The identification of mammalian centrosomal antigens using human autoimmune anticentrosome antisera

Navigating centriolar satellites: the role of PCM1 in cellular and organismal processes

Centriolar satellites are ubiquitous membrane-less organelles that play critical roles in numerous cellular and organismal processes. They were initially discovered through electron microscopy as cytoplasmic granules surrounding centrosomes in vertebrate cells. These structures remained enigmatic until the identification of pericentriolar material 1 protein (PCM1) as their molecular marker, which has enabled their in-depth characterization. Recently, centriolar satellites have come into the spotlight due to their links to developmental and neurodegenerative disorders. This review presents a comprehensive summary of the major advances in centriolar satellite biology, with a focus on studies that investigated their biology associated with the essential scaffolding protein PCM1. We begin by exploring the molecular, cellular, and biochemical properties of centriolar satellites, laying the groundwork for a deeper understanding of their functions and mechanisms at both cellular and organismal levels. We then examine the implications of their dysregulation in various diseases, particularly highlighting their emerging roles in neurodegenerative and developmental disorders, as revealed by organismal models of PCM1. We conclude by discussing the current state of knowledge and posing questions about the adaptable nature of these organelles, thereby setting the stage for future research.

Human autoantibodies as reagents in biomedical research

Abstract  Autoantibodies are typically associated with autoimmune diseases. In some instances the association of specific autoantibodies to a specific autoimmune disease have made their detection invaluable in clinical diagnosis. However, certain autoantibodies show no specific disease association and therefore have limited clinical utility. Nevertheless, autoantibodies are powerful tools for identification, characterization, and functional studies of their cognate antoantigens. In addition, the study of autoantibodies and their cognate autoantigens in human disease and in experimental animal models can provide valuable insight into disease mechanisms and the factors that ameliorate or reverse disease. This review will focus on three specific sets of autoantibodies, which were initially selected for investigation purely on the basis of their novel patterns of reactivity. These were observed when they were applied to a diagnostic HEp-2 test slide for antinuclear antibody detection by indirect immunofluorescence. The target autoantigens were identified as the trans-Golgi network protein GOLGA4 (Golgin 245 or p230), the early endosome antigen-1 (EEA1) and a yet to be identified and fully characterized phosphoepitope(s) restricted to chromosomal arms of condensed mitotic/meiotic chromosomes (MCA1). This laboratory has exploited sera which are reactive to these autoantigens for their identification and characterization, and in functional studies. This review highlights the uses of autoantibodies that may have limited diagnostic or prognostic utility, but are nonetheless novel reagents in the prosecution of molecular cell biology.

Centrosome dysfunction contributes to chromosome instability, chromoanagenesis, and genome reprograming in cancer

The unique ability of centrosomes to nucleate and organize microtubules makes them unrivaled conductors of important interphase processes, such as intracellular payload traffic, cell polarity, cell locomotion, and organization of the immunologic synapse. But it is in mitosis that centrosomes loom large, for they orchestrate, with clockmaker's precision, the assembly and functioning of the mitotic spindle, ensuring the equal partitioning of the replicated genome into daughter cells. Centrosome dysfunction is inextricably linked to aneuploidy and chromosome instability, both hallmarks of cancer cells. Several aspects of centrosome function in normal and cancer cells have been molecularly characterized during the last two decades, greatly enhancing our mechanistic understanding of this tiny organelle. Whether centrosome defects alone can cause cancer, remains unanswered. Until recently, the aggregate of the evidence had suggested that centrosome dysfunction, by deregulating the fidelity of chromosome segregation, promotes and accelerates the characteristic Darwinian evolution of the cancer genome enabled by increased mutational load and/or decreased DNA repair. Very recent experimental work has shown that missegregated chromosomes resulting from centrosome dysfunction may experience extensive DNA damage, suggesting additional dimensions to the role of centrosomes in cancer. Centrosome dysfunction is particularly prevalent in tumors in which the genome has undergone extensive structural rearrangements and chromosome domain reshuffling. Ongoing gene reshuffling reprograms the genome for continuous growth, survival, and evasion of the immune system. Manipulation of molecular networks controlling centrosome function may soon become a viable target for specific therapeutic intervention in cancer, particularly since normal cells, which lack centrosome alterations, may be spared the toxicity of such therapies.

Centriolar satellites: busy orbits around the centrosome

Since its first description by Theodor Boveri in 1888, the centrosome has been studied intensely, and it revealed detailed information about its structure, molecular composition and its various functions. The centrosome consists of two centrioles, which generally appear in electron microscopy as barrel-shaped structures usually composed of nine microtubule triplets. An amorphous mass of pericentriolar material surrounds the centrioles and accumulates many proteins important for the integrity and function of centrosomes, such as the γ-tubulin ring complex (γ-TuRC) that mediates microtubule nucleation and capping. In animal somatic cells, the centrosome generally accounts for the major microtubule organizing center, and the duplicated pair of centrosomes determines the poles of the microtubule-based mitotic spindle. Despite detailed insights into the centrosome's structure and function, it has been a complete mystery until a few years ago how centrosomes duplicate and assemble. Moreover, it is still largely unclear if and how centrosomal proteins or protein complexes are exchanged, replaced or qualitatively altered. Previously identified cytoplasmic granules, named "pericentriolar" or "centriolar satellites", might fulfil such functions in protein targeting and exchange, and communication between the centrosomes and the cytoplasm. In this review, we summarize current knowledge about the structure, molecular composition and possible roles of the satellites that seem to surround the core of the centrosome in most animal cells.

Neuroanatomical distribution of huntingtin-associated protein 1-mRNA in the male mouse brain

Huntingtin-associated protein 1 (HAP1) was identified as an interactor of the gene product (Huntingtin) responsible for Huntington's disease and found to be a core component of the stigmoid body. Even though HAP1 is highly expressed in the brain, detailed information on HAP1 distribution has not been fully described. Focusing on the neuroanatomical analysis of HAP1-mRNA expression using in situ hybridization histochemistry, the present study clarified its detailed regional distribution in the entire mouse brain. Mouse HAP1 (Hap1)-mRNAs were abundantly expressed in the limbic-related forebrain regions and midline/periventricular brainstem regions including the olfactory bulb, limbic-associated cortices, hippocampus, septum, amygdala, bed nucleus of the stria terminalis, preoptico-hypothalamic regions, central gray, raphe nuclei, locus coeruleus, parabrachial nuclei, nucleus of the solitary tract, and area postrema. In contrast, little expression was detected in the striatum and thalamus, implying that Hap1 is associated with neurodegeneration-sparing regions rather than target lesions in Huntington's disease. The distribution pattern, resembling that of the stigmoid body, suggests that HAP1 and the stigmoid body are implicated in protection from neuronal death rather than induction of neurodegeneration in Huntington's disease, and that they play an important role in integrating instinct behaviors and underlying autonomic, visceral, arousal, drive, memory, and neuroendocrinergic functions, particularly during extensive homeostatic or emotional processes. These data will provide an important morphological base for a future understanding of functions of HAP1 and the stigmoid body in the brain.

Molecular and functional analysis of the dictyostelium centrosome

The centrosome is a nonmembranous, nucleus-associated organelle that functions not only as the main microtubule-organizing center but also as a cell cycle control unit. How the approximately 100 different proteins that make up a centrosome contribute to centrosome function is still largely unknown. Considerable progress in the understanding of centrosomal functions can be expected from comparative cell biology of morphologically different centrosomal structures fulfilling conserved functions. Dictyostelium is an alternative model organism for centrosome research in addition to yeast and animal cells. With the elucidation of morphological changes and dynamics of centrosome duplication, the establishment of a centrosome isolation protocol, and the identification of many centrosomal components, there is a solid basis for understanding the biogenesis and function of this fascinating organelle. Here we give an overview of the prospective protein inventory of the Dictyostelium centrosome based on database searches. Moreover, we focus on the comparative cell biology of known components of the Dictyostelium centrosome including the gamma-tubulin complex and the homologues of centrin, Nek2, XMAP215, and EB1.

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.

Non-membranous granular organelle consisting of PCM-1: subcellular distribution and cell-cycle-dependent assembly/disassembly

Centriolar satellites were initially identified as electrondense spherical granules, approximately 70-100 nm in diameter, localized around the centrosomes. We have previously identified pericentriolar material 1 (PCM-1), with a molecular mass of approximately 230 kDa, as a component of centriolar satellites. We now show by immunofluorescence microscopy that these granules are not only concentrated around centrioles but also scattered throughout the cytoplasm in various types of mouse cells, leading us tentatively to call them 'PCM-1 granules'. We then found that, when overexpressed, PCM-1 molecules lacking their C-terminal region bound directly with each other through two distinct regions to form large aggregates, which then recruited endogenous PCM-1. These large aggregates as well as endogenous PCM-1 granules appear to be disassembled during mitosis, and reassembled when the cells entered interphase. These findings suggest that PCM-1 granules are formed by self-aggregation of PCM-1 and that this self-aggregation is regulated in a cell-cycle-dependent manner. Furthermore, we found that PCM-1 granules are distinct from pericentrin-containing granules, and that these two distinct types of granular structures are frequently associated with each other within the cytoplasm. These findings are discussed with special reference to the possible physiological functions of PCM-1 granules.

Arrest of cell cycle progression during first interphase in murine zygotes microinjected with anti-PCM-1 antibodies

To investigate the function of the centrosome protein PCM-1, antibodies against PCM-1 were microinjected into either germinal vesicle stage meiotic oocytes or fertilized mouse eggs, and cell cycle progression events (i.e., microtubule assembly, chromosome and centrosome organization, meiotic maturation) were assayed. These studies determined that microinjected PCM-1 antibodies arrested cell cycle progression, with anti-PCM-1 arresting fertilized eggs at the pronucleate stage when injected during G1. Analysis of the injected eggs determined that centrosome disruption and microtubule cytaster disorganization accompanied the cell cycle arrest. Anti-PCM-1 blocked neither pronuclear centration, completion of mitosis when microinjected into zygotes at G2, nor meiotic maturation when microinjected into immature oocytes. These results identify a novel role for PCM- 1 in cell cycle regulation, and indicate that PCM-1 must fulfill an essential function for cells to complete interphase.

Centrosome replication in somatic cells: the significance of G1 phase

Proper cell division requires that the cell be able to form a bipolar spindle during mitosis. To achieve this, the centrosome must be replicated accurately during interphase. Our understanding of the mechanisms that allow centrosome doubling to be coordinated with other cell cycle progression processes is advancing at a rapid pace. Several different experimental systems have been developed that are allowing detailed studies of centrosome replication. For example, the identification of mutants in yeast that are unable to duplicate the SPB accurately during interphase has provided important insights concerning centrosome duplication. In addition, intact embryonic cells and extracts prepared from unfertilized eggs are powerful tools for investigating the molecular regulation of centrosome doubling during the cell cycle. Many of the observations from these embryonic systems are directly applicable to understanding centrosome doubling in somatic cells. Finally, transgenic mouse models and cultured mammalian cell systems have been developed for analyzing the regulation of centrosome doubling in cells with more complex cell cycles. As our knowledge of the cell cycle advances, particularly our understanding of the intricate series of events that must occur for somatic cells to traverse G1 phase, it should be possible to use the systems that have been developed to determine how the replication of the centrosome is coordinated with other cell cycle progression processes. The next few years should see rapid advances in our understanding of this critical cell biological process.

Kendrin/pericentrin-B, a centrosome protein with homology to pericentrin that complexes with PCM-1

The centrosome is responsible for nucleating microtubules and performing other cellular roles. To define the organization of the centrosome more completely, a human anti-centrosome serum was used to screen a human cDNA library, and a cDNA encoding a >350 kDa centrosome protein was identified. Sequence analyses revealed that this novel centrosome protein contains two coiled-coil domains bounded by non-coiled regions. The N-terminal region of the protein, named pericentrin-B, shares 61% identity (75% similarity) with pericentrin, suggesting an evolutionary relationship between these proteins. Antibodies against pericentrin-B stain centrosomes at all stages of the cell cycle, and pericentrin-B remains associated with centrosomes following microtubule depolymerization. Immunodepletion of neither pericentrin-B nor PCM-1 from cellular extracts inhibited the ability of salt-stripped centrosomes to recover microtubule nucleation potential, demonstrating that neither protein plays a key role in microtubule nucleation processes. Moreover, the binding of both PCM-1 and pericentrin-B with salt-stripped centrosomes required intact microtubules, demonstrating that the association of PCM-1 and pericentrin-B with centrosomes is a late event in the centrosome maturation process. Finally, pericentrin-B and PCM-1 coimmunoprecipitate, suggesting that PCM-1 and pericentrin-B form a functional complex in cells. This observation may help to explain the generation of anti-centrosome autoantibodies in certain autoimmune patients and may be important for centrosome function.

Role for microtubules in centrosome doubling in Chinese hamster ovary cells

The centrosome must be replicated once, and only once, during each cell cycle. To achieve this somatic cells need to synthesize centrosome proteins, target those centrosome proteins to the parental centrosome, and then assemble the centrosome subunits into a functional organelle. The mechanisms that underlie each of these processes are not known. Studies were performed to investigate whether cellular microtubules are involved in centrosome doubling events. For these experiments, CHO cells were arrested in either hydroxyurea (HU) alone or in HU plus a microtubule inhibitor for 3640 h. The cells then were induced to enter mitosis and the numbers of spindle poles/centrosomes were counted following processing of the cells for immunofluorescence microscopy using anticentrosome antiserum. These studies demonstrated that centrosome replication events occurred in cells arrested with either HU alone or HU and taxol while centrosome replication did not occur in cells treated with HU and either nocodazole or colcemid. Immunoblot analysis determined that centrosome proteins were synthesized in HU/nocodazole-arrested cells and demonstrated that the role of microtubules in the centrosome replication process is not to ensure the synthesis of centrosome subunits. Rather, our results suggest that microtubules may be involved in the transport/targeting of centrosome subunits to the parental centrosome during duplication events. For microtubules to contribute to the transport of centrosome subunits during centrosome doubling, centrosome subunits would need to be able to bind to microtubules. To test this, co-sedimentation studies were performed and it was determined that the centrosome proteins, though overproduced under these conditions, remained soluble in HU/nocodazole-treated cells and co-pelleted with taxol-stabilized microtubules in the presence of GTP and AMP-PNP. Moreover, co-sedimentation of one of the centrosome proteins, PCM-1, with microtubules could be inhibited by pre-incubation of extracts with antibodies against dynactin. Together, these data suggest that during centrosome replication in somatic mammalian cells, PCM-1, and perhaps other centrosome components, are targeted to the centrosome via transport along microtubules by motor complexes that include dynein/dynactin.

Molecular characteristics of the centrosome

As an organizer of the microtubule cytoskeleton in animals, the centrosome has an important function. From the early light microscopic observation of the centrosome to examination by electron microscopy, the centrosome field is now in an era of molecular identification and precise functional analyses. Tables compiling centrosomal proteins and reviews on the centrosome are presented here and demonstrate how active the field is. However, despite this intense research activity, many classical questions are still unanswered. These include those regarding the precise function of centrioles, the mechanism of centrosome duplication and assembly, the origin of the centrosome, and the regulation and mechanism of the centrosomal microtubule nucleation activity. Fortunately, these questions are becoming elucidated based on experimental data discussed here. Given the fact that the centrosome is primarily a site of microtubule nucleation, special focus is placed on the process of microtubule nucleation and on the regulation of centrosomal microtubule nucleation capacity during the cell cycle and in some tissues.

GADD45 induction of a G2/M cell cycle checkpoint

G1/S and G2/M cell cycle checkpoints maintain genomic stability in eukaryotes in response to genotoxic stress. We report here both genetic and functional evidence of a Gadd45-mediated G2/M checkpoint in human and murine cells. Increased expression of Gadd45 via microinjection of an expression vector into primary human fibroblasts arrests the cells at the G2/M boundary with a phenotype of MPM2 immunopositivity, 4n DNA content and, in 15% of the cells, centrosome separation. The Gadd45-mediated G2/M arrest depends on wild-type p53, because no arrest was observed either in p53-null Li-Fraumeni fibroblasts or in normal fibroblasts coexpressed with p53 mutants. Increased expression of cyclin B1 and Cdc25C inhibited the Gadd45-mediated G2/M arrest in human fibroblasts, indicating that the mechanism of Gadd45-mediated G2/M checkpoint is at least in part through modulation of the activity of the G2-specific kinase, cyclin B1/p34(cdc2). Genetic and physiological evidence of a Gadd45-mediated G2/M checkpoint was obtained by using GADD45-deficient human or murine cells. Human cells with endogenous Gadd45 expression reduced by antisense GADD45 expression have an impaired G2/M checkpoint after exposure to either ultraviolet radiation or methyl methanesulfonate but are still able to undergo G2 arrest after ionizing radiation. Lymphocytes from gadd45-knockout mice (gadd45 -/-) also retained a G2/M checkpoint initiated by ionizing radiation and failed to arrest at G2/M after exposure to ultraviolet radiation. Therefore, the mammalian genome is protected by a multiplicity of G2/M checkpoints in response to specific types of DNA damage.

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.

Centrosome structure and function is altered by chloral hydrate and diazepam during the first reproductive cell cycles in sea urchin eggs

This paper explores the mode of action of the tranquillizers chloral hydrate and diazepam during fertilization and mitosis of the first reproductive cell cycles in sea urchin eggs. Most striking effects of these drugs are the alteration of centrosomal material and the abnormal microtubule configurations during exposure and after recovery from the drugs. This finding is utilized to study the mechanisms of centrosome compaction and decompaction and the dynamic configurational changes of centrosomal material and its interactions with microtubules. When 0.1% chloral hydrate or 350-750 microM diazepam is applied at specific phases during the first cell cycle of sea urchin eggs, expanded centrosomal material compacts at distinct regions and super-compacts into dense spheres while microtubules disassemble. When eggs are treated before pronuclear fusion, centrosomal material aggregates around each of the two pronuclei while microtubules disappear. Upon recovery, atypical asters oftentimes with multiple foci are formed from centrosomal material surrounding the pronuclei which indicates that the drugs have affected centrosomal material and prevent it from functioning normally. Electron microscopy and immunofluorescence studies with antibodies that routinely stain centrosomes in sea urchin eggs (4D2; and Ah-6) depict centrosomal material that is altered when compared to control cells. This centrosomal material is not able to reform normal microtubule patterns upon recovery but will form multiple asters around the two pronuclei. When cells are treated with 0.1% chloral hydrate or 350-750 microM diazepam during mitosis, the bipolar centrosomal material becomes compacted and aggregates into multiple dense spheres while spindle and polar microtubules disassemble. With increased incubation time, the smaller dense centrosome particles aggregate into bigger and fewer spheres. Upon recovery, unusual irregular microtubule configurations are formed from centrosomes that have lost their ability to reform normal mitotic figures. These results indicate that chloral hydrate and diazepam affect centrosome structure which results in the inability to reform normal microtubule formations and causes abnormal fertilization and mitosis.

The human p167 gene encodes a unique structural protein that contains centrosomin A homology and associates with a multicomponent complex

The characterization of novel cytoplasmic, structural, and enzymatic proteins has been enhanced by a panel of monoclonal antibodies specific for protein substrates of transforming and nontransforming c-Src mutants. These protein substrates have included the focal adhesion kinase (FAK), cortactin, AFAP-110, p120CAS, and p130CAS. The monoclonal antibody 4G8 was generated as part of this panel of antibodies and was used to isolate the human gene for a 167-kD polypeptide. The cDNA sequence is 5,238 nucleotides in length with a predicted open reading frame consisting of 1,382 amino acids. The polypeptide is largely hydrophilic and highly charged. The central region of p167 has 88% identity with the entire 278-amino-acid encoded sequence of the murine centrosomin A gene. The carboxyl third of p167 contains a unique cluster of 10 amino acid repeats with the consensus sequence (A/M)DDDRGPRRG. The p167 protein was found primarily in the cytoplasm of lymphocytes and is part of a multicomponent protein complex with prominent members of 167, 120, 64, 45, 40, 38, and 25 kD. Finally, we illustrate the conservation of p167 and its associated complex, and demonstrate its expression in different human tissues and cell types. The data suggest that p167 is novel and has an important cellular function as a cytoplasmic structural protein.

M-phase specific centrosome-microtubule alterations induced by the fungicide MBC in human granulosa cells

The mitostatic action of the commonly used fungicide methyl 2-benzimidazolecarbamate (MBC) was evaluated in primary cultures of human ovarian granulosa cells with respect to the organization and stability of spindle microtubules and mitotic centrosomes. MBC caused metaphase arrest and abnormal chromosome organization following a 3-15 h treatment at a concentration of 30 microM. While microtubules were retained in MBC-treated cells, alterations in spindle shape and microtubule composition were noted. Exposure to MBC resulted in an increased number of spindle poles associated with chromosomes displaced from the metaphase plate. A gradual increase from tri- to multipolar spindles was noted with prolonged treatment although a relatively constant fraction (50%) of bipolar spindles was maintained. In non-dividing cells, MBC had no effect on microtubule organization. Analysis of mitotic figures by immunofluorescence microscopy showed a reduction in interpolar and astral microtubules in response to MBC treatment while acetylated kinetochore microtubules were retained and their plus-ends were attached to metaphase chromosomes. In multipolar spindles, analysis of microtubule organizing centers (MTOCs) with antisera to stable centrosomal markers (SPJ and 5051) revealed that only poles associated with displaced chromosomes retained these markers. In contrast, transient centrosome markers (NuMA and centrophilin) were localized to all poles of multipolar spindles. Since MBC alters centrosome organization during mitosis, the results suggest that one mechanism of action of this agent is impairment of spindle microtubule dynamics at the centrosome.

The centrosome in animal cells and its functional homologs in plant and yeast cells

The centrosome is the principal microtubule-organizing center in mammalian cells. Until recently, the centrosome could only be studied at the ultrastructural level and defined as a functional entity. However, during the past decade a number of clever experimental strategies have been used to identify numerous molecular components of the centrosome. The identification of biochemical subunits of the centrosome complex has allowed the centrosome to be investigated in much more detail, resulting in important advances being made in our understanding of microtubule nucleation events, spindle formation, the assembly and replication of the centrosome, and the nature of the microtubule-organizing centers in plant cells and lower eukaryotes. The next several years should see additional rapid progress in our understanding of the microtubule cytoskeleton as investigators begin to assign functions to the centrosome proteins that have already been reported and as additional centrosome components are discovered.

Autoimmunity to the cell cycle-dependent centromere protein p330d/CENP-F in disorders associated with cell proliferation

p330d/CENP-F is a novel proliferation-associated and cell cycle-dependent centromere autoantigen which appears to play a very important role in mitotic progression. As an initial step in exploring the clinical and biological significance of autoantibodies to this protein, we evaluated the clinical histories of 26 patients producing these antibodies. The antibodies were detected by both indirect immunofluorescence microscopy (IIF) and Western blotting. All the sera contained anti-p330d/CENP-F IgG antibodies, with an average titer by IIF of 1:6,917 (range 1:160 to 1:20,480). Most of the patients had disorders associated with abnormal or increased cell proliferation at the time the anti-p330d/CENP-F antibodies were detected. These included cancers of various types (14), chronic liver disease (3), chronic rejection of renal allografts (2), and Crohn's disease (1). The average IIF titer of the anti-p330d/CENP-F antibodies in the patients with cancer, 1:10,103, was significantly higher than the average titer in non-cancer patients, 1:3,200 (P = 0.008). Autoimmunity to p330d/CENP-F appeared not to be associated with rheumatic diseases, in particular scleroderma, since only three of the 26 patients had rheumatic disease and the antibodies were not detected by IIF in a group of 351 patients with scleroderma and related disorders. Our findings, although retrospective and limited to a relatively small number of patients, point to the hypothesis that autoimmunity to p330d/CENP-F could be related to events involving increased or abnormal cell proliferation.

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.

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.

Nuf2, a spindle pole body-associated protein required for nuclear division in yeast

The NUF2 gene of the yeast Saccharomyces cerevisiae encodes an essential 53-kd protein with a high content of potential coiled-coil structure similar to myosin. Nuf2 is associated with the spindle pole body (SPB) as determined by coimmunofluorescence with known SPB proteins. Nuf2 appears to be localized to the intranuclear region and is a candidate for a protein involved in SPB separation. The nuclear association of Nuf2 can be disrupted, in part, by 1 M salt but not by the detergent Triton X-100. All Nuf2 can be removed from nuclei by 8 M urea extraction. In this regard, Nuf2 is similar to other SPB-associated proteins including Nufl/SPC110, also a coiled-coil protein. Temperature-sensitive alleles of NUF2 were generated within the coiled-coil region of Nuf2 and such NUF2 mutant cells rapidly arrest after temperature shift with a single undivided or partially divided nucleus in the bud neck, a shortened mitotic spindle and their DNA fully replicated. In sum, Nuf2 is a protein associated with the SPB that is critical for nuclear division. Anti-Nuf2 antibodies also recognize a mammalian 73-kd protein and display centrosome staining of mammalian tissue culture cells suggesting the presence of a protein with similar function.

PCM-1, A 228-kD centrosome autoantigen with a distinct cell cycle distribution

We report the identification and primary sequence of PCM-1, a 228-kD centrosomal protein that exhibits a distinct cell cycle-dependent association with the centrosome complex. Immunofluorescence microscopy using antibodies against recombinant PCM-1 demonstrated that PCM-1 is tightly associated with the centrosome complex through G1, S, and a portion of G2. However, late in G2, as cells prepare for mitosis, PCM-1 dissociates from the centrosome and then remains dispersed throughout the cell during mitosis before re-associating with the centrosomes in the G1 phase progeny cells. These results demonstrate that the pericentriolar material is a dynamic substance whose composition can fluctuate during the cell cycle.

Microtubule organizing centers and gamma-tubulin

The polar assembly of cellular microtubules is organized by microtubule organizing centers (MTOCs). Eukaryotic cells across different species, and different cell types within single species, have morphologically diverse MTOCs, which have the common function of organizing microtubule arrays by initiating microtubule assembly and anchoring microtubules by their slow-growing 'minus' ends, thus ensuring that the rapidly growing 'plus' ends extend distally. The past few years have witnessed a variety of approaches aimed at defining the molecular components of the MTOC that are responsible for regulating microtubule assembly by defining molecules common to all MTOCs.

A protein related to brain microtubule-associated protein MAP1B is a component of the mammalian centrosome

The centrosome is the main microtubule organizing center of mammalian cells. Structurally, it is composed of a pair of centrioles surrounded by a fibro-granular material (the pericentriolar material) from which microtubules are nucleated. However, the nature of centrosomal molecules involved in microtubules nucleation is still obscure. Since brain microtubule-associated proteins (MAPs) lower the critical tubulin concentration required for microtubule nucleation in tubulin solution in vitro, we have examined their possible association with centrosomes. By immunofluorescence, monoclonal and polyclonal antibodies raised against MAP1B stain the centrosome in cultured cells as well as purified centrosomes, whereas antibodies raised against MAP2 give a completely negative reaction. The MAP1B-related antigen is localized to the pericentriolar material as revealed by immunoelectron microscopy. In preparations of purified centrosomes analyzed on poly-acrylamide gels, a protein that migrates as brain MAP1B is present. After blotting on nitrocellulose, it is decorated by anti-MAP1B antibodies and the amino acid sequence of proteolytic fragments of this protein is similar to brain MAP1B. Moreover, brain MAP1B and its centrosomal counterpart share the same phosphorylation features and have similar peptide maps. These data strongly suggest that a protein homologue to MAP1B is present in centrosomes and it is a good candidate for being involved in the nucleating activity of the pericentriolar material.

Cell cycle-associated autoantibodies: markers for autoimmunity and probes for molecular cell biology

Antinuclear autoantibodies are useful diagnostic markers for systemic autoimmune diseases and as probes for the molecular cell biology of nuclear proteins. Here, we review a subset of autoantibodies to nuclear and cytoplasmic proteins involved in the cell cycle. We propose a classification of these autoantibodies into S-phase (DNA Synthesis) and M-phase (Mitosis) autoantibodies. S-phase autoantibodies are represented by autoantibodies to PCNA (Proliferating Cell Nuclear Antigen), the auxiliary protein of DNA polymerase delta. M-phase autoantibodies are represented by autoantibodies to mitotic spindle components viz. centrosomes, condensed chromosomes, centromeres, mitotic spindle proper and intercellular bridge. We have included autoantibodies to nuclear lamins as M-phase autoantibodies as lamins play a key role in reversible breakdown and reformation of nuclear membranes during mitosis. The usefulness of these autoantibodies as diagnostic markers in systemic autoimmune disease is tempered by their presence in patients with "atypical" autoimmune diseases and in normal individuals. However, as molecular probes, they have proven to be unique and invaluable tools for shedding new light on the workings of the cell cycle.

Unravelling the tangled web at the microtubule-organizing center

The last year has seen dramatic progress in the use of genetic and biochemical approaches to identify microtubule-organizing center components. The use of vertebrate and invertebrate egg extracts has allowed the development of novel assays for centrosome duplication and activation. A variety of mutations in fungi are being used to sort out the pathway of spindle pole body duplication.