Heat shock alters centrosome organization leading to mitotic dysfunction and cell death

To identify the cellular target(s) responsible for thermal killing in the G₁ phase of the cell cycle, synchronous cultures of Chinese hamster ovary cells (CHO) were heat shocked and studied for one cell cycle by time-lapse videomicroscopy and immunocytochemistry. At the first mitosis post-heating, the fraction of cells giving rise to multinucleated progeny approximately equaled the nonclonogenic fraction. In addition, the cells yielding multincleated progeny were delayed in prophase-metaphase relative to the cells yielding two uninucleated progeny (clonogenic cells). To study the basis for the delay in prophase-metaphase and subsequent formation of multinucleated cells, cells in mitosis were examined by immunofluorescence for spindle abnormalities. Multipolar mitotic spindles and chromosome misalignment were induced by heat. All multiple spindle poles induced by heat stained for pericentriolar material (PCM), the microtubule nucleating material of centrosomes. Heated cells in mitosis also contained additional foci of PCM which were not associated with the spindle. Cells made thermotolerant by a nonlethal heat shock were resistant to both thermal killing and the induction of multiple foci of PCM. Quantitative analysis revealed a good correlation between the fraction of cells with multipolar spindles, the fraction with more than two foci of PCM, and the nonclonogenic fraction. These data indicate that heat-induced alterations to the PCM of centrosomes resulted in multipolar mitotic spindles, delay in prophase-metaphase, and formation of multinucleated cells which were nonclonogenic. These results identify the centrosome as a G₁ target for cell killing. © 1993 Wiley-Liss, Inc.     

Centrosome reduction during gametogenesis and its significance

Animal spermatids and primary oocytes initially have typical centrosomes comprising pairs of centrioles and pericentriolar fibrous centrosomal proteins. These somatic cell-like centrosomes are partially or completely degenerated during gametogenesis. Centrosome reduction during spermiogenesis comprises attenuation of microtubule nucleation function, loss of pericentriolar material, and centriole degeneration. Centrosome reduction during oogenesis is due to complete degeneration of centrioles, which leads to dispersal of the pericentriolar centrosomal proteins, loss of replicating capacity of the spindle poles, and switching to acentrosomal mode of spindle organization. Oocyte centrosome reduction plays an important role in preventing parthenogenetic embryogenesis and balancing centrosome number in the embryonic cells.     

Polo-like kinase 1 regulates Nlp,a centrosome protein involved in microtubule nucleation

In animal cells, most microtubules are nucleated at centrosomes. At the onset of mitosis, centrosomes undergo a structural reorganization, termed maturation, which leads to increased microtubule nucleation activity. Centrosome maturation is regulated by several kinases, including Polo-like kinase 1 (Plk1). Here, we identify a centrosomal Plk1 substrate, termed Nlp (ninein-like protein), whose properties suggest an important role in microtubule organization. Nlp interacts with two components of the gamma-tubulin ring complex and stimulates microtubule nucleation. Plk1 phosphorylates Nlp and disrupts both its centrosome association and its gamma-tubulin interaction. Overexpression of an Nlp mutant lacking Plk1 phosphorylation sites severely disturbs mitotic spindle formation. We propose that Nlp plays an important role in microtubule organization during interphase, and that the activation of Plk1 at the onset of mitosis triggers the displacement of Nlp from the centrosome, allowing the establishment of a mitotic scaffold with enhanced microtubule nucleation 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 ?-tubulin, recruiting it to ectopic (non-centrosomal) 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.     

Centrosome Function: Sometimes Less Is More

Tight regulation of centrosome duplication is critical to ensure that centrosome number doubles once and only once per cell cycle. Superimposed onto this centrosome duplication cycle is a functional centrosome cycle in which they alternate between phases of quiescence and robust microtubule (MT) nucleation and MT-anchoring activities. In vertebrate cycling cells, interphase centrioles accumulate less pericentriolar material (PCM), reducing their MT nucleation capacity. In mitosis, centrosomes mature, accumulating more PCM to increase their nucleation and anchoring capacities to form robust MT asters. Interestingly, functional cycles of centrosomes can be altered to suit the cell's needs. Some interphase centrosomes function as a microtubule-organizing center by increasing their ability to anchor MTs to form centrosomal radial arrays. Other interphase centrosomes maintain their MT nucleation capacity but reduce/eliminate their MT-anchoring capacity. Recent work demonstrates that Drosophila cells take this to the extreme, whereby centrioles lose all detectable PCM during interphase, offering an explanation as to how centrosome-deficient flies develop to adulthood. Drosophila stem cells further modify the functional cycle by differentially regulating their two centrioles – a situation that seems important for stem cell asymmetric divisions, as misregulation of centrosome duplication in stem/progenitor cells can promote tumor formation. Here, we review recent findings that describe variations in the functional cycle of centrosomes.     

Microtubule release and capture in epithelial cells.

Many differentiated cells including polarised epithelial cells display a non-radial, apico-basal microtubule array. In some cells the centrosome disassembles and new nucleating sites are created at more appropriate locations. In others the centrosome remains, but relatively few microtubules radiate from it's immediate environs. Instead, the majority of the microtubule minus-ends are associated with apical cell surface sites. Centrosomal microtubule release and capture is evidently a mechanism exploited by some polarised epithelial cells as a means of producing non-centrosomal, apico-basal microtubule arrays. This involves microtubule nucleation at the centrosome, release and subsequent translocation and capture at the apical sites. Two functionally distinct centrosomal complexes dedicated to the control of microtubule nucleation and anchorage have been suggested to be essential and universal features of all centrosomes. The centrosomal proteins ninein and R2 are potential microtubule anchoring proteins and their discovery has exciting implications for centrosomal organisation and microtubule positioning in cells.     

Cep72 regulates the localization of key centrosomal proteins and proper bipolar spindle formation

Microtubule‐nucleation activity and structural integrity of the centrosome are critical for various cellular functions. The γ‐tubulin ring complexes (γTuRCs) localizing to the pericentriolar matrix (PCM) of the centrosome are major sites of microtubule nucleation. The PCM is thought to be created by two cognate large coiled‐coil proteins, pericentrin/kendrin and CG‐NAP/AKAP450, and its stabilization by Kizuna is essential for bipolar spindle formation. However, the mechanisms by which these proteins are recruited and organized into a proper structure with microtubule‐organizing activity are poorly understood. Here we identify a centrosomal protein Cep72 as a Kizuna‐interacting protein. Interestingly, Cep72 is essential for the localization of CG‐NAP and Kizuna. Cep72 is also involved in γTuRC recruitment to the centrosome and CG‐NAP confers the microtubule‐nucleation activity on the γTuRCs. During mitosis, Cep72‐mediated microtubule organization is important for converging spindle microtubules to the centrosomes, which is needed for chromosome alignment and tension generation between kinetochores. Our findings show that Cep72 is the key protein essential for maintaining microtubule‐organizing activity and structural integrity of the centrosome.     

中心体在配子与早期胚胎中的遗传模式及其在辅助生殖中的意义

中心体由中心粒周围物质(PCM)围绕一对相互垂直的圆柱形中心粒组成,是哺乳动物细胞内主要的微管组织中心,在细胞分裂时发挥重要的作用。中心体以半保留的形式复制,在精子及卵母细胞发生时会发生减灭,精子和卵母细胞各保留部分中心体的成分,在受精后重新组成功能完整中心体。精子的中心体结构发生异常将会导致男性的不育,卵母细胞的老化也会引起中心体蛋白缺陷,从而产生纺锤体结构异常,并导致受精及早期胚胎发育异常。中心体的结构与功能,与人类受精及胚胎发育相关密切,在辅助生殖中具有重要意义。     

Structural alterations of the mitotic apparatus induced by the heat shock response in Drosophila cells

The general architecture of the mitotic apparatus was studied at the ultrastructural level in Drosophila cultured cells. Its two main characteristics are a very polarized spindle and a strong compartmentalization, ensured by large remnants of the nuclear envelope. Such compartmentalization has previously been reported for the rapid syncytial divisions of the early embryo; a similar finding in these cells with a long cycle strongly suggests that this organization constitutes a general mechanism for mitosis in Drosophila. We followed the modifications of these structures after a heat shock of 20, 50 or 120 min at 37°C. Contrary to interphase cells, mitotic cells appear very sensitive to hyperthermia. This stress treatment induced a disruption of the mitotic spindle, a reappearance and an extension of the Golgi apparatus, an inactivation of microtubule nucleation and a disorganization of the centrosome. This organelle seems the first to be affected by the heat shock response. The centrosome is not only inactivated, but also is structurally affected. During the recovery phase after heat stress, the mitotic cells presented a remarkable ring-shaped accumulation of electrondense material around the centrioles. We conclude that in Drosophila cells the mitotic phase, and more specifically the centrosome, are targets of the stress response.     

Higher order structure of the PCM adjacent to the centriole

The centrosome is the major microtubule organizing center in most animal cells. This cytoplasmic organelle consists of two components : a mature centriole (or a pair of centrioles) and a mass of pericentriolar material (PCM). The PCM has been described as either a cloud of material that encases the entire centriole or as a cluster of proteins divided into two subsets, one that adheres to the lateral surface of the centriole and another that extends outward from this region as a cloud of material. In contrast to these protein distribution patterns, we demonstrated in a previous study that a subset of proteins present within the PCM is integrated together to form a tube (PCM tube) with an open and closed end that is duplicated in concert with centrosome duplication. The present study was undertaken to determine if this tubular conformation represents proteins that are confined to the surface of the centriole or if it represents a subset of proteins within the cloud of material that extends outward from the centriole. We document that : (1) the PCM tube represents a portion of the PCM directly associated with the centriole; (2) the PCM tube has a specific and reproducible relationship to the polar structure of the centriole; (3) the tube is a site of cytoplasmic microtubule organization, and has a structure that influences the initial pattern of microtubule assembly within the juxta-centriolar region; and (4) the PCM tube has a structural relationship with respect to the centriole, which allows the simultaneous expression of centriole- and PCM-based functions (e.g., ciliogenesis and cytoplasmic microtubule organization). Based on these findings, we propose a new model of the PCM at the centriole. This model highlights the role played by the proximal end of the centriole in the nucleation and organization of centriole-associated PCM, and indicates that the centrosome has an overall polarity in the region of the centriole.     

Positioning centrosomes and spindle poles: looking at the periphery to find the centre

Centrosome positioning is tightly controlled throughout the cell cycle and probably shares common regulatory mechanisms with spindle-pole positioning. In this article, we detail the possible mechanisms controlling centrosome and spindle positioning in various organisms both in interphase and mitotic cells, and discuss recent findings showing how microtubule plus-end-associated proteins interact with the cell cortex. We suggest that microtubule plus-end complexes simultaneously regulate microtubule dynamics and microtubule anchoring at the cell periphery to allow proper centrosome and spindle-pole positioning.     

Cytoplasmic dynein-mediated assembly of pericentrin and gamma tubulin onto centrosomes

Centrosome assembly is important for mitotic spindle formation and if defective may contribute to genomic instability in cancer. Here we show that in somatic cells centrosome assembly of two proteins involved in microtubule nucleation, pericentrin and gamma tubulin, is inhibited in the absence of microtubules. A more potent inhibitory effect on centrosome assembly of these proteins is observed after specific disruption of the microtubule motor cytoplasmic dynein by microinjection of dynein antibodies or by overexpression of the dynamitin subunit of the dynein binding complex dynactin. Consistent with these observations is the ability of pericentrin to cosediment with taxol-stabilized microtubules in a dynein- and dynactin-dependent manner. Centrosomes in cells with reduced levels of pericentrin and gamma tubulin have a diminished capacity to nucleate microtubules. In living cells expressing a green fluorescent protein-pericentrin fusion protein, green fluorescent protein particles containing endogenous pericentrin and gamma tubulin move along microtubules at speeds of dynein and dock at centrosomes. In Xenopus extracts where gamma tubulin assembly onto centrioles can occur without microtubules, we find that assembly is enhanced in the presence of microtubules and inhibited by dynein antibodies. From these studies we conclude that pericentrin and gamma tubulin are novel dynein cargoes that can be transported to centrosomes on microtubules and whose assembly contributes to microtubule nucleation.     

Remodeling of Centrosomes in Intraspecies and Interspecies Nuclear Transfer Porcine Embryos

Remodeling of donor cell centrosomes and the centrosome-associated cytoskeleton is crucially important for nuclear cloning as centrosomes are the main microtubule organizing centers that play a significant role in cell division and embryo development. Centrosome dysfunctions have been implicated in various diseases including cancer and metabolic disorders and may also play a role in developmental abnormalities that are frequently seen in cloned animals. In the present studies we investigated microtubule organization and the reorganization and fate of the integral centrosome protein γ-tubulin and the centrosome-associated protein centrin in intraspecies (pig oocytes; pig fetal fibroblast cells) and interspecies (pig oocytes; mouse fibroblast cells) reconstructed embryos by using antibodies to γ-tubulin or GFP-centrin transfected mouse fibroblasts as donor cells. Microtubules were stained with antibodies to α-tubulin. In-vitro-fertilized oocytes and nuclear transfer (NT) reconstructed oocytes were sequentially analyzed at different developmental stages. Epi-fluorescence results revealed mitotic spindle abnormalities in NT embryos during the first cell cycle (39.4%, 13/33) which were significantly higher than those in IVF embryos (17.0%, 7/41). The abnormalities in IVF embryos are due to polyspermy while the abnormalities in NT embryos are due to donor cell centrosome dysfunctions. In the NT embryos with abnormal microtubule and centrosome organization, γ-tubulin staining revealed multipolar centrosome foci while DAPI staining showed misalignment of chromosomes. In intraspecies and interspecies embryos the GFP-centrin signal was detected until 3 hrs after fusion. GFP-centrin was not detected at 8 hrs after NT which is consistent with previous results using anti-centrin antibody staining in intraspecies NT porcine embryos. These data indicate that 1) abnormalities in microtubule and centrosome organization are associated with nuclear cloning at a higher rate than observed in IVF embryos; 2) centrosome and cytoskeletal abnormalities in IVF embryos are due to polyspermy while centrosome and cytoskeletal abnormalities in NT embryos are due to donor cell centrosome dysfunctions; and 3) GFP-centrin of the donor cell centrosome provides a reliable marker to follow its fate in intraspecies reconstructed embryos.     

Centrobin regulates centrosome function in interphase cells by limiting pericentriolar matrix recruitment

The amount of pericentriolar matrix at the centrosome is tightly linked to both microtubule nucleation and centriole duplication, although the exact mechanism by which pericentriolar matrix levels are regulated is unclear. Here we show that Centrobin, a centrosomal protein, is involved in regulating these levels. Interphase microtubule arrays in Centrobin-depleted cells are more focused around the centrosome and are less stable than the arrays in control cells. Centrobin-depleted cells initiate microtubule nucleation more rapidly than control cells and exhibit an increase in the number of growing microtubule ends emanating from the centrosome, while the parameters of microtubule plus end dynamics around the centrosome are not significantly altered. Finally, we show that Centrobin depletion results in the increased recruitment of pericentriolar matrix proteins to the centrosome, including γ-tubulin, AKAP450, Kendrin and PCM-1. We propose that Centrobin might regulate microtubule nucleation and organization by controlling the amount of pericentriolar matrix.     

Functional inactivation of centrosome of mouse 3T3 cells by heat shock

The microtubule assembly capacity of centrosome has been tested in mouse 3T3 cells. Following heat shock (30 min. at 43.5 degrees C), centrosomes display a total lack of microtubule nucleation. This stress leads to functional arrest of the organelle. The natural control of the activity of the centrosome is therefore questionable.     

Proper recruitment of gamma-tubulin and D-TACC/Msps to embryonic Drosophila centrosomes requires Centrosomin Motif 1

Centrosomes are microtubule-organizing centers and play a dominant role in assembly of the microtubule spindle apparatus at mitosis. Although the individual binding steps in centrosome maturation are largely unknown, Centrosomin (Cnn) is an essential mitotic centrosome component required for assembly of all other known pericentriolar matrix (PCM) proteins to achieve microtubule-organizing activity at mitosis in Drosophila. We have identified a conserved motif (Motif 1) near the amino terminus of Cnn that is essential for its function in vivo. Cnn Motif 1 is necessary for proper recruitment of gamma-tubulin, D-TACC (the homolog of vertebrate transforming acidic coiled-coil proteins [TACC]), and Minispindles (Msps) to embryonic centrosomes but is not required for assembly of other centrosome components including Aurora A kinase and CP60. Centrosome separation and centrosomal satellite formation are severely disrupted in Cnn Motif 1 mutant embryos. However, actin organization into pseudocleavage furrows, though aberrant, remains partially intact. These data show that Motif 1 is necessary for some but not all of the activities conferred on centrosome function by intact Cnn.     

Nek5 promotes centrosome integrity in interphase and loss of centrosome cohesion in mitosis

Nek5 is a poorly characterized member of the NIMA-related kinase family, other members of which play roles in cell cycle progression and primary cilia function. Here, we show that Nek5, similar to Nek2, localizes to the proximal ends of centrioles. Depletion of Nek5 or overexpression of kinase-inactive Nek5 caused unscheduled separation of centrosomes in interphase, a phenotype also observed upon overexpression of active Nek2. However, separated centrosomes that resulted from Nek5 depletion remained relatively close together, exhibited excess recruitment of the centrosome linker protein rootletin, and had reduced levels of Nek2. In addition, Nek5 depletion led to loss of PCM components, including γ-tubulin, pericentrin, and Cdk5Rap2, with centrosomes exhibiting reduced microtubule nucleation. Upon mitotic entry, Nek5-depleted cells inappropriately retained centrosome linker components and exhibited delayed centrosome separation and defective chromosome segregation. Hence, Nek5 is required for the loss of centrosome linker proteins and enhanced microtubule nucleation that lead to timely centrosome separation and bipolar spindle formation in mitosis.     

CDK5RAP2 is a pericentriolar protein that functions in centrosomal attachment of the gamma-tubulin ring complex

Microtubule nucleation and organization by the centrosome require gamma-tubulin, a protein that exists in a macromolecular complex called the gamma-tubulin ring complex (gammaTuRC). We report characterization of CDK5RAP2, a novel centrosomal protein whose mutations have been linked to autosomal recessive primary microcephaly. In somatic cells, CDK5RAP2 localizes throughout the pericentriolar material in all stages of the cell cycle. When overexpressed, CDK5RAP2 assembled a subset of centrosomal proteins including gamma-tubulin onto the centrosomes or under the microtubule-disrupting conditions into microtubule-nucleating clusters in the cytoplasm. CDK5RAP2 associates with the gammaTuRC via a short conserved sequence present in several related proteins found in a range of organisms from fungi to mammals. The binding of CDK5RAP2 is required for gammaTuRC attachment to the centrosome but not for gammaTuRC assembly. Perturbing CDK5RAP2 function delocalized gamma-tubulin from the centrosomes and inhibited centrosomal microtubule nucleation, thus leading to disorganization of interphase microtubule arrays and formation of anastral mitotic spindles. Together, CDK5RAP2 is a pericentriolar structural component that functions in gammaTuRC attachment and therefore in the microtubule organizing function of the centrosome. Our findings suggest that centrosome malfunction due to the CDK5RAP2 mutations may underlie autosomal recessive primary microcephaly.     

The mammalian SPD-2 ortholog Cep192 regulates centrosome biogenesis

Centrosomes are the major microtubule-organizing centers of mammalian cells. They are composed of a centriole pair and surrounding microtubule-nucleating material termed pericentriolar material (PCM). Bipolar mitotic spindle assembly relies on two intertwined processes: centriole duplication and centrosome maturation. In the first process, the single interphase centrosome duplicates in a tightly regulated manner so that two centrosomes are present in mitosis. In the second process, the two centrosomes increase in size and microtubule nucleation capacity through PCM recruitment, a process referred to as centrosome maturation. Failure to properly orchestrate centrosome duplication and maturation is inevitably linked to spindle defects, which can result in aneuploidy and promote cancer progression. It has been proposed that centriole assembly during duplication relies on both PCM and centriole proteins, raising the possibility that centriole duplication depends on PCM recruitment. In support of this model, C. elegans SPD-2 and mammalian NEDD-1 (GCP-WD) are key regulators of both these processes. SPD-2 protein sequence homologs have been identified in flies, mice, and humans, but their roles in centrosome biogenesis until now have remained unclear. Here, we show that Cep192, the human homolog of C. elegans and D. melanogaster SPD-2, is a major regulator of PCM recruitment, centrosome maturation, and centriole duplication in mammalian cells. We propose a model in which Cep192 and Pericentrin are mutually dependent for their localization to mitotic centrosomes during centrosome maturation. Both proteins are then required for NEDD-1 recruitment and the subsequent assembly of gamma-TuRCs and other factors into fully functional centrosomes.     

Thermal tolerance during S phase for cell killing and chromosomal aberrations

Synchronous Chinese hamster ovary cells in early S phase were obtained by selecting mitotic cells, accumulating them at the G1/S border by incubating them in aphidicolin for 12 h, and then incubating them for 2 h after releasing them from the aphidicolin block. To determine if thermotolerance could be induced, the cells were heated at 43 degrees C for 20 min in early S phase, incubated for 160 min, and then heated a second time at 43 degrees C for different durations (30-100 min). For the control, nontolerant population, the cells in early S phase were incubated for 50 min and then heated once at 43 degrees C for different durations (20-60 min). Flow cytometric analysis indicated that the population receiving the second heat dose was in the same part of S phase as the population receiving the single heat dose. A comparison of the heat response for the two populations indicated that heating during early S phase induced thermotolerance for both cell killing and chromosomal aberrations; i.e., for 10% survival, which corresponded to 10% of the cells being cytologically normal, the thermal dose was twofold greater in the thermotolerant cells than in the control, nontolerant cells. Furthermore, this thermotolerance developed during S phase. These observations support the hypothesis that heating during S phase kills cells primarily by inducing chromosomal aberrations.