Actin clearance promotes polarized dynein accumulation at the immunological synapse

Immunological synapse (IS) formation between a T cell and an antigen-presenting cell is accompanied by the reorientation of the T cell centrosome toward the interface. This polarization response is thought to enhance the specificity of T cell effector function by enabling the directional secretion of cytokines and cytotoxic factors toward the antigen-presenting cell. Centrosome reorientation is controlled by polarized signaling through diacylglycerol (DAG) and protein kinase C (PKC). This drives the recruitment of the motor protein dynein to the IS, where it pulls on microtubules to reorient the centrosome. Here, we used T cell receptor photoactivation and imaging methodology to investigate the mechanisms controlling dynein accumulation at the synapse. Our results revealed a remarkable spatiotemporal correlation between dynein recruitment to the synaptic membrane and the depletion of cortical filamentous actin (F-actin) from the same region, suggesting that the two events were causally related. Consistent with this hypothesis, we found that pharmacological disruption of F-actin dynamics in T cells impaired both dynein accumulation and centrosome reorientation. DAG and PKC signaling were necessary for synaptic F-actin clearance and dynein accumulation, while calcium signaling and microtubules were dispensable for both responses. Taken together, these data provide mechanistic insight into the polarization of cytoskeletal regulators and highlight the close coordination between microtubule and F-actin architecture at the IS.

Simulations of centriole of polarized centrosome as a monopole antenna in immune and viral synapses

The immune synapse (IS) is a temporary interface between an antigen-presenting cell and an effector lymphocyte. Viral synapse is a molecularly organized cellular junction that is structurally similar to the IS. Primary cilium is considered as a functional homologue of the IS due to the morphological and functional similarities in architecture between both micotubule structures. It has been hypothesized that endogenous electromagnetic field in the cell is generated by a unique cooperating system between mitochondria and microtubules. We are extending this prior hypothesis of the endogenous electromagnetic field in the cell postulating that polarized centriole in immune and viral synapse could serve as a monopole antenna. This is an addition to our hypothesis that primary cilium could serve as a monopole antenna. We simulated the distribution of electric field of centriole of polarized centrosome as a monopole antenna in immune and viral synapse. Very weak electromagnetic field of polarized centriole of CD8+ T lymphocyte in IS can contribute to the transport of cytolytic granules into the attacked (cancer) cell. Analogically, very weak electromagnetic field of polarized centriole in viral synapse of infected CD4 cells can aid the transport of viruses (human immunodeficiency virus) to non-infected CD4 cells. We hypothesized that healthy organisms need these monopole antennas. If, during the neoplastic transformation, healthy cells lose monopole antennas in form of primary cilia, the IS aims to replace them by monopole antennas of polarized centrioles in IS to restore homeostasis.

Centrosomal localisation of the cancer/testis (CT) antigens NY-ESO-1 and MAGE-C1 is regulated by proteasome activity in tumour cells

The Cancer/Testis (CT) antigen family of genes are transcriptionally repressed in most human tissues but are atypically re-expressed in many malignant tumour types. Their restricted expression profile makes CT antigens ideal targets for cancer immunotherapy. As little is known about whether CT antigens may be regulated by post-translational processing, we investigated the mechanisms governing degradation of NY-ESO-1 and MAGE-C1 in selected cancer cell lines. Inhibitors of proteasome-mediated degradation induced the partitioning of NY-ESO-1 and MAGE-C1 into a detergent insoluble fraction. Moreover, this treatment also resulted in increased localisation of NY-ESO-1 and MAGE-C1 at the centrosome. Despite their interaction, relocation of either NY-ESO-1 or MAGE-C1 to the centrosome could occur independently of each other. Using a series of truncated fragments, the regions corresponding to NY-ESO-1_91-150 and MAGE-C1_900-1116 were established as important for controlling both stability and localisation of these CT antigens. Our findings demonstrate that the steady state levels of NY-ESO-1 and MAGE-C1 are regulated by proteasomal degradation and that both behave as aggregation-prone proteins upon accumulation. With proteasome inhibitors being increasingly used as front-line treatment in cancer, these data raise issues about CT antigen processing for antigenic presentation and therefore immunogenicity in cancer patients.

Deterministic mechanical model of T-killer cell polarization reproduces the wandering of aim between simultaneously engaged targets

T-killer cells of the immune system eliminate virus-infected and tumorous cells through direct cell-cell interactions. Reorientation of the killing apparatus inside the T cell to the T-cell interface with the target cell ensures specificity of the immune response. The killing apparatus can also oscillate next to the cell-cell interface. When two target cells are engaged by the T cell simultaneously, the killing apparatus can oscillate between the two interface areas. This oscillation is one of the most striking examples of cell movements that give the microscopist an unmechanistic impression of the cell's fidgety indecision. We have constructed a three-dimensional, numerical biomechanical model of the molecular-motor-driven microtubule cytoskeleton that positions the killing apparatus. The model demonstrates that the cortical pulling mechanism is indeed capable of orienting the killing apparatus into the functional position under a range of conditions. The model also predicts experimentally testable limitations of this commonly hypothesized mechanism of T-cell polarization. After the reorientation, the numerical solution exhibits complex, multidirectional, multiperiodic, and sustained oscillations in the absence of any external guidance or stochasticity. These computational results demonstrate that the strikingly animate wandering of aim in T-killer cells has a purely mechanical and deterministic explanation.

Formins regulate the actin-related protein 2/3 complex-independent polarization of the centrosome to the immunological synapse

T cell receptor (TCR)-mediated cytoskeletal reorganization is considered to be actin-related protein (Arp) 2/3 complex dependent. We therefore examined the requirement for Arp2/3- and formin-dependent F-actin nucleation during T cell activation. We demonstrated that without Arp2/3-mediated actin nucleation, stimulated T cells could not form an F-actin-rich lamellipod, but instead produced polarized filopodia-like structures. Moreover, the microtubule-organizing center (MTOC, or centrosome), which rapidly reorients to the immunological synapse through an unknown mechanism, polarized in the absence of Arp2/3. Conversely, the actin-nucleating formins, Diaphanous-1 (DIA1) and Formin-like-1 (FMNL1), did not affect TCR-stimulated F-actin-rich structures, but instead displayed unique patterns of centrosome colocalization and controlled TCR-mediated centrosome polarization. Depletion of FMNL1 or DIA1 in cytotoxic lymphocytes abrogated cell-mediated killing. Altogether, our results have identified Arp2/3 complex-independent cytoskeletal reorganization events in T lymphocytes and indicate that formins are essential cytoskeletal regulators of centrosome polarity in T cells.

Identification of new centrosome proteins by autoimmune patient sera

Compared to other subcellular organelles, centrosome proteome can hardly be studied, due to the difficulties in separation and purification of centrosome. Auto-antisera from 6 autoimmune patients, which recognized centrosome specifically in immunofluorescence, were used to identify the corresponding centrosomal proteins. The sera were first tested by Western blot on whole cell lysate, and all bound antibodies were then eluted from each single band in Western blot membrane to assure which antibody was responsible for the centrosome specific immunofluorescence staining. The corresponding proteins were obtained by immunoprecipitation and identified by mass spectrometry. Six centrosomal proteins, including 2 known centrosomal proteins and 4 proteins with unknown localization or reportedly non-centrosomal localization, were identified. These proteins apparently involve in cell cycle regulation, signal transduction pathways, molecular chaperons, and metabolism enzymes, which may reflect the expected functional diversity of centrosome.

An improved method for Dictyostelium centrosome isolation

The Dictyostelium dicoideum centrosome consists of a box-shaped, layered core structure surrounded by dense nodules embedded in amorphous material, which make up the so-called corona. Thus, it differs markedly from centriole-containing centrosomes in animal cells or the plaque structure of yeast spindle pole bodies. For a long time, purification of Dictyostelium centrosomes was hampered by its extraordinarily tight linkage to the nucleus, which resisted all attempts to dissociate centrosomes and nuclei without destruction of the centrosome itself. Fortunately, we were able to solve this problem, and have already published a centrosome isolation protocol that is based on treatment of nucleus/centrosome complexes with sodium pyrophosphate and shear forces, followed by centrosome isolation through sedimentation and filtration techniques. However, isolated centrosomes prepared according to this protocol still contained too many impurities to allow mass spectrometrical analyses. Here, we present an improved protocol for the isolation of Dictyostelium centrosomes that contain considerably less contaminations with cytosolic and nuclear proteins.

Autoantibodies to mitotic apparatus: association with other autoantibodies and their clinical significance

The most important mitotic apparatus (MA) antigens are centrosome (CE), nuclear mitotic apparatus (NuMA-1, NuMA-2), midbody, and centromere F (CENP-F). We studied associations of anti-MA antibodies with other autoantibodies and their clinical significance. A total of 6270 patients were studied for the presence of anti-MA antibodies on HEp-2 cells. Sera positive for anti-MA were tested for anti-extractable nuclear antigens (ENA) antibodies. Anti-MA antibodies were detected in 56 (45 females and 11 males) of 6270 sera (0.9%). Of these 56, NuMA-1 was found in 23, NuMA-2 in 7, CE in 20, CENP-F in 5, and CENP-F/centrosome in 1 case. Anti-NuMA-1 were associated with anti-ENA antibodies (p < 0.001). Diagnoses were established in 43/56 patients: 22 connective tissue diseases, 7 infections, 6 autoimmune hepatitis, 3 vasculitis, 3 primary antiphospholipid syndrome, 1 malignancy, and 1 fever of unknown origin. The differential diagnosis of anti-NuMA-1-positive patients must include Sjögren's syndrome, while patients with anti-CE antibodies must be observed for HCV infection.

Mycoplasma infection induces a scleroderma-like centrosome autoantibody response in mice

Development of autoantibodies to intracellular molecules is a universal feature of autoimmune diseases and parallels onset of chronic inflammatory pathology. Initiating antigens of disease-specific autoantibody responses are unknown. We previously showed that the major targets of autoantibodies in scleroderma are centrosomes, organelles involved in mitotic spindle organization. Here we show that centrosome autoantibodies are induced in mice by mycoplasma infection. The centrosome-specific antibody response involves class switching of preexisting IgM to IgG isotypes, suggesting a T cell-dependent mechanism. The antibody response spreads to include additional intracellular targets, with newly recruited autoantibody specificities arising as IgM isotypes. Antibiotic treatment of mice prevents autoantibody development. Centrosome autoantibodies may provide an aetiological link between infection and human autoimmunity and suggest novel therapeutic strategies in these disorders.

Spastin interacts with the centrosomal protein NA14, and is enriched in the spindle pole, the midbody and the distal axon

Hereditary spastic paraplegia (HSP) is characterized by the specific retrograde degeneration of the longest axons in the central nervous system, the corticospinal tracts. The gene most frequently involved in autosomal dominant cases of this disease, SPG4, encodes spastin, an ATPase belonging to the AAA family. AAA proteins are thought to exert their function by the energy-dependent rearrangement of protein complexes. The composite function of these proteins is directed by their binding to regulatory factors and adaptor proteins that target their activity into specific pathways in vivo. We previously found that overexpressed spastin interacts dynamically with microtubules and displays microtubule-severing activity. Here, we demonstrate that spastin is enriched in cell regions containing dynamic microtubules. During cell division spastin is found in the spindle pole, the central spindle and the midbody, whereas in immortalized motoneurons it is enriched in the distal axon and the branching points. Furthermore, spastin interacts with the centrosomal protein NA14, and co-fractionates with gamma-tubulin, a centrosomal marker. Deletion of the region required for binding to NA14 disrupts spastin interaction with microtubules, suggesting that NA14 may be an important adaptor to target spastin activity at the centrosome. These data strongly argue that spastin plays a role in cytoskeletal rearrangements and dynamics, and provide an attractive explanation for the degeneration of motor axons in HSP.

Kinetochore localization and microtubule interaction of the human spindle checkpoint kinase Mps1

Members of the Mps1 protein kinase family have been implicated in the regulation of the kinetochore-mediated spindle assembly checkpoint in species ranging from yeast to man. However, conflicting data have been reported on the subcellular localization of vertebrate Mps1 kinases and their possible roles in centrosome duplication. Moreover, little is presently known about the regulation of Mps1 kinases during the cell cycle. Here, we have used immunofluorescence microscopy, immunoblotting and siRNA-mediated depletion of hMps1 to re-investigate the subcellular localization of this kinase. Our data confirm the kinetochore association of hMps1 but suggest that the centrosome staining produced by some anti-hMps1 antibodies could be due to cross-reactivity with other proteins. We also show that the kinetochore association of hMps1 is mediated by the amino-terminal, non-catalytic domain and specifically requires the presence of the Hec1/Ndc80-Nuf2 complex at the kinetochore. Finally, we have combined in vitro binding studies and kinase assays to explore the influence of microtubules on hMps1 activity. Our data indicate that the catalytic domain of hMps1 displays affinity for microtubules and that microtubule binding could contribute to the regulation of kinase activity.

Human ninein is a centrosomal autoantigen recognized by CREST patient sera and plays a regulatory role in microtubule nucleation

Centrosome is the major microtubule organizing center in mammalian cells that plays a critical role in a variety of cellular events by the microtubule arrays emanating from it. Despite its significance, the molecular mechanisms underlying the structure and function of the centrosome are still not clear. Herein we describe the identification of three isotypes of human ninein by expression library screening with autoimmune sera from CREST patients. All three ninein isotypes exhibit centrosomal localization throughout the cell cycle when GFP-tagged fusion proteins are expressed transiently in mammalian cells. Construction of serial deletions of GFP-tagged ninein reveals that a stretch of three leucine zippers with a flanking sequence is required and sufficient for centrosomal targeting. Overexpression of ninein results in mislocalization of gamma-tubulin, recruiting it to ectopic (noncentrosomal) ninein-containing sites which are not active in nucleating microtubules. In these cells, nucleation of microtubules from the centrosome is also inhibited. These results thus suggest a regulatory role for ninein in microtubule nucleation.

Spectrum of centrosome autoantibodies in childhood varicella and post-varicella acute cerebellar ataxia

BACKGROUND

Sera from children with post-varicella infections have autoantibodies that react with centrosomes in brain and tissue culture cells. We investigated the sera of children with infections and post-varicella ataxia and related conditions for reactivity to five recombinant centrosome proteins: gammagamma-enolase, pericentrin, ninein, PCM-1, and Mob1.

METHODS

Sera from 12 patients with acute post-varicella ataxia, 1 with post-Epstein Barr virus (EBV) ataxia, 5 with uncomplicated varicella infections, and other conditions were tested for reactivity to cryopreserved cerebellum tissue and recombinant centrosome proteins. The distribution of pericentrin in the cerebellum was studied by indirect immunofluorescence (IIF) using rabbit antibodies to the recombinant protein. Antibodies to phospholipids (APL) were detected by ELISA.

RESULTS

Eleven of 12 children with post-varicella ataxia, 4/5 children with uncomplicated varicella infections, 1/1 with post-EBV ataxia, 2/2 with ADEM, 1/2 with neuroblastoma and ataxia, and 2/2 with cerebellitis had antibodies directed against 1 or more recombinant centrosome antigens. Antibodies to pericentrin were seen in 5/12 children with post-varicella ataxia but not in any of the other sera tested. IIF demonstrated that pericentrin is located in axons and centrosomes of cerebellar cells. APL were detected in 75% of the sera from children with post-varicella ataxia and 50% of children with varicella without ataxia and in none of the controls.

CONCLUSION

This is the first study to show the antigen specificity of anti-centrosome antibodies in children with varicella. Our data suggest that children with post-varicella ataxia have unique autoantibody reactivity to pericentrin.

Enhancing major histocompatibility complex class I antigen presentation by targeting antigen to centrosomes

Several strategies that increase proteasomal degradation of antigen have been shown to improve MHC class I presentation of antigen. Because recent studies have demonstrated that the centrosome is a subcellular compartment rich in proteasomes, we hypothesized that targeting a tumor antigen to centrosomal compartments would enhance both the MHC class I presentation of antigen and the vaccine potency. We, therefore, created a chimera of gamma-tubulin, an established centrosomal marker, with a model tumor antigen, human papillomavirus type 16 (HPV-16) E7, in a DNA vaccine. The linkage of gamma-tubulin to E7-targeted antigen to centrosomal compartments, resulted in enhanced MHC class I presentation of E7, and led to a marked increase in the number of E7-specific CD8(+) T-cell precursors as well as a potent CD4-independent antitumor effect against an E7-expressing tumor cell line, TC-1. In addition, vaccination with gamma-tubulin/E7 DNA in transporter associated with antigen presentation (TAP)-1-knockout mice revealed that the enhancement of E7-specific CD8(+) T-cell immune responses is TAP-1-dependent. Our data suggest that the centrosome may be an important locus for MHC class I antigen processing and that targeting antigen to the centrosome can improve DNA vaccine potency.

Regulation of microtubule-organizing center orientation and actomyosin cytoskeleton rearrangement during immune interactions

The reorganization of membrane, cytoskeletal and signaling molecules during immune interactions is critical for the generation of immune response. At the initiation of the T cell-antigen presenting cell (APC) interaction, antigen-independent weak adhesion forces allow the scanning of the APC surface by the T cell receptor for specific antigens. The stabilization of T cell-APC conjugates involves the segregation of membrane and intracellular signaling proteins, driven by reorganization of membrane microdomains and cytoskeletal changes. In early T cell-APC cognate interactions, the microtubular cytoskeleton undergoes drastic changes that lead to microtubule-organizing center (MTOC) reorientation to the vicinity of the cell-cell contact area. Recent data on the dynamics of MTOC redistribution and its influence in T cell-APC conjugate stabilization, together with the description of an increasing number of signaling molecules associated to this complex, underscore the key role of MTOC translocation in the T cell response. We focus on the mechanisms that control the early MTOC reorientation during T cell-APC interaction and the relevance of this process to T cell activation.

[Clinical significance of fluoroscopic patterns specific for the mitotic spindle in patients with rheumatic diseases]

OBJECTIVE

To determine the clinical significance of anti-NuMA and anti-HsEg5 antibodies in a group of patients affected with rheumatic diseases.

MATERIALS AND METHODS

Indirect immunofluorescence on HEp-2000 cells at serum dilution of 1:40 was used to examine 26 sera which had previously showed a "mitotic spindle" fluoroscopic pattern type during laboratory routine.

RESULTS

21 sera (80,7%) were identified with NuMA and 5 (19,3%) with HsEg5 patterns alone or associated with other ANA patterns. However only patients with isolated positivity and that is 15 with NuMA and 4 with HsEg5 stainings were included in this study. Of the NuMA positive patients 5 were affected with arthropathies associated to different forms of thyroiditis, 2 with seronegative arthritis, 2 with antiphospholipid syndrome, 1 with systemic lupus erythematosus (SLE), 1 with rheumatoid arthritis, 1 with sicca syndrome, 1 with undifferentiated connective tissue disease, 1 with Mycoplasma pneumoniae infection and 1 with retinal thrombosis. Of the HsEg5 positive patients 3 were affected with SLE and 1 with seronegative arthritis.

CONCLUSIONS

NuMA does not prevail in any defined rheumatic disease, while HsEg5 staining were more frequent (75%) in patients affected with SLE all of whom showing high antibody titres.

The lipid raft microdomain-associated protein reggie-1/flotillin-2 is expressed in human B cells and localized at the plasma membrane and centrosome in PBMCs

Reggie-1/flotillin-2 is a plasma membrane-associated cytoplasmic protein, which defines non-caveolar raft microdomains. Reggie-1/flotillin-2 is enriched in detergent insoluble (TX100) membrane fractions (DIG), co-localizes with activated GPI-linked proteins and the fyn-kinase in neurons and T cells, and thus apparently participates in the assembly of protein complexes essential for signal transduction. In T cells activated by crosslinking the GPI-linked protein Thy-1 or by crosslinking the ganglioside GM1, reggie-1/flotillin-2 co-localizes with the T cell receptor. To determine whether reggie-1/flotillin-2 is also expressed in B cells, primary B cells from human blood and cell lines representing the developmental stages of pro, pre, mature and plasma B cells were analyzed by Western blotting, RT-PCR and immunofluorescence. Here, we show that reggie-1/flotillin-2 is expressed throughout B cell development, as well as in primary B cells, purified by cell sorting. On non-activated mature B cell Raji cell line we found reggie-1/flotillin-2 are exclusively in the detergent (TX100) insoluble membrane fractions that are staining positive for the raft marker GM1. Immunofluorescence microscopy showed that reggie-1/flotillin-2 is localized at the plasma membrane and marks intracellular spots in PBMCs. Confocal co-localization studies showed that reggie-1/flotillin-2 is associated with the plasma membrane, and the centrosomes (microtubule organizing centers) in these PBMCs. Comparison of reggie-1/flotillin-2 cDNA sequences with the genomic sequence database allowed us to determine the exon/intron structures in mouse and human. The gene organizations are highly conserved suggesting an important function of reggie-1/flotillin-2. Since reggie/flotillin proteins co-cluster with the T cell receptor and fyn kinases upon T cell stimulation, our findings of reggie-1/flotillin-2 in B cells suggest a similar role in B cell function.

Characterization of Cep135, a novel coiled-coil centrosomal protein involved in microtubule organization in mammalian cells

By using monoclonal antibodies raised against isolated clam centrosomes, we have identified a novel 135-kD centrosomal protein (Cep135), present in a wide range of organisms. Cep135 is located at the centrosome throughout the cell cycle, and localization is independent of the microtubule network. It distributes throughout the centrosomal area in association with the electron-dense material surrounding centrioles. Sequence analysis of cDNA isolated from CHO cells predicted a protein of 1,145-amino acid residues with extensive alpha-helical domains. Expression of a series of deletion constructs revealed the presence of three independent centrosome-targeting domains. Overexpression of Cep135 resulted in the accumulation of unique whorl-like particles in both the centrosome and the cytoplasm. Although their size, shape, and number varied according to the level of protein expression, these whorls were composed of parallel dense lines arranged in a 6-nm space. Altered levels of Cep135 by protein overexpression and/or suppression of endogenous Cep135 by RNA interference caused disorganization of interphase and mitotic spindle microtubules. Thus, Cep135 may play an important role in the centrosomal function of organizing microtubules in mammalian cells.

Targeting of HIV-1 Nef to the centrosome: implications for antigen processing

To gain a better understanding of the intracellular sites of antigen processing we have looked at the localization of human immunodeficiency virus (HIV)-1 Nef protein by confocal microscopic and biochemical means. We found that ubiquitin (Ub)-Nef fusion proteins were localized to the centrosome in transfected COS-7 cells, and that the colocalization was inhibited by the microtubule-disrupting agent, nocodazole. Interestingly, we found that Ub-Nef trafficking to the centrosome was not dependent upon the metabolic stability of Ub-Nef nor on the inhibition of proteasome activity. We also analyzed the MHC class I antigen processing of a reporter epitope linked to the Ub-Nef fusion proteins and found that Ub-Nef was processed in COS-7 cells. In addition, we show that this processing was inhibited by nocodazole. We suggest that the centrosome may serve as a site of antigen processing in vivo.

A subset of centrosomal proteins are arranged in a tubular conformation that is reproduced during centrosome duplication

The centrosome plays a fundamental role in organizing the interphase cytoskeleton and the mitotic spindle, and its protein complexity is modulated to support these functions. The centrosome must also duplicate itself once during each cell cycle, thus ensuring the formation of a bipolar spindle and its continuity through successive cell divisions. In this study, we have used a battery of antibodies directed against centrosomal components to study the general organization of the centrosome during the cell cycle and during the centrosome duplication process. We demonstrate that a subset of centrosomal proteins are arranged together to form a tubular pattern within the centrosome. The tubular conformation defined by these proteins has a polarity and is closed at one end. The centriole complement of the centrosome is normally placed near this end. We show that the "wall" of the tube is enriched in proteins such as CDC2, ninein, and pericentrin as well as gamma-tubulin. In addition, a subset of gamma-tubulin is localized to the "lumen" of the tube. We also demonstrate, for the first time, that antibody staining can be used to detect centrosome duplication allowing the identification of duplication intermediates. We show that one product of centrosome duplication is the replication of the tubular structure found within the centrosome. The position of the centriole duplexes prior to and during centrosome duplication is documented and a model of the morphogenesis of the centrosome during the duplication process is proposed.

Structure of the gamma-tubulin ring complex: a template for microtubule nucleation

The gamma-tubulin ring complex (gammaTuRC) is a protein complex of relative molecular mass approximately 2.2 x 10(6) that nucleates microtubules at the centrosome. Here we use electron-microscopic tomography and metal shadowing to examine the structure of isolated Drosophila gammaTuRCs and the ends of microtubules nucleated by gammaTuRCs and by centrosomes. We show that the gammaTuRC is a lockwasher-like structure made up of repeating subunits, topped asymmetrically with a cap. A similar capped ring is also visible at one end of microtubules grown from isolated gammaTuRCs and from centrosomes. Antibodies against gamma-tubulin label microtubule ends, but not walls, in centrosomes. These data are consistent with a template-mediated mechanism for microtubule nucleation by the gammaTuRC.

Hsp90 is a core centrosomal component and is required at different stages of the centrosome cycle in Drosophila and vertebrates

To determine the molecular composition of the centrosome of a higher eukaryote, we carried out a systematic nano-electrospray tandem or MALDI mass spectrometry analysis of the polypeptides present in highly enriched preparations of immunoisolated Drosophila centrosomes. One of the proteins identified is Hsp83, a member of the highly conserved Hsp90 family including chaperones known to maintain the activity of many proteins but suspected to have other essential, unidentified functions. We have found that a fraction of the total Hsp90 pool is localized at the centrosome throughout the cell cycle at different stages of development in Drosophila and vertebrates. This association between Hsp90 and the centrosome can be observed in purified centrosomes and after treatment with microtubule depolymerizing drugs, two criteria normally used to define core centrosomal components. Disruption of Hsp90 function by mutations in the Drosophila gene or treatment of mammalian cells with the Hsp90 inhibitor geldanamycin, results in abnormal centrosome separation and maturation, aberrant spindles and impaired chromosome segregation. This suggests that another role of Hsp90 might be to ensure proper centrosome function.

Cell cycle-dependent localization of monoclonal antibodies raised against isolated Dictyostelium centrosomes

The ultrastructure of the Dictyostelium centrosome is markedly different from that of the well known yeast spindle pole body and vertebrate centriole-containing centrosome. It consists of a box-shaped, layered core structure surrounded by a corona with dense nodules embedded in an amorphous matrix. For further structural and biochemical analyses of this type of centrosome we used highly enriched isolated Dictyostelium centrosomes as an antigen to raise 14 new centrosomal monoclonal antibodies. Immunofluorescence microscopy and Western blot analysis revealed that at least 10 of them were directed against different antigens. Immunofluorescence microscopy also showed that the monoclonal antibodies fell into three different groups: A) antibodies localizing to the centrosome during the entire cell cycle; B) antibodies staining the centrosome mainly during mitosis; and C) antibodies labeling centrosome associated structures. All antibodies, except one, exhibited a cell cycle-dependent staining pattern underscoring the highly dynamic properties of the Dictyostelium centrosome.

Centrosome proteins: a major class of autoantigens in scleroderma

Autoantibodies to intracellular antigens are a hallmark of autoimmune diseases, although their role in disease pathogenesis is unclear. Centrosomes are organelles involved in the organization of the mitotic spindle and they are targets of autoantibodies in systemic sclerosis (SSc). We used recombinant centrosome autoantigens, centrosome-specific antibodies, and immunoassays to demonstrate that a significant proportion of SSc patients exhibited centrosome reactivity. Two centrosome proteins cloned in our laboratory were used to screen 129 SSc sera by Western blotting. The same sera were screened by immunofluorescence using centrosome-specific antibodies to distinguish centrosomes from nuclear speckles commonly stained by SSc sera. Using these criteria, 42.6% of SSc patients were autoreactive to centrosomes, a larger percentage than reacted with all other known SSc autoantigens. Most centrosome-positive sera reacted with both centrosome proteins and half were negative for other routinely assayed SSc autoantibodies. By these criteria, we have identified a novel class of SSc autoreactivity. Only a small percentage of normal individuals and patients with other connective tissue diseases had centrosome reactivity. These results demonstrate that centrosome autoantibodies are a major component of autoreactivity in SSc and thus have potential in disease diagnosis. Centrosome autoantigens may be useful in studying the development of autoantibodies and chronic inflammation in SSc and perhaps other autoimmune diseases.

Organelle isolation by magnetic immunoabsorption

Currently, most organelle isolation procedures rely on physical parameters and centrifugation for separation. Here, we report the rapid and gentle isolation of a variety of organelles by immunolabeling whole cell lysates with organelle-specific antibodies and streptavidin magnetic particles followed by separation in a magnetic field. Using magnetic immunoabsorption, we have been able to specifically label mouse metaphase chromosomes and a variety of plant organelles, including: amyloplasts, choroplasts and nuclei from whole cell lysates of various plant tissues. We find that the distinct magnetic properties, surface characteristics and mean diameter-size ranges of different particle preparations significantly influence their specific utility for organelle isolations. By using an internal-field magnetic separation device, we have developed a method for quantitative recovery of labeled organelles in microarrays and tested a variety of antibodies to chloroplast outer envelope proteins for their ability to immune-isolate chloroplasts.

Isolation of centrosomes from Spisula solidissima oocytes

We have described methods for the preparation of lysates and isolation of centrosomes from parthenogenetically activated oocytes of the surf clam, S. solidissima. Although oocyte availability is seasonal, between June and August as much as 2 liters of lysate can be generated by a single person. Since lysate can be stored frozen at -80 degrees C with no apparent loss in centrosome-dependent microtubule nucleation, this is a convenient system for year-round experimentation. On average, per milliliter of frozen-stored lysate, 2 or 3 x 10(6) centrosomes can be obtained at 3000- or 4000-fold purification by sucrose-density gradient centrifugation. Centrosome fractions typically contain 6.0 x 10(-12) g of protein per centrosome (Vogel et al., 1997) and 140-200 micrograms of protein is usually obtained from a single run involving six sucrose-density gradients (12 ml of lysate). One person can easily run three preparations in a day, and thus 420-600 micrograms of centrosome protein could be prepared daily. Therefore, based on the effort of one individual, as much as 20-40 mg of centrosome protein could be prepared per year. Another convenient feature of the system is that once centrosomes are isolated, they can be stored in high sucrose media at -80 degrees C for years with little or no loss in microtubule nucleation potential. Once isolated, centrosomes can be used for protein analysis, ultrastructural studies, or in functional reconstitution assays (Vogel, 1997). In addition, these preparations offer the isolation of sufficient quantities of centrosome proteins to be used as antigens for generating centrosome-specific antibodies or for obtaining protein sequence for the purpose of antibody production or the design of oligonucleotide primers for isolating cDNA fragments coding for centrosome proteins. Thus, the preparations described offer a biochemical approach for defining centrosome composition. The methods described for immunofluorescence analysis of asters assembled in lysates offer rapid and convenient preparations for screening antibodies for centrosome localization and specificity. Finally, the ability to prepare large quantities of homogeneous centrosomes should enhance ultrastructural studies since many centrosomes can be sectioned and analyzed simultaneously by EM, avoiding the problem of having to hunt through sections of single cells to find a single centrosome for analysis. In addition, colloidal gold localization studies, using antibodies and EM to pinpoint the relative location of individual proteins, could be carried out on populations of centrosomes in the same preparation simultaneously, thus drastically expanding the quantity of data gathered. In conclusion, the clam oocyte system described here offers the potential for a combined structural and biochemical approach for identification of novel centrosome proteins and elucidation of the molecular basis of microtubule nucleation, centrosome assembly, and centrosome function.

Distribution of a centrosomal antigen during morphogenesis in the ciliated protozoan Euplotes

Ciliates assemble basal bodies in great number at many stages of the life-cycle. In order to understand their assembly mechanisms, we screened a library of monoclonal antibodies directed against pericentriolar material. One of these antibodies, CTR210, was used previously to follow steps of this assembly process: in Paraurostyla, new basal bodies appear along a scaffold of linear structures recognized by this antibody. The very unusual behavior of this antigen deserved confirmation in other species. In the present study, we show by immunofluorescence that, in another phylogenetically very distant species, Euplotes, basal bodies are assembled in the same pathway during division. In addition, this antibody recognizes a filamentous ring located at the division furrow and linking many basal body assemblages. By cell fractionation and cytoskeletal extraction, we obtained fractions enriched in basal bodies and associated material. Such fractions still display a high complexity in protein composition. These fractions were used to characterize the main target of the antibody as a doublet of 45 kDa. These results confirm previous results in terms of functionality of the protein recognized by the antibody, but raise new questions in terms of the assignment of the recognized protein to the HSP70 family as hypothesized previously.

Autoantibodies to components of the mitotic apparatus

Autoantibodies directed to a variety of cellular antigens and organelles are a feature of autoimmune diseases. They have proven useful in a clinical setting to establish diagnosis, estimate prognosis, follow disease progression, alter therapy, and initiate new investigations. Cellular and molecular biologists have used autoantibodies as probes to identify molecules involved in key cellular processes. One of the most interesting sets of autoantibodies are those that target antigens within the mitotic apparatus (MA). The MA includes chromosomes, spindle microtubules and centrosomes. The identification, localization, function, and clinical relevance of MA autoantigens is the focus of this review.

Isolation of nucleation-competent centrosomes from Dictyostelium discoideum

The centrosome of Dictyostelium discoideum is a box-shaped, layered core structure surrounded by a corona which is made up of dense nodules embedded in amorphous material. It is also known as nucleus-associated body. Because of its tight association with the nucleus the centrosome has resisted so far all attempts for isolation in sufficient purity and quantity for biochemical analysis. Here we report on the large-scale isolation of D. discoideum centrosomes after treatment of nucleus-centrosome complexes with a buffer containing sodium pyrophosphate. Following heparin treatment and a filtration step, centrosomes were further purified by density gradient centrifugation. Immunofluorescence analysis of the isolated centrosomes revealed the presence of the D. discoideum 350-kDa antigen, a centrosomal marker protein, gamma-tubulin, and the D. discoideum homologues of pericentrin, Spc110p, and Cdc31p. The structural integrity of the isolated centrosomes was demonstrated by confocal laser microscopy and electron microscopy. Microtubule nucleation assays with purified pig brain tubulin showed that the isolation procedure did not only preserve the structure but also the functionality of the isolated centrosomes. D. discoideum centrosomes should now become an attractive new model system in addition to, and for comparison with, centriolar centrosomes and yeast spindle pole bodies.

Localization of autoepitopes on the PCM-1 autoantigen using scleroderma sera with autoantibodies against the centrosome

Characterization of epitope domains of autoantigens is important for deducing the cellular functions of autoantigens and may be important for understanding the autoimmune response. In the reported studies, epitope analysis of the centrosome autoantigen PCM-1 was performed. For these investigations, portion of the PCM-1 cDNA were subcloned into the pMAL expression plasmid, fusion proteins were induced, and aliquots of the extracts were probed by immunoblot analysis using two human autoimmune anticentrosome autoantisera. Immunoblotting identified three individual autoepitopes of 26-40 amino acid residues, amino acids 506-545, 1434-1465, and 1661-1686, within the PCM-1 protein. ELISA assays using non-denatured proteins did not identity any additional autoepitopes in the remainder of the PCM-1 molecule. To analyze the identified autoepitopes further, synthetic peptides were generated that covered each of the three autoepitopes and the synthetic peptides then were probed using the scleroderma sera. Peptides that covered the antigenic regions from amino acids 506-545 and 1434-1465 failed to react with the anticentrosome autoantisera suggesting that overall protein conformation may be important for the formation of those two autoepitopes. Peptides derived from the sequence of the third autoepitope were recognized by autoantibodies present in the anticentrosome autoantisera allowing the identification of the tripeptide KDC as the autoepitope in this region of the PCM-1 molecule. These studies lay the foundation for future investigations of the autoimmune response in scleroderma patients that are producing anticentrosome autoantibodies and should allow an investigation of the cellular role of the PCM-1 protein.

Autoantibodies to a group of centrosomal proteins in human autoimmune sera reactive with the centrosome

OBJECTIVE

Human autoantibodies reacting with protein components of the microtubule organizing center of the cell, the centrosome, are rare and have not been extensively studied. We therefore investigated the number, type, and frequency of autoantibodies reactive with centrosomal proteins in a cohort of human sera.

METHODS

To establish the type of autoantibodies found in autoimmune sera reactive with the centrosome, we used a prototype human serum, which was chosen for its intense reactivity with the centrosome throughout the cell cycle, to screen a HeLa complementary DNA (cDNA) (expression) library. Positive cDNA clones were sequenced and classified as encoding either known centrosomal autoantigens, known centrosomal proteins but unknown as human autoantigens, or previously unknown centrosomal antigens. To investigate whether these centrosomal autoantibody classes were characteristic of centrosomal-reactive sera, sera from 21 subjects with centrosomal reactivity by indirect immunofluorescence were characterized by Western blotting for reactivity to recombinant protein from each of the classes of centrosomal antigens. Clinical features were studied by retrospective chart review.

RESULTS

In each of the sera, autoantibodies that recognize a group of centrosomal proteins were identified. This group included known centrosomal autoantigens (pericentrin and pericentriolar material 1 [PCM-1]), the human homolog of a known mouse centrosomal protein, ninein, which was previously unknown as a human autoantigen, and a novel centrosomal protein (Cep250). Autoantibodies to PCM-1 were the least common (8 of 21 subjects; 38%) while those to ninein, Cep250, and pericentrin occurred at roughly equal frequencies (17 subjects [81%], 17 subjects [81%], and 19 subjects [90%], respectively). There was no apparent correlation between serum autoantibody reactivity and the clinical diagnosis.

CONCLUSION

Each of the autoimmune sera contained autoantibodies that reacted with a group of centrosomal proteins. We found that the centrosomal component ninein, first identified in mice, has a human homolog that is an autoantigen. Also, anticentrosomal sera contained antibodies to previously undetected centrosomal components. One of these novel antigens was identified and was designated Cep250. Thus, a characteristic of sera reactive with the centrosome is that they contain antibodies to a group of centrosomal proteins.

[Autoantibodies against centrosomes in a patient with limited systemic sclerosis with ulcera cruris and arteriopathy--case report and review of the literature]

A 63 year old woman developed painful, up to 15 x 7 cm large ulcers on both lower limbs and an acral necrosis on the right big toe. The patient had no symptoms of intermittent claudication, but a history of 40 package years of cigarette smoking. Angiography showed circumscript stenosis of medium-sized vessels, deformed vessel segments, and rarification and obstruction of peripheral vessels. Arterial occlusive disease was diagnosed, and percutaneous transluminal angioplasty (PTA) of the right common iliac artery and both femoral arteries performed. However, despite documented patency of these vessels clinical symptoms worsened. The consulting rheumatologist found a history of Raynaud's syndrome, acral necrosis of the fourth finger of the right hand, sclerodactylia, and microstomia. Capillaroscopy revealed megacapillaries and vessel rarification. High titers of antinuclear antibodies with specificity for centrosomes (1:10240), which have not been described in this context to date, were detected and limited systemic sclerosis of the CREST type was diagnosed. Treatment with iloprost (50 micrograms/day i.v.) and pulsed cyclophosphamide (800 mg i.v./month) resulted in almost complete healing of the crural and digital ulcers and a significant reduction of the analgetic medication.

Mitotic phosphoepitopes are expressed in Kc cells, neuroblasts and isolated chromosomes of Drosophila melanogaster

The progression of cells from metaphase to anaphase is thought to be regulated by a checkpoint that delays entry into anaphase until all chromosomes reach a stable bi-polar attachment at the metaphase plate. Previous work has suggested that the 3F3/2 kinetochore phosphoepitopes are involved in this checkpoint system. We show that the 3F3/2 centromere phosphoepitopes are present in Kc cells, third instar larval neuroblasts and isolated chromosomes of Drosophila melanogaster. In tissue culture cells and neuroblasts isolated from third instar larvae, centromere labelling is detected from early prophase to the metaphase-anaphase transition but absent once cells center anaphase. During anaphase, the antibody stains the spindle mid zone and during telophase the midbody is labelled until cells separate. In both cell types, the 3F3/2 antibody stains the centrosome from prophase to late telophase. The 3F3/2 staining is retained in Kc cells and third instar larval neuroblasts arrested at the prometaphase state with microtubule inhibitors. Also, two mitotic mutants that show abnormal spindle morphology retain the centromere labelling in a metaphase-like configuration, suggesting that they activate the metaphase-anaphase checkpoint. Finally, mitotic chromosomes isolated in the presence of a phosphatase inhibitor show phosphoepitopes at the primary constriction on the surface of each chromatid, however, chromosomes isolated in the absence of a phosphatase inhibitor do not. Incubation of these chromosomes with ATP causes the rephosphorylation of the phosphoepitopes at the centromere.

Recruitment of maternal material during assembly of the zygote centrosome in fertilized sea urchin eggs

Spindle poles of sea urchin embryos contain centrosomal material derived from maternal as well as paternal sources. To examine how maternal centrosomal material becomes recruited into spindle poles during the first cell cycle, fertilized sea urchin eggs were fixed and labeled with an anti-centrosomal antibody at sequential timepoints after insemination. Immunolabeling patterns demonstrate that the unfertilized egg contains small foci of immunoreactive material dispersed throughout the cytoplasm. Shortly after insemination, the diffuse foci coalesce to form a dense aggregate close to the sperm nucleus. Subsequently, centrosomal material spreads over the surface of the zygote nucleus and becomes partitioned into two masses during spindle pole formation. The involvement of the cytoskeleton in the translocation and targeting of maternal centrosomal material through the first cell cycle was examined by treating eggs with cytoskeletal disrupting agents, a general kinase inhibitor, and by re-inseminating fertilized eggs. These experiments indicate that the initially diffuse centrosomal material is transported centripetally to the sperm nucleus by the sperm aster and the centrosomal material is subsequently sequestered around the zygote nucleus by a microtubule-mediated mechanism. Remarkably, 6-dimethylaminopurine treatment shifted the targeting of maternal centrosomal material from the sperm nucleus to the female pronucleus; upon recovery, some of these zygotes formed spindle poles that flanked only the maternal chromosomes.

Multiple centrosomal microtubule organising centres and increased microtubule stability are early features of VP-16-induced apoptosis in CCRF-CEM cells

Microtubular reorganisation contributing to apoptotic morphology occurs in normal and neoplastic cells undergoing apoptosis induced by cytotoxic drugs [1-3]. The aim of this study was to correlate the changes in the microtubules (MTs) with behavior of the centrosome in apoptotic cells, and to see whether post-translational changes in tubulin occurred with the emergence of apoptotic MT bands. Apoptosis was induced in the human T-cell leukaemia line (CCRF-CEM) by treatment with 17 microM etoposide over a 4 h period. The time course of changes was assessed using flow cytometry (FCM) and immunocytochemistry in cells labelled for a centrosomal antigen (CSP-alpha) or alpha-tubulins. One hour following treatment we observed multiple centrosomal microtubule organising centres (MTOCs) associated with the nucleus and the transient appearance of a subset of stable MTs detected with an antibody specific for acetylated alpha-tubulin, as the bands of MTs which lobulate the nucleus are formed. The altered properties of the MTs thus reflect changes in function as apoptosis progresses.

Anticentromere antibodies in rheumatologic practice are not consistently associated with scleroderma

Anticentromere antibodies identified by indirect immunofluorescence are a valuable aid to the diagnosis and prognosis of patients with systemic sclerosis since they are associated in 50% to 80% of cases with limited cutaneous systemic sclerosis, a pattern usually associated with a good prognosis. We studied clinical presentations in rheumatology patients with anticentromere antibodies by indirect immunofluoresence and by ELISA and/or Western blot, but without scleroderma or Raynaud's phenomenon. Eight of 34 (23.5%) rheumatology clinic patients with centromere antibodies met these criteria, seven women and one man, with a median symptom duration of six years (range 1-20 years). Four had Sjögren's syndrome, one had isolated xerostomia, one systemic lupus erythematosus, one seronegative symmetric polyarthritis and one primary biliary cirrhosis with arthralgia. The mean anticentromere antibody titer in these eight patients was similar to that in the patients who had at least Raynaud's phenomenon. Given the low incidence of scleroderma, these data illustrate the poor predictive value of anticentromere antibodies for the diagnosis of scleroderma in rheumatology clinic patients.

The perinuclear microtubule-organizing center and the synaptonemal complex of higher plants share a common antigen: its putative transfer and role in meiotic chromosomal ordering

Recognition of homologous chromosomes during meiotic prophase is associated in most cases with the formation of the synaptonemal complex along the length of the chromosome. Telomeres, located at the nuclear periphery, are preferential initiation sites for the assembly of the synaptonemal complex. In most eukaryotic cells, telomeres cluster in a restricted area, leading to the "bouquet" configuration in leptotene-zygotene, while this typical organization progressively disappears in late zygotene-pachytene. We wondered whether such striking changes in the intranuclear ordering and pairing of meiotic chromosomes during the progression of prophase I could be correlated with activity of the centrosome and/or microtubule-organizing center (MTOC). Plant cells may be used as a model of special interest for this study as the whole nuclear surface acts as an MTOC, unlike other cell types where MTOCs are restricted to centrosomes or spindle pole bodies. Using a monoclonal antibody (mAb 6C6) raised against isolated calf centrosomes we found that the 6C6 antigen is present over the entire surface of the plant meiotic nucleus, in early prophase I, before chromosomal pairing. At zygotene, short fragments of chromosomes become stained near the nuclear envelope and within the nucleus. At pachytene, after complete synapsis, the labeling specifically concentrates within the synaptonemal complexes, although the nuclear surface is no longer reactive. Ultrastructural localization using immunogold labeling indicates that the 6C6 antigen is colocalized with the synaptonemal complex structures. Later in metaphase I, the antigen is found at the kinetochores. Our data favor the idea that the 6C6 antigen may function as a particular "chromosomal passenger-like" protein. These observations shed new light on the molecular organization of the plant synaptonemal complex and on the redistribution of cytoskeleton-related antigens during initiation of meiosis. They suggest that antigens of MTOCs are relocated to chromosomes during the synapsis process starting at telomeres and contribute to the spatial arrangement of meiotic chromosomes. Such cytoskeleton-related antigens may acquire different functions depending on their localization, which is cell-cycle regulated.

Cold-treated centrosome: isolation of centrosomes from mitotic sea urchin eggs, production of an anticentrosomal antibody, and novel ultrastructural imaging

A novel isolation of centrosomes is described and it was used to both generate a centrosome-specific monoclonal antibody and to image with high-resolution low-voltage scanning electron microscopy the surface details of the isolated centrosome. At first mitotic prometaphase, sea urchin zygotes are chilled on ice overnight. While most of the microtubules disassemble, the mitotic centrosomes collapse into aggregated masses. These centrosomes have been isolated, and used to generate a monoclonal antibody, designated 4D2, which is reactive with interphase and mitotic centrosomes. 4D2 staining of centrosomes is similar, but not identical, to that of other centrosomal antibodies like Ah6 and 5051. Centrosomal material is detected as a compact sphere after cold treatment; upon recovery the sphere expands and undergoes the shape changes previously described [Mazia et al., 1987: J. Cell Biol. 105:206a] to eventually reorganize a normal mitotic apparatus.

Dissociation of centrosome replication events from cycles of DNA synthesis and mitotic division in hydroxyurea-arrested Chinese hamster ovary cells

Relatively little is known about the mechanisms used by somatic cells to regulate the replication of the centrosome complex. Centrosome doubling was studied in CHO cells by electron microscopy and immunofluorescence microscopy using human autoimmune anticentrosome antiserum, and by Northern blotting using the cDNA encoding portion of the centrosome autoantigen pericentriolar material (PCM)-1. Centrosome doubling could be dissociated from cycles of DNA synthesis and mitotic division by arresting cells at the G1/S boundary of the cell cycle using either hydroxyurea or aphidicolin. Immunofluorescence micros-copy using SPJ human autoimmune anticentrosome antiserum demonstrated that arrested cells were able to undergo numerous rounds of centrosome replication in the absence of cycles of DNA synthesis and mitosis. Northern blot analysis demonstrated that the synthesis and degradation of the mRNA encoding PCM-1 occurred in a cell cycle-dependent fashion in CHO cells with peak levels of PCM-1 mRNA being present in G1 and S phase cells before mRNA amounts dropped to undetectable levels in G2 and M phases. Conversely, cells arrested at the G1/S boundary of the cell cycle maintained PCM-1 mRNA at artificially elevated levels, providing a possible molecular mechanism for explaining the multiple rounds of centrosome replication that occurred in CHO cells during prolonged hydroxyurea-induced arrest. The capacity to replicate centrosomes could be abolished in hydroxyurea-arrested CHO cells by culturing the cells in dialyzed serum. However, the ability to replicate centrosomes and to synthesize PCM-1 mRNA could be re-initiated by adding EGF to the dialyzed serum. This experimental system should be useful for investigating the positive and negative molecular mechanisms used by somatic cells to regulate the replication of centrosomes and for studying and the methods used by somatic cells for coordinating centrosome duplication with other cell cycle progression events.

Identification of an HSP70-related protein associated with the centrosome from dinoflagellates to human cells

The monoclonal antibody CTR210 raised against isolated human centrosomes strongly decorates the centrosome and more weakly a domain congruent with the Golgi apparatus in several animal cells (HeLa, 3T3, CHO, PtK2). Both decorations resist Triton extraction in conditions which totally extract the Golgi apparatus, as judged by galactosyltransferase decoration. A 67 kDa centrosomal antigen can be demonstrated in human cells with this antibody. CTR210 also decorates the centrosome or associated structures in several systems, including unicellular eukaryotes such as dinoflagellates or ciliates. A 72 kDa antigen has been identified and purified from the dinoflagellate C. cohnii and its NH2-terminal sequence partially established. It shows a close homology with HSP70 proteins. The possibility that the 72 kDa antigen belongs to this chaperone family was further supported using a mAb reacting, in most species, with HSP70. A polyclonal antibody raised against the 72 kDa antigen from C. cohnii decorates the centrosome in human cells and reacts with the CTR210 centrosomal 67 kDa antigen. These results suggest that specific chaperone proteins are associated with the centrosome in eukaryotic cells. The centrosomal chaperones could participate in the microtubule nucleation reaction or in the process of centrosome assembly.

Autoepitope mapping of the centrosome autoantigen PCM-1 using scleroderma sera with anticentrosome autoantibodies

We previously characterized a scleroderma serum (serum 1) containing autoantibodies against centrosome autoantigens that have been named PCM-1, PCM-2 and PCM-3. In this study, we analyzed another scleroderma serum (serum 2) reactive with centrosome autoantigens of identical molecular weights to those recognized by serum 1. To further analyze the autoepitope domains in PCM-1 recognized by the autoantibodies present in scleroderma sera, cDNAs encoding different portions of the PCM-1 autoantigen were expressed in bacteria as fusion proteins. The immunoreactivity of the fusion proteins to the scleroderma sera was assayed by immunoblot analysis. Two regions containing autoepitope domains reactive with both sera were identified in the PCM-1 molecule. One is between amino acids 312-706 of the PCM-1 autoantigen, and the other is localized between amino acids 1,433-1,787, indicating that the immune response is oligoclonal. The results are important to clarify the mechanism of induction of anticentrosome autoantibodies. The potential diagnostic and prognostic significance of the autoantibodies for subgroups of scleroderma is discussed.

[Studies on the centrosome antiserum from a scleroderma patient]

Using ascites cells as screening system and by means of indirect immunofluorescence microscopy, several antisera against centrosome from scleroderma patients were discovered. Since centrosome is chemically complex cellular structure and the autoimmune antiserum is polyclonal, further investigation was made using one of the antisera against centrosome. L929 cultured cells were also employed for the antigen localisation. It was found that the antiserum decorated microtubules, mitotic spindle, centrosome as well as some nuclear structure. Immunoblots of the cell lysate with the antiserum revealed that in addition to the main bands of tubulin there were several less distinct bands. This result confirmed the indirect immunofluorescence observation.

Centrosomal components immunologically related to tektins from ciliary and flagellar microtubules

Centrosomes are critical for the nucleation and organization of the microtubule cytoskeleton during both interphase and cell division. Using antibodies raised against sea urchin sperm flagellar microtubule proteins, we characterize here the presence and behavior of certain components associated with centrosomes of the surf clam Spisula solidissima and cultured mammalian cells. A Sarkosyl detergent-resistant fraction of axonemal microtubules was isolated from sea urchin sperm flagella and used to produce monoclonal antibodies, 16 of which were specific- or cross-specific for the major polypeptides associated with this microtubule fraction: tektins A, B and C, acetylated alpha-tubulin, and 77 and 83 kDa polypeptides. By 2-D isoelectric focussing/SDS polyacrylamide gel electrophoresis the tektins separate into several polypeptide spots. Identical spots were recognized by monoclonal and polyclonal antibodies against a given tektin, indicating that the different polypeptide spots are isoforms or modified versions of the same protein. Four independently derived monoclonal anti-tektins were found to stain centrosomes of S. solidissima oocytes and CHO and HeLa cells, by immunofluorescence microscopy. In particular, the centrosome staining of one monoclonal antibody specific for tektin B (tekB3) was cell-cycle-dependent for CHO cells, i.e. staining was observed only from early prometaphase until late anaphase. By immuno-electron microscopy tekB3 specifically labeled material surrounding the centrosome, whereas a polyclonal anti-tektin B recognized centrioles as well as the centrosomal material throughout the cell cycle. Finally, by immunoblot analysis tekB3 stained polypeptides of 48–50 kDa in isolated spindles and centrosomes from CHO cells.