Presence of the betaII isotype of tubulin in the nuclei of cultured mesangial cells from rat kidney

Tubulin has generally been considered to be a cytosolic protein whose only function is to form microtubules. This assumption is supported by a great deal of evidence derived from immunohistochemical studies using antibodies directed against whole tubulin or its component polypeptides alpha- and beta-tubulin. We have re-examined the intracellular distribution of tubulin using monoclonal antibodies specific for the betaI, betaII, betaIII, and betaIV isotypes of beta-tubulin. Our test system is the cultured rat kidney mesangial cell. We have found that betaIII is absent from these cells and that beta1 and betaIV are present in microtubules throughout the cytosol. In contrast, betaII is present largely in the nuclei. Immunoblotting of purified nuclear extracts shows that the betaII-reactive antigen co-migrates with beta-tubulin. Extraction of the cytosol and chromatin suggests that betaII is concentrated in the nucleoli and also in a reticulated network in the rest of the nucleoplasm. An antibody to tyrosinated alpha-tubulin shows that alpha is also present in the nucleoli. Treatment of the cells with fluorescent colchicine shows an accumulation of colchicine in the nucleoli. Finally, fluorescently labeled alphabetaII-tubulin dimers, when microinjected into the cells, enter the nuclei and are concentrated in the nucleoli. These results suggest that the betaII isotype of tubulin is present as an alphabetaII dimer in the nuclei of cultured mesangial cells and suggest the possibility that different tubulin isotypes may have specific functions within the cell.     

The betaII isotype of tubulin is present in the cell nuclei of a variety of cancers

Tubulin, the subunit protein of microtubules, has generally been thought to be exclusively a cytoplasmic protein in higher eukaryotes. We have previously shown that cultured rat kidney mesangial cells contain the betaII isotype of tubulin in their nuclei in the form of an alphabetaII dimer [Walss et al., 1999: Cell Motil. Cytoskeleton 42:274-284, 1999]. More recently, we examined a variety of cancerous and non-cancerous cell lines and found betaII in the nuclei of all of the former and only a few of the latter (Walss-Bass et al., 2002: Cell Tissue Res. 308:215-223]. In order to determine if betaII-tubulin occurs in the nuclei of actual cancers as well as in cancer cell lines, we used the immunoperoxidase method to look for nuclear betaII in a variety of tumors excised from 201 patients. We found that 75% of these tumors contain betaII in their nuclei. Distribution of nuclear betaII was highly dependent on the type of cancer, with 100% of the colon and prostate cancers, but only 19% of the skin tumors, having nuclear betaII. Nuclear betaII was particularly marked in tumors of epithelial origin, of which 83% showed nuclear betaII, in contrast to 54% in tumors of non-epithelial origin. In many cases, betaII staining occurred very strongly in the nuclei and not in the cytoplasm; in other cases, betaII was present in both. In many cases, particularly metastases, otherwise normal cells adjacent to the tumor also showed nuclear betaII, suggesting that cancer cells may influence nearby cells to synthesize betaII and localize it to their nuclei. Our results have implications for the diagnosis, biology, and chemotherapy of cancer.     

Occurrence of nuclear beta(II)-tubulin in cultured cells

Microtubules are cylindrical organelles that play critical roles in cell division. Their subunit protein, tubulin, is a target for various antitumor drugs. Tubulin exists as various forms, known as isotypes. In most normal cells, tubulin occurs only in the cytosol and not in the nucleus. However, we have recently reported the finding of the beta(II) isotype of tubulin in the nuclei of cultured rat kidney mesangial cells. Mesangial cells, unlike most normal cell lines, have the ability to proliferate rapidly in culture. In efforts to determine whether nuclear beta(II)-tubulin occurred in other cell lines, we examined the distribution of the beta(I), beta(II), and beta(IV) mammalian tubulin isotypes in a variety of normal and cancer human cell lines by immunofluorescence microscopy. We have found that, in the normal cell lines, all three isotypes are present only in the cytoplasm. However, the beta(II) isotype of tubulin is located not only in the cytoplasm, but also in the nuclei of the following cell lines: LNCaP prostate carcinoma, MCF-7, MDA-MB-231, MDA-MB-435, and Calc18 breast carcinoma, C6 and T98G glioma, and HeLa cells. In contrast, the beta(I) and beta(IV) isotypes, which are also synthesized in cancer cells, are not localized to the nucleus but are restricted to the cytoplasm. We have also seen beta(II) in breast cancer excisions. In most of these cells, beta(II) appears to be concentrated in the nucleoli. These results suggest that transformation may lead to localization of beta(II)-tubulin in cell nuclei, serving an as yet unknown function, and that nuclear beta(II) may be a useful marker for detection of tumor cells.     

Characterization of nuclear betaII-tubulin in tumor cells: a possible novel target for taxol

As the subunits of microtubules, alpha- and beta-tubulins have been thought to only exist in the cytoplasm where they are incorporated into microtubules. However, the beta(II) isotype of tubulin has recently been observed in the nuclei of rat kidney mesangial cells [Walss et al., 1999: Cell Motil. Cytoskeleton 42:274-284]. In this study, we detected nuclear beta(II)-tubulin in rat C6 glioma cells, human T98G glioma cells, human MCF-7 breast carcinoma cells, human MDA-MB-435 breast carcinoma cells, and human Hela cervix carcinoma cells. In addition, nuclear beta(II)-tubulin in these cells was found to exist as alphabeta(II) dimers instead of assembled microtubules and appeared to be particularly concentrated in the nucleoli. Several anti-tubulin drugs were used to treat C6 cells to determine their influence on nuclear beta(II)-tubulin. Taxol, a tubulin drug with higher specificity for beta(II)-tubulin than for other beta-tubulin isotypes, irreversibly decreased nuclear beta(II) content in a concentration-dependent manner in C6 cells. Meanwhile, cells were found to be apoptotic as was suggested by the presence of multiple micronuclei and DNA fragmentation. On the other hand, no depletion of nuclear beta(II)-tubulin was observed when C6 cells were incubated with colchicine or nocodazole, two anti-tubulin drugs with higher specificity for the alphabeta(IV) isotype, supporting the hypothesis that drugs with higher specificity for beta(II)-tubulin deplete nuclear beta(II)-tubulin.     

daughterless-abo-like, a Drosophila maternal-effect mutation that exhibits abnormal centrosome separation during the late blastoderm divisions

daughterless-abo-like (dal) is a maternal-effect semilethal mutation in Drosophila. The nuclear divisions of embryos derived from homozygous dal females are normal through nuclear cycle 10. However, during nuclear cycles 11, 12 and 13, a total of about half of the nuclei in each embryo either fail to divide or fuse with a neighboring nucleus during telophase. These abnormal nuclei eventually sink into the interior of the embryo, leaving their centrosomes behind on the surface. The loss of about one-half of the peripheral nuclei into the interior of the embryo results in these embryos cellularizing during nuclear cycle 14 with about one-half the normal number of cells. Surprisingly, many of these embryos develop a nearly normal larval cuticle and 8% develop to adulthood. Observations of live embryos doubly injected with tubulin and histones that have been fluorescently labeled allows nuclear and centrosomal behavior to be directly followed as the embryo develops. We find that the abnormal nuclei arise from nuclei whose centrosomes have failed to separate normally in the previous interphase. These incompletely separated centrosomes can cause a non-functional spindle to form, leading to a nuclear division failure. Alternatively, they can form an abnormal spindle with a centrosome from a neighboring nucleus, causing two nuclei to share a common spindle pole. Such nuclei with a shared centrosome will undergo telophase fusions, unequal divisions, or division failures later in mitosis. These findings have helped us to understand the function of the centrosome in the Drosophila embryo.     

Nuclear import of the capsid protein of tomato yellow leaf curl virus (TYLCV) in plant and insect cells

The tomato yellow leaf curl virus (TYLCV) found in Israel is a whitefly-transmitted monopartite geminivirus. Although geminiviruses have been found in the nuclei of phloem-associated cells, the mechanism of viral invasion is poorly understood. The possible role of the TYLCV capsid protein (CP), the only known component of the viral coat, in virus transport into the host cell nucleus was investigated by monitoring its specific nuclear accumulation in plant and insect cells. CP was fused to the β-glucuronidase (GUS) reporter enzyme to assay nuclear import in petunia protoplasts, and micro-injection of purified fluorescently labeled CP was used to examine its nuclear uptake in Drosophila embryos. Both assays demonstrated that TYLCV CP is transported into plant-and insect-cell nuclei by an active process of nuclear import via a nuclear localization signal (NLS)-specific pathway. Using the GUS assay and deletion analysis, the TYLCV CP NLS sequence was identified in the amino-terminus of the protein.     

In situ monitoring of DNA: the plant nuclear envelope allows passage of short DNA fragments

We monitored the cellular localization of fluorescently labeled foreign DNA in living plant cells. After physical delivery of labeled DNA fragments to the cytoplasm, short fragments up to 1.5 kb in length were found equally distributed between the cytoplasm and nucleus after 60 min. In contrast, 2.5 kb DNA fragments did not appear inside the nucleus. Thus, foreign DNA can enter plant nuclei through the intact nuclear envelope, but the efficiency of this process declines with increasing size of fragment.     

Intracellular distribution of a nuclear localization signal binding protein.

The transport of proteins into the nucleus requires the recognition of a nuclear localization signal sequence. Several proteins that interact with these sequences have been identified, including one of about 66 kDa. We have prepared antibodies that recognize the 66-kDa nuclear localization signal binding protein (NLSBP) and inhibit nuclear localization in vitro. By immunofluorescence, it is seen that the NLSBP is predominantly cytoplasmic and is distributed peripherally around the nucleus and the microtubule organizing center. There is also a weak punctate staining of the surface of the nucleus. Methanol-fixed cells can also be stained directly with fluorescently labeled karyophilic proteins. These stains reveal the same cytoplasmic structures as anti-NLSBP. The expression of the NLSBP is growth dependent. When cells grown to confluence are examined, the cytoplasmic staining is greatly reduced, leaving the punctate nuclear staining as the predominant feature. In serum-starved cells, very little staining of either the cytoplasm or the nucleus can be seen. Upon simulation by the addition of serum, the original cytoplasmic and nuclear envelope staining is restored. Cells grown in the presence of colchicine or taxol have an altered NLSBP distribution but apparently normal cytoplasmic nuclear transport.     

Nuclear localization of profilin during the cell cycle in Tradescantia virginiana stamen hair cells

Summary. The localization of the actin-monomer-binding protein profilin during the cell cycle of living Tradescantia virginiana stamen hair cells has been studied by microinjection of a fluorescently labeled analog of the protein. In contrast to previously published studies performed on chemically fixed animal cells, we do not find a specific colocalization of profilin with actin filament arrays. Our results show that, besides a general cytoplasmic distribution, profilin specifically accumulates in the nucleus in interphase and prophase cells. This nuclear localization was confirmed by means of electron microscopic immunolocalization of endogenous profilin (in Gibasis scheldiana stamen hair cells). During mitosis, as the nuclear envelope and nuclear matrix break down at the onset of prometaphase, the nuclear profilin redistributes equally into the accessible volume (cytosol) of the cell. During metaphase and anaphase no specific localization of profilin can be observed associated with the mitotic apparatus. However, during telophase, as nuclear envelopes and nuclear matrices re-form and the sister chromatids start to decondense, a subset of the microinjected profilin again localizes to the nucleus. No accumulation of profilin could be observed in the phragmoplast, where a distinct array of actin filaments exists. The function of profilin in the nucleus remains unclear.Correspondence and reprints: Department of Biology, 221 Morrill Science Center II, University of Massachusetts, Amherst, MA 01003, U.S.A.Received September 30, 2002; accepted February 12, 2003 Published online September 23, 2003     

Identification and characterization of a yeast nucleolar protein that is similar to a rat liver nucleolar protein

We have produced monoclonal antibodies against purified nuclei from the yeast Saccharomyces cerevisiae and have characterized three different antibodies that recognize a protein with an apparent molecular weight of 38,000, termed p38. Subcellular fractionation shows that virtually all of p38 occurs in the nuclear fraction. High concentrations of salt (1 M) or urea (6 M) effectively solubilize p38 from a nuclear envelope fraction prepared by digestion of nuclei with DNase. Indirect immunofluorescence demonstrates a crescent shaped distribution of p38 at the inner periphery of the nucleus, with p38 extending between dividing pairs of cells during (closed) mitosis. Postembedding immunogold electron microscopy shows decoration of the densely stained "crescent" region of the yeast nucleus, confirming the localization of p38 to the nucleolus. One of the monoclonals, D77, cross reacts on immunoblots with a single protein of molecular weight 37,000 from purified rat liver nuclei. Indirect immunofluorescence localizes this protein to the nucleolus, and shows that it is dispersed throughout the cell during mitosis. The yeast and rat liver nucleolar proteins behave similarly when electrophoresed in two dimensions, and appear to have basic pI values. Analysis of immunological cross-reactivity using D77, and antibodies specific for nucleolar proteins from other sources, suggests that the rat liver protein is fibrillarin, and demonstrates that p38 shares epitopes with fibrillarin, as well as with other vertebrate nucleolar proteins.     

Consequences of defective tubulin folding on heterodimer levels, mitosis and spindle morphology in Saccharomyces cerevisiae

In budding yeast, the essential roles of microtubules include segregating chromosomes and positioning the nucleus during mitosis. Defects in these functions can lead to aneuploidy and cell death. To ensure proper mitotic spindle and cytoplasmic microtubule formation, the cell must maintain appropriate stoichiometries of alpha- and beta-tubulin, the basic subunits of microtubules. The experiments described here investigate the minimal levels of tubulin heterodimers needed for mitotic function. We have found a triple-mutant strain, pac10Delta plp1Delta yap4Delta, which has only 20% of wild-type tubulin heterodimer levels due to synthesis and folding defects. The anaphase spindles in these cells are approximately 64% the length of wild-type spindles. The mutant cells are viable and accurately segregate chromosomes in mitosis, but they do have specific defects in mitosis such as abnormal nuclear positioning. The results establish that cells with 20% of wild-type levels of tubulin heterodimers can perform essential cellular functions with a short spindle, but require higher tubulin heterodimer concentrations to attain normal spindle length and prevent mitotic defects.     

Rna1p, a Ran/TC4 GTPase activating protein, is required for nuclear import

The Saccharomyces cerevisiae gene, RNA1, encodes a protein with extensive homology to the mammalian Ran/TC4 GTPase activating protein. Using indirect immunofluorescence microscopy, we have demonstrated that rna1-1 mutant cells are defective in nuclear import of several proteins. The same result is obtained when nuclear import is examined in living cells using a nuclear protein fused to the naturally green fluorescent protein. These findings suggest a role for the Rna1p in trafficking of proteins across the nuclear membrane. To investigate this role more directly, an in vitro import assay that monitors the import of a fluorescently labeled substrate into the nuclei of semi- intact yeast cells was used. Import to the nucleus requires the addition of exogenous cytosol. Results indicate that, in contrast to wild-type cytosols, extracts made from rna1-1 mutant cells are unable to support import of the fluorescently labeled substrate into competent nuclei. Immunoblotting demonstrates that these mutant-derived extracts are depleted of Rna1p. However, when purified Rna1p is added back to these extracts the import activity is restored in a dose-dependent manner. These results demonstrate that Rna1p plays a direct role in the import of proteins into the nucleus.     

Nuclear tubulin of tissue culture cells

Tubulin has been implicated as a nuclear protein because of the role it plays in mitosis. In this paper we examined the role of tubulin in the nuclei of nonmitotic cells. Tubulin was found distributed throughout the nucleus and particularly in association with the chromatin. It comprised about 6.5% of the nonhistone chromosomal proteins. Nuclear tubulin appeared to be nonmicrotubular in form. Fluorescence microscopy data on metaphase chromosomes revealed that tubulin was present on the outside of the chromosomes. These data suggest a structural role for chromatin-associated tubulin.     

Effect of the thermostable protein kinase inhibitor on intracellular localization of the catalytic subunit of cAMP-dependent protein kinase.

cAMP-dependent protein kinase mediates a variety of cellular responses in most eukaryotic cells. Many of these responses are cytoplasmic, whereas others appear to require nuclear localization of the catalytic subunit. In order to understand further the molecular basis for subcellular localization of the catalytic subunit, the effect of the heat stable protein kinase inhibitor (PKI) was investigated. The subcellular localization of the catalytic (C) subunit was determined both in the presence and absence of PKI, by microinjecting fluorescently labeled C subunit into single living cells. When injected alone, a significant fraction of the dissociated C subunit localized to the nucleus. When coin-injected with an excess of PKI, little of the C subunit localized to the nucleus, suggesting that accumulation of catalytic subunit in the nucleus requires either enzymatic activity or a nuclear localization signal. Inactivation of the catalytic subunit in vitro by treatment with N-ethylmaleimide did not prevent localization in the nucleus, indicating that enzymatic activity was not a prerequisite for nuclear localization. In an effort to search for a specific signal that might mediate nuclear localization, a complex of the catalytic subunit with a 20-residue inhibitory peptide derived from PKI (PKI(5-24)) was microinjected. In contrast to intact PKI, the peptide was not sufficient to block nuclear accumulation. In the presence of PKI(5-24), the C subunit localized to the nucleus in a fashion analogous to that of dissociated, active C subunit despite evidence of no catalytic activity in situ. Thus, nuclear localization of the C subunit appears to be independent of enzymatic activity but most likely dependent upon a signal. The signal is apparently masked by both the regulatory subunit and PKI but not by the inhibitory peptide.     

Interaction of the betaIV-tubulin isotype with actin stress fibers in cultured rat kidney mesangial cells.

Microtubules and actin filaments are two of the major components of the cytoskeleton. There is accumulating evidence for interaction between the two networks. Both the alpha- and beta-subunits of tubulin exist as numerous isotypes, some of which have been highly conserved in evolution. In an effort to better understand the functional significance of tubulin isotypes, we used a double immunofluorescence labeling technique to investigate the interactions between the tubulin beta-isotypes and the actin stress fiber network in cultured rat kidney mesangial cells, smooth-muscle-like cells from the renal glomerulus. Removal of the soluble cytoplasmic and nucleoplasmic proteins by detergent extraction caused the microtubule network to disappear while the stress fiber network was still present. In these extracted cells, the betaI- and betaII-tubulin isotypes were no longer present in the cytoplasm while the betaIV-isotype co-localized with actin stress fibers. Co-localization between betaIV-tubulin and actin stress fibers was also observed when the microtubule network was disrupted by the anti-tubulin drug colchicine and also by microinjection of the betaIV-tubulin antibody. Our results suggest that the betaIV isotype of tubulin may be involved in interactions between microtubules and actin.     

Spindle formation in Aspergillus is coupled to tubulin movement into the nucleus

In many important organisms, including many algae and most fungi, the nuclear envelope does not disassemble during mitosis. This fact raises the possibility that mitotic onset and/or exit might be regulated, in part, by movement of important mitotic proteins into and out of the nucleoplasm. We have used two methods to determine whether tubulin levels in the nucleoplasm are regulated in the fungus Aspergillus nidulans. First, we have used benomyl to disassemble microtubules and create a pool of free tubulin that can be readily observed by immunofluorescence. We find that tubulin is substantially excluded from interphase nuclei, but is present in mitotic nuclei. Second, we have observed a green fluorescent protein/alpha-tubulin fusion in living cells by time-lapse spinning-disk confocal microscopy. We find that tubulin is excluded from interphase nuclei, enters the nucleus seconds before the mitotic spindle begins to form, and is removed from the nucleoplasm during the M-to-G1 transition. Our data indicate that regulation of intranuclear tubulin levels plays an important, perhaps essential, role in the control of mitotic spindle formation in A. nidulans. They suggest that regulation of protein movement into the nucleoplasm may be important for regulating mitotic onset in organisms with intranuclear mitosis.     

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.     

Signal-dependent translocation of simian virus 40 large-T antigen into rat liver nuclei in a cell-free system.

An in vitro nuclear translocation system is described in which isolated rat liver nuclei were incubated in a defined buffered medium containing radiolabeled or fluorescently labeled exogenous proteins. The nuclei were rapidly recovered, extracted, and analyzed for the presence of associated radiolabeled or fluorescently labeled proteins. The isolated nuclei exhibited the same specificity for protein uptake as seen previously in vivo, accumulating simian virus 40 wild-type large-T antigen and p53 while excluding a cytoplasmic variant of large-T antigen (d10) and bovine serum albumin. The rapid nuclear accumulation of wild-type large-T antigen was shown to be selective and dependent upon the recognition of a wild-type nuclear location signal, ATP and temperature dependent, and unidirectional. Taken together, the data suggest that in our in vitro system the nuclear translocation of wild-type large-T antigen exhibits some of the characteristics of an active transport process.     

The motif of SPARC that inhibits DNA synthesis is not a nuclear localization signal

SPARC (secreted protein acidic and rich in cysteine), although primarily known as a secreted, matricellular protein, has also been identified in urothelial cell nuclei. Many biological activities, including inhibition of cell adhesion and repression of DNA synthesis, have been ascribed to SPARC, but the influence of its intracellular localization on each of these activities is unknown. When exposed by epitope retrieval and nuclear matrix unmasking techniques, endogenous SPARC was found to localize strongly to the nuclei and the nuclear matrix of cultured urothelial cells. Live-cell time-lapse imaging revealed that exogenous fluorescently labeled recombinant (r) SPARC was taken up from medium over a 16 h period and accumulated inside cells. Two variants of rSPARC with alterations in its putative nuclear localization signal (NLS) were generated to investigate the existence and effects of the NLS. These variants demonstrated similar biophysical characteristics as the wild-type protein. Visualization by a variety of techniques, including live-cell imaging, deconvolution microscopy, and cell fractionation, all concurred that exogenous rSPARC was not able to localize to cell nuclei, but instead accumulated as perinuclear clusters. Localization of the rSPARC NLS variants was no different than wild-type, arguing against the presence of an active NLS in rSPARC. Imaging experiments showed that only permeabilized, dead cells avidly took up rSPARC into their nuclei. The rSPARC(no NLS) variant proved ineffective at inhibiting DNA synthesis, whereas the rSPARC(strong NLS) variant was a more potent inhibitor of DNA synthesis than was wild-type rSPARC. The motif of SPARC that inhibits the synthesis of urothelial cell DNA is therefore not a nuclear localization signal, but its manipulation holds therapeutic potential to generate a "Super-SPARC" that can quiesce proliferative tissues.