is not present in parental cells, and is greatly reduced in revertant cells. A model for colchicine-resistance is proposed which suggests that certain membrane proteins such as the new glycoprotein of CHR cells, are modulators of membrane fluidity (mmf proteins) whose molecular conformation regulates membrane permeability to a variety of compounds and that the CHR mutants are altered in their mmf proteins. The possible importance of the CHR cells as models for investigating aspects of chemotherapy related to drug resistance is discussed.     

Microtubules and protein secretion in rat lacrimal glands: localization of short-term effects of colchicine on the secretory process

The pathway and kinetics of the secretory protein transport in rat lacrimal exorbital gland have been established by an in vitro time- course radioautographic study of pulse-labeled protein secretion. The colchicine-sensitive steps have been localized by using the drug at various times with respect to the pulse labeling of proteins. Colchicine (10 microM) does not block any step of the secretory protein transport, but when introduced before the pulse it decreases the transfer of labeled proteins from the rough endoplasmic reticulum to the Golgi area, suppressing their temporary accumulation in the Golgi area before any alteration of this organelle is detectable. Moreover, colchicine inhibits protein release only from the secretory granules formed in its presence because the peroxidase discharge is diminished 1 h after colchicine addition, and the secretion of newly synthesized proteins is strongly inhibited only when colchicine is introduced before secretory granule formation. Morphometric studies show that there is a great increase of secondary lysosomes, related to crinophagy, as early as 40-50 min after colchicine is added. However, changes in lysosomal enzymatic activities remained biochemically undetectable. We conclude that: (a) the labile microtubular system does not seem indispensable for protein transport in the rough endoplasmic reticulum-Golgi area but may facilitate this step, perhaps by maintaining the spatial organization of this area; and (b) in the lacrimal gland, colchicine inhibits protein release not by acting on the steps of secretion following the secretory granule formation, but by acting chiefly on the steps preceding secretory granule formation, perhaps by making the secretory granules formed in its presence incapable of discharging their content.     

Photoaffinity Identification of Colchicine-Solubilized Regulatory Subunit from Rat Brain Adenylate Cyclase

Five GTP binding proteins in rat cerebral cortex synaptic membranes were identified by photoaffinity labelling with [3H] or [32P](P3-azido-anilido)-P1-5' GTP (AAGTP). When AAGTP-treated membranes were incubated with colchicine or vinblastine and subsequently washed, a single AAGTP-labelled protein of 42 kD was released into the supernatant. About 30% of the total labelled 42-kD protein was released into supernatants from membranes pretreated with colchicine or vinblastine compared with 15% released from control membranes. The amount of adenylate cyclase regulatory subunit (G unit) remaining in these membranes was assessed with reconstitution studies after inactivating the adenylate cyclase catalytic moiety with N-ethylmaleimide (NEM). Forty to fifty percent of functional G units were lost from membranes treated with colchicine prior to washing. This 40-50% loss of functional G unit after colchicine treatment corresponds to the previously observed 42% loss of NaF and guanylyl-5'-imidodiphosphate [Gpp(NH)p]-activated adenylate cyclase. Release of the AAGTP-labelled 42-kD protein from colchicine-treated synaptic membranes is double that from lumicolchicine-treated membranes. This colchicine-mediated release of 42-kD protein correlates with a doubling of functional G unit released from synaptic membranes after colchicine treatment. These findings suggest multiple populations of the G unit within the synaptic plasma membrane, some of which may interact with cytoskeletal components.     

CILIA REGENERATION IN TETRAHYMENA AND ITS INHIBITION BY COLCHICINE

The cilia of Tetrahymena were amputated by the use of a procedure in which the cells remained viable and regenerated cilia. Deciliated cells were nonmotile, and cilia regeneration was assessed by scoring the percentage of motile cells at intervals following deciliation. After a 30-min lag, the deciliated cells rapidly recovered motility until more than 90% of the cells were motile at 70 min after amputation. Cycloheximide inhibited both protein synthesis and cilia regeneration. This indicated that cilia formation in Tetrahymena was dependent on protein synthesis after amputation. Conversely, colchicine was found to inhibit cilia regeneration without affecting either RNA or protein synthesis. This observation suggested the action of colchicine to be an interference with the assembly of ciliary subunit proteins. The finding that colchicine binds to microtubule protein subunits isolated from cilia and flagella (13) supports this possibility. The potential of the colchicine-blocked cilia-regenerating system in Tetrahymena for studying the assembly of microtubule protein subunits during cilia formation and for isolating ciliary precursor proteins is discussed.     

Inhibition of cardiac proteolysis by colchicine. Selective effects on degradation of protein subclasses

1. The effect of colchicine (2.5 microM) on cardiac protein turnover was tested with foetal mouse hearts in organ culture. 2. Colchicine had no effect on protein synthesis, but inhibited total protein degradation by 12-18%. Lumicolchicine, which lacks colchicine's ability to disaggregate microtubules, but shares its non-specific effects, did not alter protein degradation. 3. The colchicine-induced inhibition of protein degradation was accompanied by significant changes in cardiac lysosomal enzyme activities and distribution. 4. Colchicine inhibited the degradation of organellar proteins, including mitochondrial cytochromes, more than that of cytosolic proteins. 5. Colchicine decreased the rate of myosin degradation and the rate of proteolysis of the total protein pool to a similar extent. Since the regulation of myosin degradation does not involve lysosomes, this suggests that colchicine affects non-lysosomal as well as lysosomal pathways. 6. Release of branched-chain amino acids from colchicine-treated hearts was disproportionately decreased, suggesting that colchicine increased their metabolism. 7. It is concluded that colchicine, via its actions on microtubules, exerts important inhibitory effects on cardiac proteolysis. Colchicine is especially inhibitory to the degradation of organellar proteins, including mitochondrial cytochromes. Its inhibitory effects may be mediated in part via lysosomal mechanisms, but non-lysosomal mechanisms are probably involved as well.     

Fate of surface proteins of rabbit polymorphonuclear leukocytes during phagocytosis. II. Internalization of proteins

The distribution of surface proteins during phagocytosis by rabbit peritoneal polymorphonuclear leukocytes was studied to determine whether the proteins of the phagocytic vesicles of these differentiated cells were representative of the entire set of plasma membrane proteins. Phagocytosis of bovine serum albumin-diisodecylphthalate emulsion by lactoperoxidase-iodinated rabbit neutrophils was linear over 15-20 min at a rate of 96 microgram oil/min/mg cell protein. This rate was similar to that of unlabeled cells. Incorporation of cell-associated free iodine by endogenous myeloperoxidase during phagocytosis was inhibited by 1 mM cyanide, which had no effect on the rate of particle uptake. The surface of intact neutrophils contained at least 13 iodinated proteins distinguishable by polyacrylamide gel electrophoresis followed by autoradiography. Isolated phagosomes were deficient in six of these proteins. The plasma membrane fraction of these cells was missing five of these same proteins which, however, were enriched in a dense surface fraction (Willinger, M., and F. R. Frankel. J. Cell Biol. 82: 32-44). When experimental conditions were reversed, and the PMNs were labeled after phagocytosis, these five proteins remained on the cell surface, while at least three of the major proteins found on resting cells were depleted. Incubating the cells with colchicine, which has been shown to affect the distribution of some plasma membrane constituents during phagocytosis, had no effect on the distribution of surface proteins in our system. These results indicate that a nonrandom interiorization of lactoperoxidase-labeled surface proteins of polymorphonuclear leukocytes occurs during phagocytosis.     

Insulin release and the microtubular system of the islets of Langerhans. Identification and characterization of tubulin-like protein.

1. Incubation of islets of Langerhans in vitro in the presence of colchicine produced a progressive inhibition of the insulin-secretory response to glucose, which was dependent on the time of incubation. 2. The uptake of [3-H]colchicine by islet cells was a rapid process, equilibrium being reached in less than 30 min. Part of the colchicine taken up was bound to protein material, which was recovered largely in a post-microsomal supernatant fraction prepared from the islets. In contrast with this rapid uptake, the binding of colchicine by islet-cell proteins in intact islets or in islet homogenates was a slow process, and equilibrium was not reached for 60-90 min. After an initial 30 min delay, the time-course of the binding of [3-H]colchicine to islet-cell proteins paralleled that for the inhibitory effect of colchicine on insulin release. 3. Some purification of the colchicine-binding material present in islet homogenates could be achieved by precipitation of the protein with 2mM-CaCl2 (2.8-fold). However, ion-exchange chromatography on DEAE-Sephadex produced a further 27-fold purification on elution with 0.6M-NaCl. 4. Colchicine-binding protein prepared from islets by ion-exchange chromatography showed an intrinsic association constant for colchicine of 1.4muM and an apparent molecular weight on gel filtration of 110000. 5. These results suggest that colchicine-binding protein in islet cells closely resembles tubulin extracted from the other tissues. The delayed effectiveness of colchicine in inhibiting insulin secretion is not due to poor penetration of colchicine into the cells but rather to slow binding of the alkaloid to islet-cell tubulin. It seems likely that, as in other tissues, this binding prevents polymerization of the tubulin into microtubules, and thus interferes with the release process.     

Differential effect of colchicine upon the entry of proteins into myelin and myelin related membranes

Brain slices from 20 day old rats were incubated with radioactive aminoacids in the presence and absence of 500 M colchicine and the appearance of labeled proteins in myelin and in a myelin-like fraction (SN₄ fraction) was measured. In the presence of the inhibitor, the entry of proteolipid proteins was decreased to 55% in myelin and to 45% in SN₄ fraction with reference to control values while the entry of basic proteins and other minor protein components was unaffected in both fractions. The synthesis of proteolipid proteins was not affected by the presence of colchicine; moreover, a slight accumulation of these proteins was observed in microsomes. The results suggest that the microtubular system is involved in the transport of proteolipid proteins from their site of synthesis to their site of deposition and that the various types of myelin proteins follow different transport routes to enter into this special type of membrane.     

BIOCHEMICAL AND IMMUNOLOGICAL CHARACTERIZATION OF ALKALOID-BINDING PROTEINS FROM IMMATURE RAT BRAIN1

Abstract— Vinblastine- and colchicine-binding proteins in the soluble fraction of immature rat brains were characterized and compared. Based upon criteria of Sephadex G-200 chromatography, electrofocusing and immunological reactivity, several separable species of vinblastine-binding protein were isolated. By contrast, these same procedures yielded only one protein band or elution peak to which [¹⁴C]colchicine could be tightly bound. This colchicine-binding protein peak coincided, in part, with one of the protein peaks to which [³H]vinblastine was tightly bound. Rabbit antiserum against soluble brain proteins precipitated by vinblastine sulfate contained antibodies which reacted with colchicine-binding protein. Thus, despite apparent differences in physical properties between the bulk of the vinblastine-binding proteins and the colchicine-binding protein, the vinblastine sulfate-precipitated protein antigens gave rise to antibodies capable of forming an immune complex with colchicine-binding protein.     

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.     

Isolation of Major Proteins from Boar Sperm Plasma Membranes by Preparative Gel Electrophoresis and Localization of a Major Polypeptide Using Specific Monoclonal Antibodies

A preparative procedure using two-dimensional polyacrylamide gel electrophoresis (2-D PAGE) is described for isolating major boar sperm plasma membrane polypeptides (PMPs) in soluble form. Proteins were first separated on 6 mm diameter gels using a pH gradient expanded in the acidic region. The second dimension used 6 mm thick, 10 acrylamide gels. Major proteins identified by Coomassie staining were excised and electroeluted. The procedure was applied to the isolation of a group of proteins in the molecular weight range 40K-50K which comprise a major fraction of the total integral membrane protein in these cells (groups 4 and 5^1,2). Yields of electrophoretically pure soluble polypeptides from these groups were between 0.3 mg-0.5 mg from the processing of 16 gels per week. Electroeluted proteins were also used to elicit monoclonal antibodies tc major proteins. Monoclonal antibodies to the major plasma membrane protein referenced as 4.85 were isolatpd and shown to be specific tc this protein by transblotting precedures. This proteir was primarily localized over the anterior portion of the principal segment of ejaculated sperm by indirect FITC fluorescence microscopy.

The ability to isolate 60–100 mg of plasma membranes per week from the cauda epididymides of boars also permitted developing a procedure for the rapid fractionation of large amounts of detergent sclubilizec plasma membranes by isoelectric focusing in flatbecls of Biogel P200. For the first time, individual proteins of sperm surface proteins can be isolated in large enough amounts to begin detailed biochemical characterization, localization, and functional testing.     

Characterization of a colchicine receptor protein in rat epididymal adipose tissue.

Colchincine 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 x g. A similar binding occurred when soluble extracts of adipose tissue were incubated with colchicine. The binding reaction 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 muM. The colchicine binding activity of soluble tissue extracts decreased when the extracts were incubated at 37 degree C. Addition of guanosine triphosphate and Mg-2+ 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.