SAS-1 Is a C2 Domain Protein Critical for Centriole Integrity in C. elegans

Centrioles are microtubule-based organelles important for the formation of cilia, flagella and centrosomes. Despite progress in understanding the underlying assembly mechanisms, how centriole integrity is ensured is incompletely understood, including in sperm cells, where such integrity is particularly critical. We identified C. elegans sas-1 in a genetic screen as a locus required for bipolar spindle assembly in the early embryo. Our analysis reveals that sperm-derived sas-1 mutant centrioles lose their integrity shortly after fertilization, and that a related defect occurs when maternal sas-1 function is lacking. We establish that sas-1 encodes a C2 domain containing protein that localizes to centrioles in C. elegans, and which can bind and stabilize microtubules when expressed in human cells. Moreover, we uncover that SAS-1 is related to C2CD3, a protein required for complete centriole formation in human cells and affected in a type of oral-facial-digital (OFD) syndrome.     

Centrin2 regulates CP110 removal in primary cilium formation

Primary cilia are antenna-like sensory microtubule structures that extend from basal bodies, plasma membrane–docked mother centrioles. Cellular quiescence potentiates ciliogenesis, but the regulation of basal body formation is not fully understood. We used reverse genetics to test the role of the small calcium-binding protein, centrin2, in ciliogenesis. Primary cilia arise in most cell types but have not been described in lymphocytes. We show here that serum starvation of transformed, cultured B and T cells caused primary ciliogenesis. Efficient ciliogenesis in chicken DT40 B lymphocytes required centrin2. We disrupted CETN2 in human retinal pigmented epithelial cells, and despite having intact centrioles, they were unable to make cilia upon serum starvation, showing abnormal localization of distal appendage proteins and failing to remove the ciliation inhibitor CP110. Knockdown of CP110 rescued ciliation in CETN2-deficient cells. Thus, centrin2 regulates primary ciliogenesis through controlling CP110 levels.     

Abnormal centrosomal structure and duplication in Cep135-deficient vertebrate cells

Centrosomes are key microtubule-organizing centers that contain a pair of centrioles, conserved cylindrical, microtubule-based structures. Centrosome duplication occurs once per cell cycle and relies on templated centriole assembly. In many animal cells this process starts with the formation of a radially symmetrical cartwheel structure. The centrosomal protein Cep135 localizes to this cartwheel, but its role in vertebrates is not well understood. Here we examine the involvement of Cep135 in centriole function by disrupting the Cep135 gene in the DT40 chicken B-cell line. DT40 cells that lack Cep135 are viable and show no major defects in centrosome composition or function, although we note a small decrease in centriole numbers and a concomitant increase in the frequency of monopolar spindles. Furthermore, electron microscopy reveals an atypical structure in the lumen of Cep135-deficient centrioles. Centrosome amplification after hydroxyurea treatment increases significantly in Cep135-deficient cells, suggesting an inhibitory role for the protein in centrosome reduplication during S-phase delay. We propose that Cep135 is required for the structural integrity of centrioles in proliferating vertebrate cells, a role that also limits centrosome amplification in S-phase–arrested cells.     

Cby1 promotes Ahi1 recruitment to a ring-shaped domain at the centriole–cilium interface and facilitates proper cilium formation and function

Defects in centrosome and cilium function are associated with phenotypically related syndromes called ciliopathies. Cby1, the mammalian orthologue of the Drosophila Chibby protein, localizes to mature centrioles, is important for ciliogenesis in multiciliated airway epithelia in mice, and antagonizes canonical Wnt signaling via direct regulation of β-catenin. We report that deletion of the mouse Cby1 gene results in cystic kidneys, a phenotype common to ciliopathies, and that Cby1 facilitates the formation of primary cilia and ciliary recruitment of the Joubert syndrome protein Arl13b. Localization of Cby1 to the distal end of mature centrioles depends on the centriole protein Ofd1. Superresolution microscopy using both three-dimensional SIM and STED reveals that Cby1 localizes to an ∼250-nm ring at the distal end of the mature centriole, in close proximity to Ofd1 and Ahi1, a component of the transition zone between centriole and cilium. The amount of centriole-localized Ahi1, but not Ofd1, is reduced in Cby1^−/− cells. This suggests that Cby1 is required for efficient recruitment of Ahi1, providing a possible molecular mechanism for the ciliogenesis defect in Cby1^−/− cells.     

VDAC3 and Mps1 negatively regulate ciliogenesis

Centrosomes serve to organize new centrioles in cycling cells, whereas in quiescent cells they assemble primary cilia. We have recently shown that the mitochondrial porin VDAC3 is also a centrosomal protein that is predominantly associated with the mother centriole and modulates centriole assembly by recruiting Mps1 to centrosomes. Here, we show that depletion of VDAC3 causes inappropriate ciliogenesis in cycling cells, while expression of GFP-VDAC3 suppresses ciliogenesis in quiescent cells. Mps1 also negatively regulates ciliogenesis, and the inappropriate ciliogenesis caused by VDAC3 depletion can be bypassed by targeting Mps1 to centrosomes independently of VDAC3. Thus, our data show that a VDAC3-Mps1 module at the centrosome promotes ciliary disassembly during cell cycle entry and suppresses cilia assembly in proliferating cells. Our data also suggests that VDAC3 might be a link between mitochondrial dysfunction and ciliopathies in mammalian cells.     

C-NAP1 and rootletin restrain DNA damage-induced centriole splitting and facilitate ciliogenesis

Cilia are found on most human cells and exist as motile cilia or non-motile primary cilia. Primary cilia play sensory roles in transducing various extracellular signals, and defective ciliary functions are involved in a wide range of human diseases. Centrosomes are the principal microtubule-organizing centers of animal cells and contain two centrioles. We observed that DNA damage causes centriole splitting in non-transformed human cells, with isolated centrioles carrying the mother centriole markers CEP170 and ninein but not kizuna or cenexin. Loss of centriole cohesion through siRNA depletion of C-NAP1 or rootletin increased radiation-induced centriole splitting, with C-NAP1-depleted isolated centrioles losing mother markers. As the mother centriole forms the basal body in primary cilia, we tested whether centriole splitting affected ciliogenesis. While irradiated cells formed apparently normal primary cilia, most cilia arose from centriolar clusters, not from isolated centrioles. Furthermore, C-NAP1 or rootletin knockdown reduced primary cilium formation. Therefore, the centriole cohesion apparatus at the proximal end of centrioles may provide a target that can affect primary cilium formation as part of the DNA damage response.     

C-NAP1 and rootletin restrain DNA damage-induced centriole splitting and facilitate ciliogenesis

Cilia are found on most human cells and exist as motile cilia or non-motile primary cilia. Primary cilia play sensory roles in transducing various extracellular signals, and defective ciliary functions are involved in a wide range of human diseases. Centrosomes are the principal microtubule-organizing centers of animal cells and contain two centrioles. We observed that DNA damage causes centriole splitting in non-transformed human cells, with isolated centrioles carrying the mother centriole markers CEP170 and ninein but not kizuna or cenexin. Loss of centriole cohesion through siRNA depletion of C-NAP1 or rootletin increased radiation-induced centriole splitting, with C-NAP1-depleted isolated centrioles losing mother markers. As the mother centriole forms the basal body in primary cilia, we tested whether centriole splitting affected ciliogenesis. While irradiated cells formed apparently normal primary cilia, most cilia arose from centriolar clusters, not from isolated centrioles. Furthermore, C-NAP1 or rootletin knockdown reduced primary cilium formation. Therefore, the centriole cohesion apparatus at the proximal end of centrioles may provide a target that can affect primary cilium formation as part of the DNA damage response.     

Self-assembling SAS-6 Multimer Is a Core Centriole Building Block

Centrioles are conserved microtubule-based organelles with 9-fold symmetry that are essential for cilia and mitotic spindle formation. A conserved structure at the onset of centriole assembly is a “cartwheel” with 9-fold radial symmetry and a central tubule in its core. It remains unclear how the cartwheel is formed. The conserved centriole protein, SAS-6, is a cartwheel component that functions early in centriole formation. Here, combining biochemistry and electron microscopy, we characterize SAS-6 and show that it self-assembles into stable tetramers, which serve as building blocks for the central tubule. These results suggest that SAS-6 self-assembly may be an initial step in the formation of the cartwheel that provides the 9-fold symmetry. Electron microscopy of centrosomes identified 25-nm central tubules with repeating subunits and show that SAS-6 concentrates at the core of the cartwheel. Recombinant and native SAS-6 self-oligomerizes into tetramers with ∼6-nm subunits, and these tetramers are components of the centrosome, suggesting that tetramers are the building blocks of the central tubule. This is further supported by the observation that elevated levels of SAS-6 in Drosophila cells resulted in higher order structures resembling central tubule morphology. Finally, in the presence of embryonic extract, SAS-6 tetramers assembled into high density complexes, providing a starting point for the eventual in vitro reconstruction of centrioles.     

The UNI1 and UNI2 Genes Function in the Transition of Triplet to Doublet Microtubules between the Centriole and Cilium in Chlamydomonas

One fundamental role of the centriole in eukaryotic cells is to nucleate the growth of cilia. The unicellular alga Chlamydomonas reinhardtii provides a simple genetic system to study the role of the centriole in ciliogenesis. Wild-type cells are biflagellate, but “uni” mutations result in failure of some centrioles (basal bodies) to assemble cilia (flagella). Serial transverse sections through basal bodies in uni1 and uni2 single and double mutant cells revealed a previously undescribed defect in the transition of triplet microtubules to doublet microtubules, a defect correlated with failure to assemble flagella. Phosphorylation of the Uni2 protein is reduced in uni1 mutant cells. Immunogold electron microscopy showed that the Uni2 protein localizes at the distal end of the basal body where microtubule transition occurs. These results provide the first mechanistic insights into the function of UNI1 and UNI2 genes in the pathway mediating assembly of doublet microtubules in the axoneme from triplet microtubules in the basal body template.     

A ciliopathy complex builds distal appendages to initiate ciliogenesis

Cells inherit two centrioles, the older of which is uniquely capable of generating a cilium. Using proteomics and superresolved imaging, we identify a module that we term DISCO (distal centriole complex). The DISCO components CEP90, MNR, and OFD1 underlie human ciliopathies. This complex localizes to both distal centrioles and centriolar satellites, proteinaceous granules surrounding centrioles. Cells and mice lacking CEP90 or MNR do not generate cilia, fail to assemble distal appendages, and do not transduce Hedgehog signals. Disrupting the satellite pools does not affect distal appendage assembly, indicating that it is the centriolar populations of MNR and CEP90 that are critical for ciliogenesis. CEP90 recruits the most proximal known distal appendage component, CEP83, to root distal appendage formation, an early step in ciliogenesis. In addition, MNR, but not CEP90, restricts centriolar length by recruiting OFD1. We conclude that DISCO acts at the distal centriole to support ciliogenesis by restraining centriole length and assembling distal appendages, defects in which cause human ciliopathies.     

DISCO is key to successful centriole maturation

Centriole maturation is essential for ciliogenesis, but which proteins and how they regulate ciliary assembly is unclear. In this issue, Kumar et al. (2021. J. Cell Biol. https://doi.org/10.1083/jcb.202011133) shed light on this process by identifying a ciliopathy complex at the distal mother centriole that restrains centriole length and supports the formation of distal appendages.

The primary cilium plays a crucial role in embryonic development by allowing the integration of a variety of inputs, including chemical and mechanical signals. Primary cilia are found on most cell types; thereby, mutations in genes encoding cilia components may perturb many cellular functions, including airway mucus clearance, mechanosensation, and cell signaling, which are central regulators of organ function and homeostasis. Numerous mutations leading to ciliary dysfunction have been identified in recent years and thus linked to human cilia-related diseases, called ciliopathies (1, 2). Some of these mutations affect components of the centrioles, which are cytoplasmic cylindrical structures composed by triplets of microtubules arranged in a ninefold symmetry.Cilia originate from centrioles and are anchored to the cell surface. In most mammalian cells, centrioles are present within the centrosome, the main organizing center of microtubules. During G1 phase, cells have one centrosome containing two centrioles of different ages. The older mother centriole is distinguished from the younger daughter centriole by the presence of two sets of appendages organized around its circumference. The centrosome duplicates in S phase and, as a result, a new centriole is formed orthogonally to each parent centriole. The new centrioles subsequently elongate during S and G2 phases, and each daughter cell inherits a parent and a newly formed centriole after mitosis. During this transition, new centrioles become daughter centrioles, and the daughter centriole from the previous cycle acquires appendages to mature into a mother centriole. Distal appendages (DAs) are essential for anchoring the mother centriole to the plasma membrane and for the formation of a cilium (2). The formation of a mature centriole competent for ciliogenesis is therefore a complex process taking place over three successive cell cycles.Different molecular factors required for the progressive maturation of centrioles and the assembly of DAs have been identified in the past, and perturbation of their function has been linked to ciliopathies (2, 3). However, the precise mechanism by which DAs are assembled onto centrioles remains elusive. In this issue, Kumar et al. focused their attention on CEP90, a poorly characterized protein whose mutations have been implicated in several ciliopathies (4). CEP90 is a component of centriolar satellites, which are proteinaceous granules located at the periphery of the centrosome (5, 6). Using a combination of expansion microscopy and structured illumination super-resolution microscopy techniques, the authors found that CEP90 also localized to centrioles, where it formed a discontinuous ring with a ninefold symmetry. CEP90 localized near a well-characterized DA component, CEP164, which was consistent with CEP90 being present at the base of these appendages. Then, they searched for CEP90 interactors. For that, the researchers first had to circumvent the shortcoming of discriminating between interactions that may take place at the centrosome from those occurring within centriolar satellites. To get around this, Kumar et al. used a cell line in which satellite assembly is inhibited. Among the candidates they found interacting with CEP90 at the centrosome were OFD1 and Moonraker (MNR), which are two proteins previously associated with multiple ciliopathies. OFD1 is a centriole component required to restrict centriole elongation and assemble DAs (7). MNR, also called OFIP or KIAA073, is a satellite component necessary for cilia formation (8). Making again use of super-resolution microscopy, the authors showed that all three proteins colocalized at the centriole distal end, with the MNR protein being the closest to the centriole wall, so they named this newly identified complex after DISCO (distal centriole complex).Next, Kumar et al. elegantly demonstrated that, as previously shown for OFD1 (7), inactivating either CEP90 or MNR led to the absence of cilia in cells. In mice, deficiency of any of these proteins resulted in Hedgehog signaling inhibition and early arrest of embryonic development. As reported for OFD1-deficient cells, loss of MNR in human cells resulted in overly long centrioles. However, centriole length was normal in CEP90-deficient cells, suggesting partially distinct functions between members of the DISCO complex. The authors noted that ciliogenesis was blocked at an early stage in CEP90^−/− and MNR^−/− cells and, given that DAs are essential for centriole anchoring and ciliogenesis, they decided to examine DA organization in these cells (4). Indeed, they found that DA components, such as CEP83, were not recruited during centriole maturation in MNR^−/− or CEP90^−/− cells, and DAs were not detected by electron microscopy. These findings pointed out that CEP90 and MNR, like OFD1, were required for the assembly of DAs.Since CEP90 is required for satellite accumulation around the centrosome, and satellites are, in turn, essential for ciliogenesis (6), one possible explanation to their results is that CEP90 might affect DA assembly indirectly via its role in satellite localization. To answer this question, the authors again used cells lacking centriolar satellites. CEP90 was correctly localized at centriole distal ends in these cells, and DAs were formed, supporting a direct requirement for the centriolar pool of CEP90 in DA assembly. Putting all their data together, Kumar et al. proposed the following model: First, MNR is recruited to elongating centrioles, which, in turn, triggers the recruitment of OFD1 to arrest elongation at the end of the first cell cycle. MNR and OFD1 then recruit CEP90, which initiates the recruitment of DA components, including CEP83, at the end of the following cell cycle (Fig. 1). Thus, the DISCO complex allows for coupling the arrest of centriole elongation to centriole maturation across successive cell cycles.Open in a separate windowFigure 1.The DISCO complex restrains centriole elongation and initiates DA assembly. (1) The DISCO complex member MNR is recruited first at the distal end of assembling centrioles. MNR then recruits other members of the complex, including OFD1, which inhibits centriole elongation at the end of the first cell cycle, i.e., when newly formed centrioles become daughter centrioles (DCs). Other members of the complex include CEP90 and possibly also FOPNL. (2) At the end of the following cell cycle, as the daughter centriole matures into a mother centriole (MC), CEP90 initiates the recruitment of CEP83, the most upstream component in DA assembly. A previously identified interaction between OFD1 and another DA component, CEP89, might also contribute to DA organization (10). Proteins are drawn in contact with each other when an interaction or hierarchical recruitment was described (3, 4, 8, 11).Besides OFD1 and MNR proteins, Kumar et al. also identified a protein called FGFR1OP N-Terminal Like (FOPNL or FOR20) as a potential CEP90 interactor (4). Interestingly, this interaction was confirmed in a recent study describing that a complex containing CEP90, OFD1, and FOPNL localizes at the distal end of Paramecium centrioles and is necessary for the recruitment of DA components and centriole docking in Paramecium and human cells (9). FOPNL was previously found in complex with MNR and OFD1 and shown to facilitate their interaction (8). Together, these data suggest that the DISCO complex could also include FOPNL. The functional similarities of some of the components of the DISCO complex between Paramecium and humans strongly suggest that the role of DISCO in centriole maturation and ciliogenesis is broadly conserved across species.Previous studies in different organisms have underpinned the relevance of ciliopathy-associated proteins to ensure normal organism development and tissue function (1, 2). Overall, the findings by Kumar et al. highlight the critical role of a ciliopathy-associated protein complex at distal centrioles in building distal appendages, thus supporting centriole maturation and ciliogenesis in rodents and human cells (4).     

DSas-6 and Ana2 coassemble into tubules to promote centriole duplication and engagement

Centrioles form cilia and centrosomes, organelles whose dysfunction is increasingly linked to human disease. Centriole duplication relies on a few conserved proteins (ZYG-1/Sak/Plk4, SAS-6, SAS-5/Ana2, and SAS-4), and is often initiated by the formation of an inner "cartwheel" structure. Here, we show that overexpressed Drosophila Sas-6 and Ana2 coassemble into extended tubules (SAStubules) that bear a striking structural resemblance to the inner cartwheel of the centriole. SAStubules specifically interact with centriole proximal ends, but extra DSas-6/Ana2 is only recruited onto centrioles when Sak/Plk4 kinase is also overexpressed. This extra centriolar DSas-6/Ana2 induces centriole overduplication and, surprisingly, increased centriole cohesion. Intriguingly, we observe tubules that are structurally similar to SAStubules linking the engaged centrioles in normal wild-type cells. We conclude that DSas-6 and Ana2 normally cooperate to drive the formation of the centriole inner cartwheel and that they promote both centriole duplication and centriole cohesion in a Sak/Plk4-dependent manner.     

Drosophila Bld10 Is a Centriolar Protein That Regulates Centriole, Basal Body, and Motile Cilium Assembly

Cilia and flagella play multiple essential roles in animal development and cell physiology. Defective cilium assembly or motility represents the etiological basis for a growing number of human diseases. Therefore, how cilia and flagella assemble and the processes that drive motility are essential for understanding these diseases. Here we show that Drosophila Bld10, the ortholog of Chlamydomonas reinhardtii Bld10p and human Cep135, is a ubiquitous centriolar protein that also localizes to the spermatid basal body. Mutants that lack Bld10 assemble centrioles and form functional centrosomes, but centrioles and spermatid basal bodies are short in length. bld10 mutant flies are viable but male sterile, producing immotile sperm whose axonemes are deficient in the central pair of microtubules. These results show that Drosophila Bld10 is required for centriole and axoneme assembly to confer cilium motility.     

Centriole translocation and degeneration during ciliogenesis in Caenorhabditis elegans neurons

Neuronal cilia that are formed at the dendritic endings of sensory neurons are essential for sensory perception. However, it remains unclear how the centriole‐derived basal body is positioned to form a template for cilium formation. Using fluorescence time‐lapse microscopy, we show that the centriole translocates from the cell body to the dendrite tip in the Caenorhabditis elegans sensory neurons. The centriolar protein SAS‐5 interacts with the dynein light‐chain LC8 and conditional mutations of cytoplasmic dynein‐1 block centriole translocation and ciliogenesis. The components of the central tube are essential for the biogenesis of centrioles, which later drive ciliogenesis in the dendrite; however, the centriole loses these components at the late stage of centriole translocation and subsequently recruits transition zone and intraflagellar transport proteins. Together, our results provide a comprehensive model of ciliogenesis in sensory neurons and reveal the importance of the dynein‐dependent centriole translocation in this process.     

The centrosome duplication cycle in health and disease

Centrioles function in the assembly of centrosomes and cilia. Structural and numerical centrosome aberrations have long been implicated in cancer, and more recent genetic evidence directly links centrosomal proteins to the etiology of ciliopathies, dwarfism and microcephaly. To better understand these disease connections, it will be important to elucidate the biogenesis of centrioles as well as the controls that govern centriole duplication during the cell cycle. Moreover, it remains to be fully understood how these organelles organize a variety of dynamic microtubule-based structures in response to different physiological conditions. In proliferating cells, centrosomes are crucial for the assembly of microtubule arrays, including mitotic spindles, whereas in quiescent cells centrioles function as basal bodies in the formation of ciliary axonemes. In this short review, we briefly introduce the key gene products required for centriole duplication. Then we discuss recent findings on the centriole duplication factor STIL that point to centrosome amplification as a potential root cause for primary microcephaly in humans. We also present recent data on the role of a disease-related centriole-associated protein complex, Cep164-TTBK2, in ciliogenesis.     

Molecular characterization of centriole assembly in ciliated epithelial cells

Ciliated epithelial cells have the unique ability to generate hundreds of centrioles during differentiation. We used centrosomal proteins as molecular markers in cultured mouse tracheal epithelial cells to understand this process. Most centrosomal proteins were up-regulated early in ciliogenesis, initially appearing in cytoplasmic foci and then incorporated into centrioles. Three candidate proteins were further characterized. The centrosomal component SAS-6 localized to basal bodies and the proximal region of the ciliary axoneme, and depletion of SAS-6 prevented centriole assembly. The intraflagellar transport component polaris localized to nascent centrioles before incorporation into cilia, and depletion of polaris blocked axoneme formation. The centriolar satellite component PCM-1 colocalized with centrosomal components in cytoplasmic granules surrounding nascent centrioles. Interfering with PCM-1 reduced the amount of centrosomal proteins at basal bodies but did not prevent centriole assembly. This system will help determine the mechanism of centriole formation in mammalian cells and how the limitation on centriole duplication is overcome in ciliated epithelial cells.     

Human microcephaly protein CEP135 binds to hSAS‐6 and CPAP,and is required for centriole assembly

Centrioles are cylindrical structures that are usually composed of nine triplets of microtubules (MTs) organized around a cartwheel‐shaped structure. Recent studies have proposed a structural model of the SAS‐6‐based cartwheel, yet we do not know the molecular detail of how the cartwheel participates in centriolar MT assembly. In this study, we demonstrate that the human microcephaly protein, CEP135, directly interacts with hSAS‐6 via its carboxyl‐terminus and with MTs via its amino‐terminus. Unexpectedly, CEP135 also interacts with another microcephaly protein CPAP via its amino terminal domain. Depletion of CEP135 not only perturbed the centriolar localization of CPAP, but also blocked CPAP‐induced centriole elongation. Furthermore, CEP135 depletion led to abnormal centriole structures with altered numbers of MT triplets and shorter centrioles. Overexpression of a CEP135 mutant lacking the proper interaction with hSAS‐6 had a dominant‐negative effect on centriole assembly. We propose that CEP135 may serve as a linker protein that directly connects the central hub protein, hSAS‐6, to the outer MTs, and suggest that this interaction stabilizes the proper cartwheel structure for further CPAP‐mediated centriole elongation.     

Bld10p constitutes the cartwheel-spoke tip and stabilizes the 9-fold symmetry of the centriole

Centrioles/basal bodies have a characteristic cylindrical structure consisting of nine triplet microtubules arranged in a rotational symmetry. How this elaborate structure is formed is a major unanswered question in cell biology [1, 2]. We previously identified a 170 kDa coiled-coil protein essential for the centriole formation in Chlamydomonas. This protein, Bld10p, is the first protein shown to localize to the cartwheel, a 9-fold symmetrical structure possibly functioning as the scaffold for the centriole-microtubule assembly [3]. Here, we report results by using a series of truncated Bld10p constructs introduced into a bld10 null mutant. Remarkably, a transformant (DeltaC2) in which 35% of Bld10p at the C terminus was deleted assembled centrioles with eight symmetrically arranged triplets, in addition to others with the normal nine triplets. The cartwheels in these eight-membered centrioles had spokes approximately 24% shorter than those in the wild-type, suggesting that the eight-triplet centrioles were formed because the cartwheel's smaller diameter. From the morphology of the cartwheel spoke in the DeltaC2 centriole and immunoelectron-microscope localization, we conclude that Bld10p is a major spoke-tip component that extends the cartwheel diameter and attaches triplet microtubules. These results provide the first experimental evidence for the crucial function of the cartwheel in centriolar assembly.     

Proteomic analysis of isolated chlamydomonas centrioles reveals orthologs of ciliary-disease genes

BACKGROUND: The centriole is one of the most enigmatic organelles in the cell. Centrioles are cylindrical, microtubule-based barrels found in the core of the centrosome. Centrioles also act as basal bodies during interphase to nucleate the assembly of cilia and flagella. There are currently only a handful of known centriole proteins. RESULTS: We used mass-spectrometry-based MudPIT (multidimensional protein identification technology) to identify the protein composition of basal bodies (centrioles) isolated from the green alga Chlamydomonas reinhardtii. This analysis detected the majority of known centriole proteins, including centrin, epsilon tubulin, and the cartwheel protein BLD10p. By combining proteomic data with information about gene expression and comparative genomics, we identified 45 cross-validated centriole candidate proteins in two classes. Members of the first class of proteins (BUG1-BUG27) are encoded by genes whose expression correlates with flagellar assembly and which therefore may play a role in ciliogenesis-related functions of basal bodies. Members of the second class (POC1-POC18) are implicated by comparative-genomics and -proteomics studies to be conserved components of the centriole. We confirmed centriolar localization for the human homologs of four candidate proteins. Three of the cross-validated centriole candidate proteins are encoded by orthologs of genes (OFD1, NPHP-4, and PACRG) implicated in mammalian ciliary function and disease, suggesting that oral-facial-digital syndrome and nephronophthisis may involve a dysfunction of centrioles and/or basal bodies. CONCLUSIONS: By analyzing isolated Chlamydomonas basal bodies, we have been able to obtain the first reported proteomic analysis of the centriole.