Posttranslational modifications of tubulin in cultured mouse brain neurons and astroglia

Posttranslational modifications of tubulin were analyzed in mouse brain neurons and glia developing in culture. Purified tubulin was resolved by isoelectric focusing. After 3 weeks of culture, neurons were shown to express a high degree of tubulin heterogeneity (8 alpha and 10 beta isoforms), similar to that found in the brain at the same developmental stage. Astroglial tubulin exhibits a less complex pattern consisting of 4 alpha and 4 beta isoforms. After incubation of neuronal and glial cells with 3H-acetate in the presence of cycloheximide, a major posttranslational label was found associated with alpha-tubulin and a minor one with beta-tubulin. The acetate-labeled isotubulins of neurons were resolved by isoelectric focusing into as many as 6 alpha and 7 beta isoforms, while those of astroglia were resolved into only 2 alpha and 2 beta isoforms. The same alpha isoforms were also shown to react with a monoclonal antibody recognizing selectively the acetylated form(s) of alpha-tubulin. Whether acetate-labeling of alpha-tubulin in these cells corresponds to the acetylation of Lys40, as reported for Chlamydomonas reinhardtii, is discussed according to very recent data obtained by protein sequence analysis. Tubulin phosphorylation was analyzed by incubation of cell cultures with 32PO4. No phosphorylation of alpha-tubulin isoforms was detected. A single beta-tubulin isoform (beta'2), expressed only in neurons, was found to be phosphorylated. This isoform is similar to that previously identified in differentiated mouse neuroblastoma cells.     

Adriamycin promotes neurite outgrowth in the "neurite-minus" N1A-103 mouse neuroblastoma cell line.

Adriamycin, an anticancer agent acting on topoisomerase II, promotes the arrest of cell division and neurite extension in a "neurite-minus" murine neuroblastoma cell line, N1A-103. This morphological differentiation is accompanied by a blockade in the S phase of the cell cycle, modification of the amount of peripherin, and appearance of the beta 7-tubulin isoform. Yet, adriamycin-induced N1A-103 cells fail to express other neuronal markers, such as long-lasting Ca2+ channels, synaptophysin, and the shift in the proportion of the beta'1 tubulin isoform to the beta'2 isoform, whose appearance parallels the terminal differentiation of the wild type neuroblastoma cell line N1E-115. Hence, a comparison of the behavior of these two cell lines leads to the proposal that there are two programs of neuroblastoma differentiation: one where expression is triggered by the arrest of cell division and which is observed in adriamycin-induced N1A-103 variant cells, and the other, presumably occurring further downstream, which would involve further changes in morphogenesis and acquisition of new electrophysiological properties.     

Microheterogeneity of tubulin proteins in neuronal and glial cells from the mouse brain in culture

The microheterogeneity of the alpha and beta isoforms of tubulin in brain cells in culture was studied. The cells were prepared from two precise regions of the embryonic mouse brain (ED15), the striatum and the mesencephalon. It was possible to maintain virtually pure cultures of neuronal or glial cells up to 1 and 4 weeks in vitro, respectively. The tubulin heterogeneity of striatal and mesencephalic neurons was found to be very similar after a few days in culture. More precise examination of pure neurons from the striatum revealed that their tubulin content after 7 days in vitro exhibited the same degree of complexity as a control extract from a 4 day-old mouse brain. In fact, we could detect the presence of at least six alpha and nine beta tubulin isoforms. Among these isoforms a specific family of beta proteins (beta' tubulin) and the more acidic alpha proteins were present. Since these isoforms have, up to now, been found only in tubulin extracts prepared from the nervous system, our experiments suggest that they belong to the neuronal subpopulation of this tissue. This point is reinforced by their complete absence from the tubulin proteins extracted from pure glial cells even after several weeks in vitro. These results lead us to propose that brain tubulin microheterogeneity is associated with the presence of neurons and not of glia and may, therefore, play a specific role in maintaining neuronal shape and function.     

A polymer-dependent increase in phosphorylation of beta-tubulin accompanies differentiation of a mouse neuroblastoma cell line

We have examined the phosphorylation of cellular microtubule proteins during differentiation and neurite outgrowth in N115 mouse neuroblastoma cells. N115 differentiation, induced by serum withdrawal, is accompanied by a fourfold increase in phosphorylation of a 54,000-mol-wt protein identified as a specific isoform of beta-tubulin by SDS PAGE, two-dimensional isoelectric focusing/SDS PAGE, and immunoprecipitation with a specific monoclonal antiserum. Isoelectric focusing/SDS PAGE of [35S]methionine-labeled cell extracts revealed that the phosphorylated isoform of beta-tubulin, termed beta 2, is one of three isoforms detected in differentiated N115 cells, and is diminished in amounts in the undifferentiated cells. Taxol, a drug which promotes microtubule assembly, stimulates phosphorylation of beta-tubulin in both differentiated and undifferentiated N115 cells. In contrast, treatment of differentiated cells with either colcemid or nocodazole causes a rapid decrease in beta-tubulin phosphorylation. Thus, the phosphorylation of beta-tubulin in N115 cells is coupled to the levels of cellular microtubules. The observed increase in beta-tubulin phosphorylation during differentiation then reflects developmental regulation of microtubule assembly during neurite outgrowth, rather than developmental regulation of a tubulin kinase activity.     

Developmental regulation of type II calcium/calmodulin-dependent kinase isoforms in rat cerebellum

Two distinct isoforms of a Type II calcium/calmodulin-dependent protein kinase were separated from high-speed supernates (cytosol) of rat neonatal [postnatal day 10 (P10)] and adult [postnatal day 40 (P40)] cerebellum using cation-exchange chromatography. The isoenzymes contained variable amounts of three subunits of apparent Mr's of 50 kDa (alpha), 58 kDa (beta'), and 60 kDa (beta). The specific activity of calmodulin-dependent kinase (CaM kinase II) in crude homogenates increased sixfold between P10 and P40 using exogenous MAP 2 as substrate. Cytosol from cerebellum at P40 contained a predominant isoform (approximately 40% of total cytosolic activity) with a 1:5 molar ratio of alpha:beta',beta subunits that eluted with 150 mM NaCl (designated 150) and a less abundant isoform (approximately 20% of total cytosolic activity) containing a 1:8 molar ratio of alpha:beta',beta subunits that eluted with 350 mM NaCl (designated 350). In neonatal cerebellum at P10, the relative abundance of the two isoforms was reversed such that approximately 50% of the cytosolic calmodulin-dependent kinase activity was recovered in the 350 isoform, whereas only 20% of the total cytosolic kinase activity was recovered in the 150 isoform. Previous studies indicate that cerebellar granule cells may contain an all beta',beta isoform of CaM kinase II that lacks alpha subunit. Thus, to assess the cell-specific localization of kinase isoforms within cerebellum, cytosol prepared from primary cultures of rat cerebellar granule cells was applied to cation-exchange chromatography and analyzed for calmodulin-dependent kinase activity. The cells contained both isoforms of the kinase that were present in fresh tissue suggesting that granule cell-enriched cultures express all three kinase subunits. The data demonstrate that rat cerebellum contains unique mixtures of CaM kinase II isoenzymes and that their expression is developmentally regulated.     

Metabolism of two Go alpha isoforms in neuronal cells during differentiation

We have previously shown that undifferentiated N1E-115 neuroblastoma cells express only one isoform of Go alpha (pI = 5.8), whereas differentiated neuroblastoma cells expressed, in addition to this isoform, another Go alpha with a more acidic pI (5.55). Moreover, primary cultures of cerebellar granule cells, which are extremely well differentiated cells yielding a high density of synapses, expressed only a single Go alpha isoform with a pI of 5.55 (Brabet, P., Pantaloni, C., Rodriguez Martinez, J., Bockaert, J., and Homburger, V. (1990) J. Neurochem. 54, 1310-1320). In this report, using biosynthetic labeling with [35S]methionine and specific quantitative immunoprecipitation with a polyclonal antibody raised against the purified Go alpha protein, we have determined 1) the degradation rate of total Go alpha (sum of the two isoforms) in differentiated as well as in undifferentiated neuroblastoma cells and in cerebellar granule cells, 2) the degradation rates of each isoform in differentiated neuroblastoma cells. The t 1/2 for total Go alpha protein degradation was very different in the three neuronal cell populations and was 28 +/- 5 h (n = 5), 58 +/- 9 h (n = 5), and 154 +/- 22 h (n = 6) in undifferentiated, differentiated neuroblastoma, and granule cells, respectively. Using two-dimensional gel analysis of immunoprecipitates, we have also determined the individual t 1/2 for degradation of each Go alpha isoform in differentiated neuroblastoma cells, in which the two Go alpha isoforms were expressed. Results indicated that the two Go alpha isoforms exhibit similar t1/2 for degradation (49 +/- 5 h, n = 3). Thus, the t1/2 for degradation of the more basic Go alpha isoform is higher in differentiated neuroblastoma cells (49 +/- 5 h, n = 3) than in undifferentiated neuroblastoma cells (28 +/- 5 h, n = 5) which expressed only the more basic Go alpha isoform. It can be concluded that the degradation rate of the more basic Go alpha isoform is not a characteristic of the protein itself but depends on the state of the cell differentiation. The comparison between the t1/2 for degradation of the more acidic Go alpha isoform is differentiated neuroblastoma cells (51 +/- 6 h, n = 3) with that of cerebellar granule cells (154 +/- 22 h, n = 6) suggests that there is also a decrease in the degradation rate of the more acidic Go alpha isoform during differentiation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Androgen-induced up-regulation of tubulin isoforms in neuroblastoma cells

Androgens regulate the physiology of motor neurones both during development and in adult life. In particular, androgens increase the rate of axonal regeneration after axotomy, an effect correlated with the up-regulation of tubulin. In order to determine whether this was the result of a direct hormone action on neurones, we examined the effect of testosterone on microtubular proteins in human neuroblastoma SH-SY5Y cells. Treatment of proliferating SH-SY5Y cells with testosterone resulted in an up-regulation of alpha- and beta-tubulin. By contrast, no change in tubulin was observed either in cells differentiated into a neuronal phenotype by retinoic acid or in adrenal SW13 cells. We also show that an up-regulation of the ubiquitous beta(II)-tubulin and of the neurone-specific beta(III)-tubulin isoforms contributes to the overall increase in tubulin in response to androgen treatment. The increase in tubulin levels following testosterone treatment was abolished by co-incubation with antiandrogens, indicating that this effect is mediated through a classical mechanism of steroid action. The two microtubule-associated proteins, tau and MAP2b, remained unchanged following testosterone exposure. Thus, these results demonstrate that tubulin is a direct neuronal target of androgen regulation and suggest that dysregulation of tubulin expression may contribute to the pathogenesis of some motor neuronopathies.     

Posttranslational modification of brain tubulins from the Antarctic fish Notothenia coriiceps: reduced C-terminal glutamylation correlates with efficient microtubule assembly at low temperature

We have shown previously that the tubulins of Antarctic fish assemble into microtubules efficiently at low temperatures (-2 to +2 degrees C) due to adaptations intrinsic to the tubulin subunits. To determine whether changes in posttranslational glutamylation of the fish tubulins may contribute to cold adaptation of microtubule assembly, we have characterized C-terminal peptides from alpha- and beta-tubulin chains from brains of adult specimens of the Antarctic rockcod Notothenia coriiceps by MALDI-TOF mass spectrometry and by Edman degradation amino acid sequencing. Of the four fish beta-tubulin isotypes, nonglutamylated isoforms were more abundant than glutamylated isoforms. In addition, maximal glutamyl side-chain length was shorter than that observed for mammalian brain beta tubulins. For the nine fish alpha-tubulin isotypes, nonglutamylated isoforms were also generally more abundant than glutamylated isoforms. When glutamylated, however, the maximal side-chain lengths of the fish alpha tubulins were generally longer than those of adult rat brain alpha chains. Thus, Antarctic fish adult brain tubulins are glutamylated differently than mammalian brain tubulins, resulting in a more heterogeneous population of alpha isoforms and a reduction in the number of beta isoforms. By contrast, neonatal rat brain tubulin possesses low levels of glutamylation that are similar to that of the adult fish brain tubulins. We suggest that unique residue substitutions in the primary structures of Antarctic fish tubulin isotypes and quantitative changes in isoform glutamylation act synergistically to adapt microtubule assembly to low temperatures.     

A lineage-restricted and divergent beta-tubulin isoform is essential for the biogenesis, structure and function of blood platelets

BACKGROUND: Mammalian megakaryocytes release blood platelets through a remarkable process of cytoplasmic fragmentation and de novo assembly of a marginal microtubule band. Cell-specific components of this process include the divergent beta-tubulin isoform beta1 that is expressed exclusively, and is the predominant isoform, in platelets and megakaryocytes. The functional significance of this restricted expression, and indeed of the surprisingly large repertoire of metazoan tubulin genes, is unclear. Fungal tubulin isoforms appear to be functionally redundant, and all mammalian beta-tubulins can assemble in a variety of microtubules, whereas selected fly and worm beta-tubulins are essential in spermatogenesis and neurogenesis. To address the essential role of beta1-tubulin in its natural context, we generated mice with targeted gene disruption. RESULTS: beta1-tubulin(-/-) mice have thrombocytopenia resulting from a defect in generating proplatelets, the immediate precursors of blood platelets. Circulating platelets lack the characteristic discoid shape and have defective marginal bands with reduced microtubule coilings. beta1-tubulin(-/-) mice also have a prolonged bleeding time, and their platelets show an attenuated response to thrombin. Two alternative tubulin isoforms, beta2 and beta5, are overexpressed, and the total beta-tubulin content of beta1-tubulin(-/-) megakaryocytes is normal. However, these isoforms assemble much less efficiently into platelet microtubules and are thus unable to compensate completely for the absence of beta1-tubulin. CONCLUSIONS: This is the first genetic study to address the essential functions of a mammalian tubulin isoform in vivo. The results establish a specialized role for beta1-tubulin in platelet synthesis, structure, and function.     

High expression of the gamma5 isoform of G protein in neuroepithelial cells and its replacement of the gamma2 isoform during neuronal differentiation in the rat brain

High concentrations of G proteins, which include multiple isoforms of each subunit, alpha, beta, and gamma, are expressed in the adult brain. In this study, we concentrated attention on changes of these isoforms during embryonic development in the rat brain. Concentrations of gamma2 as well as GoAalpha, GoBalpha, and beta2 were low in early embryogenesis and then increased, whereas expression of gamma5, in contrast, was initially high followed by a drop, with only very low levels observed throughout postnatal development. Among the other isoforms, Gi1alpha, G(s)alpha-short, G12alpha, G13alpha, beta4, gamma3, gamma7, and gamma12 were present in the embryonic brain at low levels, but their levels markedly increased after birth. In contrast, the levels of Gi2alpha, G(s)alpha-long, Gq/11alpha, and beta1 were essentially constant throughout. Immunohistochemical staining of the brain vesicles in the embryos showed gamma5 to be specifically expressed in the proliferative region of the ventricular zone, whereas gamma2 was mainly present in differentiated neuronal cells of the marginal zone. Furthermore, differentiation of P19 mouse embryonal carcinoma cells to neuronal cells with retinoic acid induced the expression of gamma2 and a decrease of gamma5, the major isoform in the undifferentiated state. These results suggest that neuronal differentiation is responsible for the on/off switch of the expression of gamma2 and gamma5 subunits.     

Occurrence of two beta-tubulin isoforms with different polymerizing abilities in L5178Y cells

Mouse lymphoma L5178Y cells express at least two isoforms of beta-tubulin, designated M beta I and M beta II, as revealed by isoelectrofocusing, whereas two independently isolated normal T-cell clones, 3D10 and K23, express only M beta I. M beta II-tubulin is more acidic (pI, 5.10) than M beta I-tubulin (pI, 5.15). L5178Y cells were disrupted under the microtubule-stabilizing conditions, followed by centrifugation to separate fractions containing polymerized and unpolymerized tubulin. We found that a proportion of M beta II to total beta-tubulins is larger in the fraction containing unpolymerized tubulin than in that containing polymerized tubulin. In addition, when tubulin was purified from extracts of L5178Y cells by repeated cycles of polymerization-depolymerization, the M beta II-tubulin isoform was gradually lost during the successive purification steps. The low recovery of M beta II-tubulin was observed, irrespective of the presence or absence of MAPs, and even in the presence of an excess amount of essentially polymerizable porcine brain tubulin. These results indicate that M beta II-tubulin is less able to polymerize than is M beta I-tubulin, both in vivo and in vitro.     

Cytoskeleton changes following differentiation of N1E-115 neuroblastoma cell line

Summary. No systematic approach to detect expression of differentiation-related elements was published so far. The undifferentiated N1E-115 neuroblastoma cell line was switched into a neuronal phenotype by DMSO treatment and used for proteomic experiments. We used two-dimensional gel electrophoresis followed by unambiguous mass spectrometrical identification of proteins to generate a map of cytoskeleton proteins (CPs), i.e., to search for differentiation-related structures. Alpha-actin, actin-like protein 6A, gamma-tubulin complex component 2, tubulin alpha 3/alpha 7, CLIP associating protein 2, B4 integrin interactor homolog were detectable in the undifferentiated cell line exclusively and neuron-specific CPs drebrin and presynaptic density protein 95, actin-related protein 2/3, alpha and beta-centractin, PDZ-domain actin binding protein, actinin alpha 1, profilin II, ezrin, coactosin-like protein, transgelin 2, myosin light polypeptide 6, tubulin alpha 2, 6 and 7, beta tubulin (94% similar with tubulin beta-2), tubulin beta 3, tubulin tyrosine ligase-like protein 1, lamin B1 and keratin 20 were observed in the differentiated cell line only. We herein identified differentiation-related expressional patterns thus providing new evidence for the role of CPs in the process of neuronal differentiation.     

Estrogen regulation of human osteoblast function is determined by the stage of differentiation and the estrogen receptor isoform

Although osteoblasts have been shown to respond to estrogens and express both isoforms of the estrogen receptor (ER alpha and ER beta), the role each isoform plays in osteoblast cell function and differentiation is unknown. The two ER isoforms are known to differentially regulate estrogen-inducible promoter-reporter gene constructs, but their individual effects on endogenous gene expression in osteoblasts have not been reported. We compared the effects of 17 beta-estradiol (E) and tamoxifen (TAM) on gene expression and matrix formation during the differentiation of human osteoblast cell lines stably expressing either ER alpha (hFOB/ER alpha 9) or ER beta (hFOB/ER beta 6). Expression of the appropriate ER isoform in these cells was confirmed by northern and western blotting and the responses to E in the hFOB/ER beta 6 line were abolished by an ER beta-specific inhibitor. The data demonstrate that (1) in both the hFOB/ER cell lines, certain responses to E or TAM (including alkaline phosphatase, IL-6 and IL-11 production) are more pronounced at the late mineralization stage of differentiation compared to earlier stages, (2) E exerted a greater regulation of bone nodule formation and matrix protein/cytokine production in the ER alpha cells than in ER beta cells, and (3) the regulated expression of select genes differed between the ER alpha and ER beta cells. TAM had no effect on nodule formation in either cell line and was a less potent regulator of gene/protein expression than E. Thus, both the ER isoform and the stage of differentiation appear to influence the response of osteoblast cells to E and TAM.     

A PKCbeta isoform mediates phorbol ester-induced activation of Erk1/2 and expression of neuronal differentiation genes in neuroblastoma cells.

Protein kinase C (PKC) activation induces neuronal differentiation of SH-SY5Y neuroblastoma cells. This study examines the role of PKCbeta isoforms in this process. The PKCbeta-specific inhibitor LY379196 had no effect on 12-O-tetradecanoylphorbol 13-acetate (TPA)-induced neurite outgrowth from SH-SY5Y neuroblastoma cells. On the other hand, PKCbeta inhibition suppressed the TPA-stimulated increase in neuropeptide Y mRNA, activation of neuropeptide Y gene promoter elements, and phosphorylation of Erk1/2. The TPA-induced increase in neuropeptide Y expression was also inhibited by the MEK inhibitor PD98059. These data indicate that activation of a PKCbeta isoform, through a pathway involving Erk1/2, leads to increased expression of neuronal differentiation genes in neuroblastoma cells.     

Guanylyl cyclase/PSD-95 interaction: targeting of the nitric oxide-sensitive alpha2beta1 guanylyl cyclase to synaptic membranes

The signaling molecule nitric oxide (NO) exerts most of its effects by the stimulation of the NO-sensitive guanylyl cyclase. Two isoforms of the NO receptor molecule exist: the ubiquitously occurring alpha(1)beta(1) and the alpha(2)beta(1) with a more limited distribution. As the isoforms are functionally indistinguishable, the physiological relevance of these isoforms remained unclear. The neuronal NO synthase has been reported to be associated with PSD-95. Here, we demonstrate the interaction of the so far unnoticed alpha(2)beta(1) isoform with PSD-95 in rat brain as shown by coprecipitation. The interaction is mediated by the alpha(2) C-terminal peptide and the third PDZ domain of PSD-95. As a consequence of the PSD-95 interaction, the so far considered "soluble" alpha(2)beta(1) isoform is recruited to the membrane fraction of synaptosomes, whereas the alpha(1)beta(1) isoform is found in the cytosol. Our results establish the alpha(1)beta(1) as the cytosolic and the alpha(2)beta(1) as the membrane-associated NO-sensitive guanylyl cyclase and suggest the alpha(2)beta(1) isoform as the sensor for the NO formed by the PSD-95-associated neuronal NO synthase.     

Thyroidal regulation of different isoforms of NaKATPase in the primary cultures of neurons derived from fetal rat brain

The developmental profile of the different isoforms of NaKATPase have been investigated using primary cultures of isolated neurons initiated from 17 day old fetal rat brain. Northern blot analysis showed that the expression of three alpha isoforms (alpha(1), alpha(2) and alpha(3)) and two beta isoforms (beta(1) and beta(2)) increased progressively and reached a peak between 12 to 16 days of culture. Comparison of the mRNA levels of these isoforms in the cells maintained in thyroid hormone deficient (TH def) and thyroid hormone supplemented (TH sup) media for 6-12 days, revealed for the first time that in the neurons three alpha and two beta isoforms of NaKATPase are sensitive to TH. Furthermore immunocytochemical staining of these cells with isoform specific NaKATPase antibodies showed that the uniform distribution of alpha(2), alpha(3) and beta(2) isoforms in the neuronal processes require the presence of TH. These results establish neurons as the target cells for the regulation of NaKATPase by TH in the developing brain.