CDK1-mediated phosphorylation of the RIIalpha regulatory subunit of PKA works as a molecular switch that promotes dissociation of RIIalpha from centrosomes at mitosis.

Protein kinase A regulatory subunit RIIalpha is tightly bound to centrosomal structures during interphase through interaction with the A-kinase anchoring protein AKAP450, but dissociates and redistributes from centrosomes at mitosis. The cyclin B-p34(cdc2) kinase (CDK1) has been shown to phosphorylate RIIalpha on T54 and this has been proposed to alter the subcellular localization of RIIalpha. We have made stable transfectants from an RIIalpha-deficient leukemia cell line (Reh) that expresses either wild-type or mutant RIIalpha (RIIalpha(T54E)). When expressed, RIIalpha detaches from centrosomes at mitosis and dissociates from its centrosomal location in purified nucleus-centrosome complexes by incubation with CDK1 in vitro. By contrast, centrosomal RIIalpha(T54E) is not redistributed at mitosis, remains mostly associated with centrosomes during all phases of the cell cycle and cannot be solubilized by CDK1 in vitro. Furthermore, RIIalpha is solubilized from particular cell fractions and changes affinity for AKAP450 in the presence of CDK1. D and V mutations of T54 also reduce affinity for the N-terminal RII-binding domain of AKAP450, whereas small neutral residues do not change affinity detected by surface plasmon resonance. In addition, only RIIalpha(T54E) interacts with AKAP450 in a RIPA-soluble extract from mitotic cells. Finally, microtubule repolymerization from mitotic centrosomes of the RIIalpha(T54E) transfectant is poorer and occurs at a lower frequency than that of RIIalpha transfectants. Our results suggest that T54 phosphorylation of RIIalpha by CDK1 might serve to regulate the centrosomal association of PKA during the cell cycle.

Post-translational modifications of the regulatory subunits of cAMP-dependent protein kinases during G1/S progression.

During the G1/S transition of the cell cycle variations in the labelling by 8-N3-[32P]cAMP of the protein kinase A regulatory subunits RI and RII, used as a probe to monitor post-translational modifications that may regulate cAMP binding, were observed in synchronized HeLa cells. A decrease in 8-N3-[32P]cAMP labelling of RI, RII and RII phosphorylated by the catalytic subunit of PKA was correlated with the increased percentage of cells in phases G1. An increase in 8-N3-[32P]cAMP incorporated into the 54-kDa RII subunit during progression from G1 to S was correlated with an increase in intracellular cAMP. A transient increase in Mn-SOD activity was detected in cells arrested at the G1/S transition using two different techniques, suggesting that oxidative modulation of regulatory subunits by free radicals may modify cAMP binding sites during the cell cycle. Decreased photoaffinity labelling by 8-N3-[32P]cAMP of RI, RII and autophosphorylated RII subunits was found to be an inherent characteristic of PKA in the G1/S transition.

Principle of pattern-signature synthesis and analysis based on double optical correlations.

Pattern-recognition problems for which patterns cannot be recognized directly but by their attitudes and/or behaviors is addressed. To analyze these attitudes, pattern signatures are generated from picture sequences. Two complementary signature synthesis algorithms are presented. The architecture is made up of two cascaded correlators. The first is used to create the signatures and the second to classify them. We focus our analysis on the case of optical implementations. Illustrations are given in the case of face recognition by attitudes (multisensor in the optronic imaging range) and moving-target recognition by behavior (in the radar imaging range).

Differential localization of protein kinase A type II isozymes in the Golgi-centrosomal area.

Selectivity in the action of cAMP may be mediated by compartmentalized pools of cyclic AMP-dependent protein kinase (PKA). PKA type II is directed to different subcellular loci by interaction of the type II regulatory subunits (RIIalpha, RIIbeta) with A-kinase anchoring proteins. In order to separately investigate the subcellular localization of PKA type II isozymes, monospecific antibodies to human RIIalpha and RIIbeta subunits of PKA were developed. We demonstrate that centrosomes bind both RIIalpha and RIIbeta. Centrosomes were the preferred intracellular anchoring site for RIIbeta. However, centrosomal localization of RIIbeta was observed only in some highly differentiated cells such as keratinocytes, granulosa cells, and macrophages and in all neoplastic cell lines examined. Centrosomal localization of RIIbeta was not observed in normal undifferentiated cells such as fibroblasts, myoblasts, and T and B cells. In contrast, RIIalpha was abundant in the Golgi area and in the trans-Golgi network (TGN). Furthermore, although RIIalpha appeared to colocalize with microtubules in the Golgi/TGN, extractions with nonionic detergent demonstrated that RIIalpha was mainly membrane-associated. In addition, alterations of microtubule dynamics with Nocodazole or Taxol affected the distribution of the detergent-extractable pool of RIIalpha, indicating that RIIalpha may localize with microtubule-associated vesicles. Thus, RIIalpha and RIIbeta clearly localize differently in the Golgi-centrosomal region. This indicates specific roles for PKA isozymes containing either RIIalpha or RIIbeta.

Cloning and characterization of a cDNA encoding an A-kinase anchoring protein located in the centrosome, AKAP450.

A combination of protein kinase A type II (RII) overlay screening, database searches and PCR was used to identify a centrosomal A-kinase anchoring protein. A cDNA with an 11.7 kb open reading frame was characterized and found to correspond to 50 exons of genomic sequence on human chromosome 7q21-22. This cDNA clone encoded a 3908 amino acid protein of 453 kDa, that was designated AKAP450 (DDBJ/EMBL/GenBank accession No. AJ131693). Sequence comparison demonstrated that the open reading frame contained a previously characterized cDNA encoding Yotiao, as well as the human homologue of AKAP120. Numerous coiled-coil structures were predicted from AKAP450, and weak homology to pericentrin, giantin and other structural proteins was observed. A putative RII-binding site was identified involving amino acid 2556 of AKAP450 by mutation analysis combined with RII overlay and an amphipatic helix was predicted in this region. Immunoprecipitation of RII from RIPA-buffer extracts of HeLa cells demonstrated co-precipitation of AKAP450. By immunofluorecent labeling with specific antibodies it was demonstrated that AKAP450 localized to centrosomes. Furthermore, AKAP450 was shown to co-purify in centrosomal preparations. The observation of two mRNAs and several splice products suggests additional functions for the AKAP450 gene.

Optical implementation of segmented composite filtering.

We investigate possible performance improvements of coherent optical correlators by using an appropriate filter design. Multidecision strategies are often required in high-level image-processing tasks. For an optical system characterized by a given space-bandwidth product we show that the filter design plays a crucial role in satisfying both system and processing requirements, with respect to the optimization of the encoding capacity. This leads us to the definition of segmented composite filtering, which is discussed in terms of processing performance. This filtering is assessed experimentally in the case of a face-recognition problem.

Mitosis-specific phosphorylation and subcellular redistribution of the RIIalpha regulatory subunit of cAMP-dependent protein kinase.

Phosphorylation of the RII regulatory subunits of cyclic AMP-dependent protein kinases (PKAs) was examined during the HeLa cell cycle. Three RIIalpha isoforms of 51, 54, and 57 kDa were identified by RIIalpha immunodetection and labeling with 8-azido[32P]cAMP in different cell cycle phases. These isoforms were characterized as different phosphorylation states by the use of selective PKA and cyclin-directed kinase inhibitors. Whereas RIIalpha autophosphorylation by PKA caused RIIalpha to shift from 51 to 54 kDa, phosphorylation of RIIalpha by one other or a combination of several kinases activated during mitosis caused RIIalpha to shift from 51 to 57 kDa. In vivo incorporation of [32P]orthophosphate into mitotic cells and RIIalpha immunoprecipitation demonstrated that RIIalpha was hyperphosphorylated on a different site than the one phosphorylated by PKA. Deletion and mutation analysis demonstrated that the cyclin B-p34(cdc2) kinase (CDK1) phosphorylated human recombinant RIIalpha in vitro on Thr54. Whereas RIIalpha was associated with the Golgi-centrosomal region during interphase, it was dissociated from its centrosomal localization at metaphase-anaphase transition. Furthermore, particulate RIIalpha from HeLa cell extracts was solubilized following incubation with CDK1 in vitro. Our results suggest that at the onset of mitosis, CDK1 phosphorylates RIIalpha, and this may alter its subcellular localization.

In vitro effects of oxygen-derived free radicals on type I and type II cAMP-dependent protein kinases.

Oxygen free radicals may act as second messengers in signal transduction pathways and contribute to inflammatory diseases. We studied the action in vitro of radiolytically generated hydroxyl radicals (.OH) and superoxide radicals (O-2) on the cAMP-dependent protein kinases, I and II (PKAI and -II, respectively). The effects of the gasses O2 and N2O used to produce O-2 or .OH radicals by gamma-radiolysis of the water were also studied. PKAI is more sensitive than PKAII to oxygen gas (10 mM sodium formate) and to hydroxyl and superoxide radicals. Hydroxyl radicals decreased the kinase phosphotransferase activities stimulated either by cAMP or its site-specific analogs for both PKAI and PKAII; however, PKAI was more affected. The binding of [3H]cAMP and of 8-N3-[32P]cAMP to RI regulatory subunits was decreased. .OH caused a loss of tryptophan 260 fluorescence at site A of PKAI and of bityrosine production. Superoxide radicals affected only PKAI. O-2 modified both cAMP-binding sites A and B of the regulatory subunit but had a smaller effect on the catalytic subunit. The catalytic subunit was more sensitive to radicals when free than when part of the holoenzymes during exposure to the oxygen free radicals. These results suggest that oxygen free radicals alter the structure of PKA enzymes. Thus, oxidative modifications may alter key enzymes, including cAMP-dependent protein kinases, in certain pathological states.

Involvement of phosphoinositide 3-kinase and Rac in membrane ruffling induced by IL-2 in T cells.

IL-2 is known to play a critical role in regulating T lymphocyte proliferation. We show here that IL-2 also provokes an instantaneous and sustained membrane ruffling in cloned human or murine T cells as well as in lectin-activated peripheral blood lymphocytes. In the IL-2-induced lamellipodia, tubulin is depolymerized whereas actin is strongly polymerized, forming caps. IL-2-induced membrane ruffling is protein kinase C (PKC) independent, as judged by the absence of effects of bisindolylmaleimide, an efficient inhibitor of all PKC isoforms. The formation of lamellipodia by IL-2 is blocked by wortmannin and LY294002, two inhibitors of phosphoinositide 3-kinase (PI3-kinase). Moreover, expression in murine T cells of an inactive form of P13-kinase inhibits IL-2-induced membrane ruffling, whereas expression of a constitutively active p110 increases the basal membrane ruffling. Rac is also involved in IL-2-induced membrane ruffling since an inactive form of Rac (N17rac) blocks the IL-2-induced lamellipodia, whereas the constitutive form of Rac (Val12rac) can also lead to membrane ruffling. In the signaling cascade, Rac is downstream of PI3-kinase since constitutive membrane ruffling in Val12rac cells is insensitive to wortmannin. Thus, through a signaling cascade involving PI3-kinase and Rac, IL-2 can induce profound alterations of the T cell cytoskeleton, a phenomenon which might be of importance for T cell physiology.

MAP kinase abnormalities in hyperproliferative cultured fibroblasts from psoriatic skin.

Several studies indicate that dermal fibroblasts have a specific role in the pathophysiology of psoriasis. We have previously found that cultured fibroblasts from psoriatic patients are hyperproliferative and have low cyclic AMP-dependent protein kinase activity. In this study, we observed that these cells are also larger than normal. Given the key role of mitogen-activated protein kinases (MAPK) in the regulation of cell proliferation and cytoskeleton function, we characterized MAPK in psoriatic fibroblasts and in normal fibroblasts. Serum and platelet-derived growth factor treatment of serum-deprived fibroblasts led to a larger increase in MAPK activity in psoriatic cells than in normal cells. We then purified MAPK by ion-exchange chromatography. MAPK activity was again found to be significantly higher in psoriatic fibroblasts than in normal cells, both when deprived of serum (p < 0.01) and when stimulated with serum (p < 0.05). Interestingly, 8-bromo-cAMP treatment inhibited serum-stimulated MAPK phosphorylation in normal fibroblasts but had no effect in psoriatic fibroblasts. We observed a temporal variation in nuclear localization of phosphorylated MAPK in cultured fibroblasts stimulated by either serum or platelet-derived growth factor. No difference in the localization of phosphorylated MAPK in normal and psoriatic skins was found. Psoriatic fibroblasts are the first example of a MAPK pathway abnormality in large human benign hyperproliferative cells.

Cyclic AMP-dependent protein kinases and human trophoblast cell differentiation in vitro.

Human trophoblast cells offer a unique in vitro model for the study of aspects of the dynamic processes occurring during cell fusion and syncytium formation. In the human placenta, mononuclear cytotrophoblasts aggregate and fuse to form a multinucleated syncytiotrophoblast. In vitro, the addition of cyclic AMP analogs, 8-bromo-cyclic-AMP or Sp-8-bromo-cyclic AMPS, promotes syncytiotrophoblast formation, as shown by the disappearance of immunostained E-cadherin and desmoplakin, and increased numbers of nuclei per syncytium. An antagonist of cyclic AMP, Rp-8-bromo-cyclic AMPS, and an inhibitor of the cyclic AMP-dependent protein kinase catalytic subunit, H-89, impair cell fusion. This led us to study the pattern of expression and subcellular localization of cyclic-AMP-dependent protein kinase subunits during syncytium formation. Cytotrophoblasts expressed the RIalpha and RIIalpha regulatory subunits and the Calpha and Cbeta catalytic subunits. RIalpha was down-regulated during syncytium formation. No change in RIIalpha protein levels was observed, but there was a drastic subcellular redistribution. RIIalpha located in the Golgi-centrosomal area of cytotrophoblasts was scattered throughout the cytoplasm of the syncytiotrophoblast. Interestingly, an accumulation of RIIalpha was observed underneath the apical membrane of syncytiotrophoblast in vitro and in situ. This suggests a key role of cyclic AMP-dependent protein kinase type IIalpha during cell fusion and microvilli formation, both of which are essential for the secretory and transfer functions of the syncytiotrophoblast.

Performance comparison of ferroelectric liquid-crystal-technology-based coherent optical multichannel correlators.

Our purpose is to compare two architectures when implemented with ferroelectric liquid-crystal technology: the conventional VanderLugt and joint transform correlators. The architectures are compared in the single-correlation and multichannel cases. The analysis covers both theoretical aspects and practical considerations regarding implementation. Specifications for a multichannel correlator design, including considerations of both spatial light modulators and architecture configurations, are discussed. Experimental results are presented for both architectures. Finally, the benefit resulting from extension to multichannel operation is discussed in terms of both multiplexing and algorithmic capabilities.

In isolated human centrosomes, the associated kinases phosphorylate a specific subset of centrosomal proteins.

Several studies have shown that kinases and phosphatases can interact with the centrosome during interphase and mitosis suggesting that centrosomal components might be the targets of these enzymes. The association of the cAMP-dependent protein kinase type II and the mitotic kinase p34cdc2 with centrosomes from human lymphoblast cells has previously been shown (Keryer et al, 1993, Exp Cell Res 204, 230-240; Bailly et al, 1989, EMBO J 8, 3985-3995). In this paper we demonstrate that isolated centrosomes are able to phosphorylate a few number of centrosomal proteins (M(r) 230-220000; 135000 and 50000) and also H1 histone. The phosphorylation of H1-histone is cell cycle dependent and modulated by phosphatases. The use of kinase and phosphatase inhibitors and the addition of the catalytic subunit of cAMP-dependent kinase or of cyclinB-p34cdc2 kinase showed that both kinases phosphorylate the same centrosomal substrates. In addition two centrosomal proteins (M(r) 100000 and 37000) were phosphorylated only by p34cdc2 kinase. Although the low amount of centrosomal proteins precluded a full characterization of these substrates we discuss the identity of the major centrosomal phosphoproteins by comparison with proteins known to associate with microtubule-organizing centres or mitotic spindles. Our results raise also the intriguing possibility that the cAMP-dependent protein kinase could be regulated by the mitotic kinase at the entry of mitosis.

Phosphorylation of the regulatory subunit of type II beta cAMP-dependent protein kinase by cyclin B/p34cdc2 kinase impairs its binding to microtubule-associated protein 2.

Subcellular localization of type II cAMP-dependent protein kinase is determined by the interactions of the regulatory subunit (RII) with specific RII-anchoring proteins. By using truncated NH2-terminal RII beta fusion proteins expressed in Escherichia coli and the mitotic protein kinase p34cdc2 isolated from HeLa cells or starfish oocytes, we investigated the in vitro phosphorylation of RII beta by these kinases. The putative site for phosphorylation by the mitotic kinases is Thr-69 in the NH2-terminal domain of RII beta. This phosphorylation site matches the consensus sequence X(T/S)PX(K/R) for p34cdc2 recognition and belongs to a well-conserved sequence found in all RII beta sequences known to date. In contrast to phosphorylation by casein kinase II or the cAMP-dependent protein kinase catalytic subunit, phosphorylation of RII beta by mitotic kinases impaired its interaction with a well-known RII-anchoring protein, the neuronal microtubule-associated protein 2. The potential regulatory significance of the phosphorylation of this site on the interaction with microtubule-associated protein 2 and other RII-anchoring proteins and the physiological relevance of this cyclin B/p34cdc2 kinase-catalyzed modification of RII beta (or phosphorylation by other proline-directed protein kinases) are discussed.

A high-affinity binding protein for the regulatory subunit of cAMP-dependent protein kinase II in the centrosome of human cells.

In the human lymphoblastic cell line KE 37, Northern blot analysis with cDNA probes for human regulatory subunits RII alpha RII beta of the cAMP-dependent protein kinase (A-kinase) type II and immunoblotting or immunoprecipitation studies with several antibodies directed against RII alpha and RII beta show that these two isoforms are expressed. The major isoform alpha is mostly cytosolic, whereas the beta isoform appears concentrated in the Golgi-centrosomal area, as judged by immunofluorescence and cell fractionation. Using a 32P-labelled RII overlay on Western blots, a 350-kDa RII-binding protein (AKAP 350) was specifically identified in centrosomes isolated from this cell line, whereas a Golgi fraction has previously been demonstrated to contain an 85-kDa RII-binding protein (AKAP 85). AKAP 350 is highly insoluble and can partially be extracted from centrosomes as a complex of AKAP 350 and RII subunit. AKAP 350 was identified as a specific centrosomal protein previously demonstrated in the pericentriolar material. The potential significance of a specific subcellular distribution for different RII-binding proteins in nonneuronal cells is discussed.

Identification of a high affinity binding protein for the regulatory subunit RII beta of cAMP-dependent protein kinase in Golgi enriched membranes of human lymphoblasts.

Immunocytochemical evidence of an association between the regulatory subunit RII of the cAMP-dependent protein kinase (cAMP-PK) and the Golgi apparatus in several cell types has been reported. In order to identify endogenous Golgi proteins binding RII, a fraction enriched in Golgi vesicles was isolated from human lymphoblasts. Only the RII beta isoform was detected in the Golgi-rich fraction, although RII alpha has also been found to be present in these cells. A 85 kDa RII-binding protein was identified in Golgi vesicles using a [32P]RII overlay of Western blots. The existence of an endogenous RII beta-p85 complex in isolated Golgi vesicles was demonstrated by two independent means: (i) co-immunoprecipitation of both proteins under non-denaturing conditions with an antibody against RII beta and (ii) co-purification of RII beta-p85 complexes on a cAMP-analogue affinity column. p85 was phosphorylated by both endogenous and purified catalytic subunits of cAMP-pKII. Extraction experiments and protease protection experiments indicated that p85 is an integral membrane protein although it partitioned atypically during Triton X-114 phase separation. We propose that p85 anchors RII beta to the Golgi apparatus of human lymphoblasts and thereby defines the Golgi substrate targets most accessible to phosphorylation by C subunit. This mechanism may be relevant to the regulation of processes involving the Golgi apparatus itself, such as membrane traffic and secretion, but also relevant to nearby nuclear events dependent on C subunit.

Cortical morphogenesis in Paramecium: a transcellular wave of protein phosphorylation involved in ciliary rootlet disassembly.

In Paramecium, the morphogenesis of the cortex at cell division, which assures reconstruction of shape and surface pattern, has been shown to involve transcellular signals which spread across the cortex like a wave, originating principally from the oral apparatus. One of the events these signals control is the reorganization of the ciliary rootlets through a cycle of regression and regrowth. The ciliary rootlets are nucleated on the ciliary basal bodies and form a scaffold extending over the entire cell surface that is important in aligning the basal bodies and the unit territories organized around them in longitudinal rows. We present evidence that the mechanism underlying their reorganization is cell-cycle-dependent phosphorylation of the structural proteins which compose the ciliary rootlets. We have isolated the rootlets and prepared a polyclonal antibody against them. In situ immunofluorescence of dividing cells with the anti rootlet antibody, and with the monoclonal antibody MPM-2 specific for phosphoproteins shows that a wave of phosphorylation of the ciliary rootlets spreads across the cell at division and just precedes their regression. Two-dimensional Western blot analysis of cytoskeleton and isolated rootlets along with alkaline phosphatase treatment demonstrates that the rootlets are composed of phosphoproteins, while experiments with interphase and dividing cells provide direct evidence that hyperphosphorylation of these proteins at division brings about disassembly of the structure.

Purification of the surface membrane-cytoskeleton complex (Cortex) of Paramecium and identification of several of its protein constituents.

In ciliates, the major morphogenetic events take place in the cortex, a complex of membranes and closely associated filamentous networks. To analyze the problems of assembly and morphogenesis at the molecular level in Paramecium, we have developed a method of purification of cortex fragments which retain their in situ organization and display a highly reproducible electrophoretic profile. The method used either a four-step sucrose gradient yielding a cortex + oral apparatus fraction or a six-step gradient which allowed the cortex fragments to be freed from the oral apparatuses (which were recovered separately). By comparative electrophoresis and immunological probing of these and other cell fractions or purified organelles, we could identify several of the major polypeptides resolved by SDS PAGE as components of specific cortical or oral structures. The purification method was successfully applied to morphological mutants, and the first case of a mutational modification of a cortical polypeptide was observed.

Protein phosphorylation and dynamics of cytoskeletal structures associated with basal bodies in Paramecium.

The presence of phosphorylated proteins associated with microtubule organizing centers in tissue culture cells during mitosis has been demonstrated by the use of monoclonal antibodies raised against mitotic HeLa cells [Vandre et al., Proc. Natl. Acad. Sci. U.S.A. 81:4439-4443, 1984]. We report here that in Paramecium two of the mitosis specific antibodies, MPM-1 and MPM-2, decorate throughout the cell cycle all the microtubule organizing centers (MTOCs) located in the cortex and in the oral apparatus (gullet). Immuno-electron microscopy showed that these antibodies labeled the electron-dense material surrounding basal bodies from which several microtubule networks as well as kinetodesmal fibers originate. During mitosis, these antibodies also stained other cortical cytoskeletal structures, the kinetodesmal fibers (MPM-1 and MPM-2) and the epiplasm (MPM-1). Among the different polypeptides recognized by the antibodies on immunoblots, three major ones of 60, 63, and 116 kDa were found to be common to the cortex (where several thousand ciliary basal bodies are anchored) and the oral apparatus (which comprises several hundred basal bodies around which various arrays of cytoplasmic microtubules are organized). Alkaline phosphatase treatment abolished the immunoreactivity of the polypeptides and the labeling observed by immunofluorescence. These results demonstrate that phosphorylated proteins are associated with all the known active microtubule organizing centers present in the cortex throughout the cell cycle of Paramecium. Furthermore they indicate that in Paramecium phosphorylation of proteins could also be involved in the cell cycle dependent dynamics of cortical cytoskeletal structures other than microtubules.

Centriole distribution during tripolar mitosis in Chinese hamster ovary cells.

During bipolar mitosis a pair of centrioles is distributed to each cell but the activities of the two centrioles within the pair are not equivalent. The parent is normally surrounded by a cloud of pericentriolar material that serves as a microtubule-organizing center. The daughter does not become associated with pericentriolar material until it becomes a parent in the next cell cycle (Rieder, C.L., and G. G. Borisy , 1982, Biol. Cell., 44:117-132). We asked whether the microtubule-organizing activity associated with a centriole was dependent on its becoming a parent. We induced multipolar mitosis in Chinese hamster ovary cells by treatment with 0.04 micrograms/ml colcemid for 4 h. After recovery from this colcemid block, the majority of cells divided into two, but 40% divided into three and 2% divided into four. The tripolar mitotic cells were examined by antitubulin immunofluorescence and by high voltage electron microscopy of serial thick (0.25-micron) sections. The electron microscope analysis showed that centriole number was conserved and that the centrioles were distributed among the three spindle poles, generally in a 2:1:1 or 2:2:0 pattern. The first pattern shows that centriole parenting is not prerequisite for association with pole function; the second pattern indicates that centrioles per se are not required at all. However, the frequency of midbody formation and successful division was higher when centrioles were present in the 2:1:1 pattern. We suggest that the centrioles may help the proper distribution and organization of the pericentriolar cloud, which is needed for the formation of a functional spindle pole.