Re-evaluating centrosome function

Over the past 100 years, the centrosome has risen in status from an enigmatic organelle, located at the focus of microtubules, to a key player in cell-cycle progression and cellular control. A growing body of evidence indicates that centrosomes might not be essential for spindle assembly, whereas recent data indicate that they might be important for initiating S phase and completing cytokinesis. Molecules that regulate centrosome duplication have been identified, and the expanding list of intriguing centrosome-anchored activities, the functions of which have yet to be determined, promises continued discovery.     

Interphase centrosome organization by the PLP-Cnn scaffold is required for centrosome function

Pericentriolar material (PCM) mediates the microtubule (MT) nucleation and anchoring activity of centrosomes. A scaffold organized by Centrosomin (Cnn) serves to ensure proper PCM architecture and functional changes in centrosome activity with each cell cycle. Here, we investigate the mechanisms that spatially restrict and temporally coordinate centrosome scaffold formation. Focusing on the mitotic-to-interphase transition in Drosophila melanogaster embryos, we show that the elaboration of the interphase Cnn scaffold defines a major structural rearrangement of the centrosome. We identify an unprecedented role for Pericentrin-like protein (PLP), which localizes to the tips of extended Cnn flares, to maintain robust interphase centrosome activity and promote the formation of interphase MT asters required for normal nuclear spacing, centrosome segregation, and compartmentalization of the syncytial embryo. Our data reveal that Cnn and PLP directly interact at two defined sites to coordinate the cell cycle–dependent rearrangement and scaffolding activity of the centrosome to permit normal centrosome organization, cell division, and embryonic viability.     

Dominant-negative mutant dynein allows spontaneous centrosome assembly, uncouples chromosome and centrosome cycles

Cleavage cycles commence and chromosome and centrosome cycles proceed in harmony following fertilization of Drosophila eggs and completion of the meiotic divisions. The sperm-introduced centrioles replicate, separate, and while recruit pericentriolar material centrosomes (CS) form. The CS nucleate asters of microtubules (MT). Spindles form following interaction of some astral MT with kinetochores. In unfertilized eggs, chromosomes do not replicate, and CS and MT asters never form, although their components are present in the egg cytoplasm; unknown mechanisms prevent chromosome replication and CS and MT assembly. In unfertilized Laborc(D) eggs, rudimentary CS assemble spontaneously and instantaneously and nucleate small MT asters. In fertilized Laborc(D) eggs, normal CS form and organize normal asters. However, the CS replicate prior to accomplishment of the first mitosis, and spindles with multiple CS develop. In fertilized Laborc(D) eggs, while the chromosome cycles cease, CS cycles proceed as in wild type. Knowing that Laborc(D) is a dominant-negative mutation and encodes the formation of mutant cytoplasmic dynein heavy chain molecules, we show here that cytoplasmic dynein is involved in prevention of CS assembly in unfertilized eggs and establishing harmony between the chromosome and the CS cycles.     

Mechanisms of metal-induced centrosome amplification

Exposure to toxic and carcinogenic metals is widespread; however, their mechanisms of action remain largely unknown. One potential mechanism for metal-induced carcinogenicity and toxicity is centrosome amplification. Here we review the mechanisms for metal-induced centrosome amplification, including arsenic, chromium, mercury and nano-titanium dioxide.     

FBXW5 controls centrosome number

Regulatory mechanisms to prevent centriole overduplication during the cell cycle are not completely understood. In this issue, FBXW5 is shown to control the degradation of the centriole assembly factor HsSAS-6. Moreover, the study proposes that FBXW5 is a substrate of both PLK4 and APC/C, two established regulators of centriole duplication.     

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.     

Pattern formation in centrosome assembly

A striking but poorly explained feature of cell division is the ability to assemble and maintain organelles not bounded by membranes, from freely diffusing components in the cytosol. This process is driven by information transfer across biological scales such that interactions at the molecular scale allow pattern formation at the scale of the organelle. One important example of such an organelle is the centrosome, which is the main microtubule organising centre in the cell. Centrosomes consist of two centrioles surrounded by a cloud of proteins termed the pericentriolar material (PCM). Profound structural and proteomic transitions occur in the centrosome during specific cell cycle stages, underlying events such as centrosome maturation during mitosis, in which the PCM increases in size and microtubule nucleating capacity. Here we use recent insights into the spatio-temporal behaviour of key regulators of centrosomal maturation, including Polo-like kinase 1, CDK5RAP2 and Aurora-A, to propose a model for the assembly and maintenance of the PCM through the mobility and local interactions of its constituent proteins. We argue that PCM structure emerges as a pattern from decentralised self-organisation through a reaction-diffusion mechanism, with or without an underlying template, rather than being assembled from a central structural template alone. Self-organisation of this kind may have broad implications for the maintenance of mitotic structures, which, like the centrosome, exist stably as supramolecular assemblies on the micron scale, based on molecular interactions at the nanometer scale.     

DNA defects target the centrosome

When cells enter mitosis with DNA that is unfit to be segregated, the consequences appear to be loss of centrosome function, abnormal spindles and a failure to segregate chromosomes. These defects may result from the workings of a surveillance mechanism that acts to cull irreparable nuclei.     

Molecular components of the centrosome

The centrosome organizes microtubules during both interphase and mitosis and therefore governs fundamental processes in the life of a eukaryotic cell. The past few years have seen a substantial increase in the identification of potential components localized at the centrosome. Although we are still far from achieving a coherent picture of the workings of the centrosome, these recent discoveries are promising first steps towards an understanding of centrosomal functions at the molecular level.     

SADB kinases license centrosome replication

Comment on: Alvarado-Kristensson M, et al. Nat Cell Biol 2009; 11:1081-92.     

Geminin is partially localized to the centrosome and plays a role in proper centrosome duplication

Background information. Centrosome duplication normally parallels with DNA replication and is responsible for correct segregation of replicated DNA into the daughter cells. Although geminin interacts with Cdt1 to prevent loading of MCMs (minichromosome maintenance proteins) on to the replication origins, inactivation of geminin nevertheless causes centrosome over‐duplication in addition to the re‐replication of the genome, suggesting that geminin may play a role in centrosome duplication. However, the exact mechanism by which loss of geminin affects centrosomal duplication remains unclear and the possible direct interaction of geminin with centrosomal‐localized proteins is still unidentified. Results. We report in the present study that geminin is physically localized to the centrosome. This unexpected geminin localization is cell‐cycle dependent and mediated by the actin‐related protein, Arp1, one subunit of the dynein—dynactin complex. Disruption of the integrity of the dynein—dynactin complex by overexpression of dynamitin/p50, a well‐characterized inhibitor of dynactin, reduces the centrosomal localization of both geminin and Arp1. Enrichment of geminin on centrosomes was enhanced when cellular ATP production was suppressed in the ATP‐inhibitor assay, whereas the accumulation of geminin on the centrosome was disrupted by depolymerization of the microtubules using nocodazole. We further demonstrate that the coiled‐coil motif of geminin is required for its centrosomal localization and the interaction of geminin with Arp1. Depletion of geminin by siRNA (small interfering RNA) in MDA‐MB‐231 cells led to centrosome over‐duplication. Conversely, overexpression of geminin inhibits centrosome over‐duplication induced by HU in S‐phase‐arrested cells, and the coiled‐coil‐motif‐mediated centrosomal localization of geminin is required for its inhibition of centrosome over‐duplication. Centrosomal localization of geminin is conserved among mammalian cells and geminin might perform as an inhibitor of centrosome duplication. Conclusions. The results of the present study demonstrate that a fraction of geminin is localized on the centrosome, and the centrosomal localization of geminin is Arp1‐mediated and dynein—dynactin‐dependent. The coiled‐coil motif of geminin is required for its targeting to the centrosome and inhibition of centrosome duplication. Thus the centrosomal localization of geminin might perform an important role in regulation of proper centrosome duplication.     

Molecular links between centrosome and midbody

The terminal step in cytokinesis that severs a cell in two-abscission-is poorly understood. In Developmental Cell, Fabbro et al (2005) identify a centrosome protein whose multiple phosphorylations regulate its movement from centrosome to midbody and completion of abscission.