1 NERC Center for Population Biology, Imperial College London, Silwood Park Campus, Ascot SL5 7PY, UK
2 Wellcome Trust-Cancer Research UK Institute, Tennis Court Road, Cambridge CB2 1QR, UK
3 Department of Pharmacological Sciences, SUNY, Stony Brook, NY 11794-8651, USA
4 Biological Sciences Institute, Faculty of Life Sciences, University of Dundee, Dundee DD1 4HN, UK
Author for correspondence (e-mail: w.g.f.whitfield{at}dundee.ac.uk)
Accepted 11 November 2003
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Summary |
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Key words: Drosophila, Centrosome, CP190, CP60, Mitosis
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Introduction |
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CP190 begins to accumulate at the centrosome as soon as nuclear envelope breakdown occurs, whereas CP60 accumulates later and reaches maximal levels only in anaphase/telophase (Oegema et al., 1997). CP60 is extensively phosphorylated in vivo, and contains several cdc2 consensus phosphorylation sites (Kellogg et al., 1995
). Intriguingly, when purified CP60 is phosphorylated by cdc2/cyclin B kinase in vitro, it loses its ability to interact with microtubules (Kellogg et al., 1995
). These findings have led to the suggestion that the CP190-CP60 complex may be involved in regulating the interaction between centrosomes and microtubules during anaphase/telophase, when their levels at centrosomes are maximal, and when cdc2/cyclin B activity is in decline. However, despite widespread use of CP190 as a centrosomal marker in many avenues of Drosophila research, its centrosomal function and that of CP60 remains unknown.
Although both CP190 and CP60 were originally identified and characterised as a consequence of their association with the centrosome and with microtubules, during interphase they are both localised within the nucleus. Indeed, the amino acid sequence of CP190 suggests that it is a C2H2 zinc-finger protein, and both CP190 and CP60 bind to specific chromosomal loci on salivary gland polytene chromosomes, leading to the suggestion that these proteins play a role in interphase nuclei (Whitfield et al., 1995). Subsequent work has indicated that both proteins are components of the nuclear matrix, as they remain insoluble after nuclei have been treated with DNAse I and extracted with high salt (Oegema et al., 1997
). In the same paper, evidence from wide-field 3D microscopy studies was presented, showing that in diploid interphase nuclei of cycle 13 embryos, CP190 and CP60 do not extensively co-localise with each other or with DNA [in contrast to the observations of Whitfield et al. (Whitfield et al., 1995
) on polytene chromosomes], suggesting that these proteins may be components of distinct extra-chromosomal nuclear domains (ENDs). In support of this possibility, overexpression of the EAST protein, a known END component, specifically recruits extra CP60 to an expanded END (Wasser and Chia, 2000
). However, the nuclear roles of CP190 and CP60, whether chromosomal or extra-chromosomal, remain as obscure as their centrosomal functions.
Here we have used RNA-mediated interference to deplete the levels of CP190 and CP60 in Drosophila S2 cells, and we have identified mutations in the Cp190 gene. Our studies demonstrate that CP190 is essential for fly viability, but suggest that neither CP190 nor CP60 are involved in regulating centrosome or microtubule behaviour during mitosis.
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Materials and Methods |
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Fly strains
Flies were maintained on standard corn meal Drosophila medium at 25°C. The following strains were used in these studies: w67 was the parental line used to generate all transformed lines; mwh1 red1 P{hsneo}l(3)neo431 e1/TM3, ryRK Sb1 Ser1 was the P-element insertion stock used to generate Df(3R)P280NR27 by male recombination; y* w*; CyO, H{w+mC=PDelta2-3}HoP2.1/Bc1 EgfrE1 (derived by William Gelbart, Harvard University) was employed as the source of transposase for promoting male recombination; red1 e1 males were used for ethylmethane sulphonate (EMS) mutagenesis; ms(3)K81/TM3 Sb1 Ser1 e1 was used to balance mutagenised red1 e1 chromosomes prior to screening over Df(3R)P280NR27. All stocks other than w67 and those whose derivation is described below, were obtained from Bloomington Stock Center, University of Indiana, USA.
Derivation of deficiencies uncovering the Cp190 locus
Virgin females from the P-element insertion line mwh1 red1 P{hsneo}l(3)neo431 e1/TM3, ryRK Sb1 Ser1 were crossed with y* w*; CyO, H{P{Delta2-3}}HoP2.1/Bc1 EgfrE1 males. CyO, H{P{Delta2-3}}HoP2.1/+; mwh1 red1 P{hsneo}l(3)neo431 e1/+ males were selected from the progeny and crossed en masse with red1 e1 virgin females. Recombinant (red+ e1/red1 e1 or red1 e+/red1 e1) male progeny from this cross were individually mated to TM6B/TM3 red* Ser1 e1 virgin females before extracting their genomic DNA. Candidate deficiencies were identified by electrophoretic analysis of PCR-amplified products from these DNA samples using 3 oligonucleotide primers: one complementary to the inverted repeat of the P-element [5'-CGA CGG GAC CAC CTT ATG TTA TTT C-3'], one complementary to a flanking genomic site 2.2 kb from the site of insertion (proximal to Cp190) [5'-ATG CCT ATG CAG CCT GCA AGA GCA GCG ATG-3'] and one complementary to a flanking genomic site 1.5 kb from the site of insertion (distal to Cp190) [5'-CTT GGA GAA CAT TTG CCA GTC CGA GGT TGG-3']. Balanced stocks were established from lines corresponding to PCR products which showed absence of the 2.2 kb band but presence of the 1.5 kb band. Deficiency breakpoints of these stocks were identified by cloning the P-element (by means of its pUC insert) and sequencing of the associated genomic DNA using standard methods.
EMS mutagenesis screen for identification of Cp190 mutants
Approximately 100 four day-old red1 e1 males were starved for 8 hours before feeding on 5% (w/v) sucrose containing 10 mM EMS for 15 hours. The EMS-treated males were transferred to freshly yeasted bottles and mated to ms(3)K81/TM3 Sb Ser e1 virgin females at approximately 10 males and 50 females per bottle. After 4 days at 25°C the males were discarded, and the females transferred to fresh bottles every 2 days until they ceased to lay. Approximately 6000 red1 e1/TM3 Sb Ser e1 males were selected from the resulting progeny, and each mated in a separate yeasted vial with 5 red+ Df(3R)P280NR27 e1/TM3 red Ser e1 virgin females. Recessive lethal mutations uncovered by the deficiency were identified by screening the progeny from each vial for the absence of red*e1/red+ Df(3R)P280NR27 e1 flies, and stocks were established from their red1 *e1/TM3 red* Ser e1 siblings. Candidate Cp190 mutants were retested by mating males to red1 Df(3R)P280NR27 e+/TM3 red1 Ser e1 virgin females, and their status subsequently confirmed by rescue of both hemizygous and homozygous mutations by expression of a transgenic copy of Cp190 under control of the polyubiquitin promoter.
Larval brain and testes squashes
Larval brains and testes were squashed and prepared for immunostaining as described previously (Williams and Goldberg, 1994). If brains were also to be stained to reveal the distribution of microtubules, then the protocol of Bonaccorsi et al. (Bonaccorsi et al., 2000
) was followed. Incubation of slides with primary antibodies (diluted in PBT) was performed overnight in a humidified chamber at 4°C. After washing the slides 3 times in PBT, secondary antibodies were applied for 4 hours at room temperature. The slides were finally given 4x15-minute washes in PBT, before counterstaining for DNA with 0.5 µg ml1 Hoechst 33258 and mounting in 95% v/v glycerol in PBS containing 2.5% w/v n-propyl gallate.
Microtubule-spin downs, SDS-PAGE, and western blotting
Microtubule spin downs from embryo extracts expressing CP190M, SDS-PAGE and western blotting were performed as described previously (Gergely et al., 2000
; Laemmli, 1970
)
Antibodies
The following antibodies were used in this study: the affinity-purified rabbit anti-CP190 and anti-CP60 have been described previously (Kellogg et al., 1995; Oegema et al., 1995
), as has the rabbit anti-CNN anti-serum (Li and Kaufman, 1996
), and the anti-D-TACC and anti-Msps affinity purified rabbit antibodies (Gergely et al., 2000
; Lee et al., 2001
). The mouse monoclonal DM1a (Sigma) was used to detect tubulin; the mouse monoclonal GTU88 (Sigma) was used to detect gamma-tubulin; an anti-phospho-histone H3 rabbit serum (Upstate Technology) was used to detect phospho-histone H3. All affinity-purified antibodies were used at 1-2 µg/ml in western blotting or immunofluorescence experiments. The DM1a, GTU88 and anti-phospho-histone H3 antibodies were used at a 1:500 dilution in western blotting and immunofluorescence studies.
Transgenic lines that express CP190, CP190M and CP60
To create transgenic lines that express CP190 and CP60, the full-length cDNAs were subcloned into the pWR-Pubq transformation vector that constitutively drives relatively high levels of expression throughout the organism (Lee et al., 1998; Gergely et al., 2000). To generate flies expressing CP190
M, the full-length CP190 cDNA was digested with BamHI and BssHII. The reaction was end-filled with klenow and re-ligated. This created an in-frame deletion of amino acids 311-541 of the CP190 coding sequence (thus deleting the previously identified centrosomal and microtubule targeting domain between amino acids 385-508). The resulting deleted cDNA was then subcloned into pWR-Pubq. Full cloning details are available upon request. Transformants were generated using standard P-element-mediated transformation (Roberts, 1986
).
Image acquisition
The imaging of all brain and testes preparations was performed on a Zeiss Axioskop 2 microscope with a Photometrics CoolSnap HQ camera using MetaMorph software (Universal Imaging). The imaging of S2 tissue culture cells was performed on a Nikon E800 microscope with a Bio-Rad Radiance confocal system. All images were imported into Adobe Photoshop where the entire image was adjusted to use the full range of pixel intensities. In some images an Unsharp Mask filter was also applied to the entire image. In all cases, control and experimental images were treated in exactly the same way.
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Results |
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Immunofluorescence analysis of fixed cells at the 96 hour time point confirmed that both proteins were substantially depleted from cells (Fig. 2). The organisation of microtubules throughout mitosis appeared to be unaffected by the depletion of either CP190 or CP60 (Fig. 2A,B), and several centrosomal markers such as -tubulin, Centrosomin, D-TACC and Msps appeared to localise normally to centrosomes in CP190- or CP60-depleted cells (not shown, see below). The localisation of CP190 to nuclei in interphase and to centrosomes in mitosis was unaffected by the depletion of CP60 (Fig. 2C). In contrast, although the localisation of CP60 to nuclei in interphase was not affected by the depletion of CP190, the localisation of CP60 to mitotic centrosomes was strongly inhibited in the CP190-depleted cells (Fig. 2C). Thus, neither CP190 nor CP60 appear to be required to organise centrosomes or microtubules during cell division in Drosophila S2 tissue culture cells. However, the presence of CP190 appears to be necessary for the recruitment of CP60 to mitotic centrosomes.
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Isolation of mutations in the Cp190 gene
To test whether CP190 has an essential function in flies, we performed a genetic screen to isolate mutations in the Cp190 gene. Screening was performed in two stages: the first to generate a suitable deficiency to uncover the Cp190 gene locus at 88E, and the second to exploit this deficiency to identify candidate Cp190 mutations.
Starting with a P-element insertion P{hsneo}l(3)neo431 (Cooley et al., 1988), mapping approximately 4.5 kb upstream of the Cp190 gene (Fig. 3A), P-element-mediated male recombination was used to generate deficiencies at or near the insertion site (Preston et al., 1996
). Nearly 100 recombinants were isolated from a screen of over 2x105 flies, and from these, 4 fly-lines were identified that carried candidate Cp190 deficiencies. Subsequent cloning and sequencing of the deficiency breakpoints revealed one deficiency, Df(3R)P280NR27, with a breakpoint in the second exon of the Cp190 gene. In addition to Cp190, Df(3R)P280NR27 includes only three other gene loci, one encoding a homologue of the human chromodomain protein MRG15 (CG6363), the other two being uncharacterised genes (CG4338 and CG14865) (Fig. 3A).
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A standard EMS mutagenesis screen (Ashburner, 1989) was then performed to isolate mutations that were either lethal or female sterile over the Df(3R)P280NR27 deficiency chromosome. From approximately 6x103 mutated chromosomes, four candidate Cp190 mutants were isolated as recessive lethals over Df(3R)P280NR27. All four mutants were fully rescued as hemizygotes over Df(3R)P280NR27 by a second chromosome insertion of the full-length Cp190 cDNA expressed under control of the polyubiquitin promoter (Fig. 3B). Two of the four mutants, Cp1901 and Cp1902 were also fully rescued as homozygotes, demonstrating unequivocally that (at least for these two alleles) the lethality must be because of mutations at the Cp190 locus and that Cp190 is an essential gene.
Animals homozygous for Cp1901 and Cp1902 (or hemizygous over Df(3R)P280NR27), and Cp1901/Cp1902 heterozygotes show some larval mortality, but approximately half the mutants survived until late pupal stages of development, dying as pharate adults. Western blotting analysis revealed that the CP190 protein, although readily detectable in brains from wild-type 3rd instar larvae, was not seen in samples from either Cp1901 or Cp1902 homozygotes, suggesting that both lesions may be null or are at least strong hypomorphs (Fig. 3B).
Cp190 mutants do not have obvious mitotic or meiotic defects
Analysis of the eyes, wings and cuticle of pharate adults homozygous for either Cp1901 or Cp1902 revealed no obvious defects in tissue organisation, suggesting that these animals were not dying as a consequence of major defects in mitosis (data not shown). This conclusion was confirmed by a detailed analysis of mitosis in brains from homozygous mutant 3rd instar larvae. In mutant cells there were no dramatic differences in the organisation of the spindle at any stage of mitosis (Fig. 4). Astral microtubules were readily detectable in mutant spindles, even though CP190 was not detectable at centrosomes (Fig. 4). In addition, we observed many mutant neuroblasts undergoing morphologically normal asymmetric divisions (not shown). In agreement with our results using RNAi in Drosophila S2 cells, the localisation of CP60 at centrosomes was severely disrupted in Cp190 mutant larval brain cells (Fig. 5A), whereas the localisation of several other centrosome-associated proteins was not dramatically altered (Fig. 5C). Finally, the mitotic index was not significantly altered in mutant brains (data not shown), indicating that microtubule organisation was relatively normal and that the spindle assembly checkpoint was not being triggered in these cells.
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We also assayed whether meiosis occurred normally in Cp190 mutant larval testes. In fixed mutant testes, the distribution of microtubules appeared to be normal and the localisation of -tubulin and centrosomal protein centrosomin (CNN) was not perturbed during meiosis I or II (not shown). In living mutant testes, an analysis of onion stage spermatids by phase contrast microscopy revealed no obvious defects in chromosome segregation (not shown). Taken together, these data strongly suggest that although CP190 function is essential, it is not required for centrosome or microtubule function during mitosis in larval brains or meiosis in larval testes.
The ability of CP190 to interact with centrosomes and microtubules is not essential for its function
The observation that spindle formation and function is not disrupted in Cp190 mutants, raises the intriguing question of why CP190 can bind directly to microtubules and is recruited to centrosomes during mitosis if it has no function in regulating microtubule or centrosome behaviour. To address whether the ability of CP190 to bind to centrosomes and microtubules is essential for its function, we expressed a form of CP190 in flies that cannot bind to centrosomes or microtubules. It has previously been shown that amino acid residues 385-508 of CP190 can bind directly to microtubules in vitro, and can target a bacterially expressed fusion protein to centrosomes when injected into embryos (Oegema et al., 1995). We therefore made a P-element-transformation construct that deleted this region of CP190 (CP190
M Fig. 6A), and used it to derive several transgenic fly-lines that express CP190
M under the control of the polyubiquitin promoter (Lee et al., 1998; Gergely et al., 2000
).
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In extracts made from pUbq-CP190M embryos, although the endogenous CP190 strongly interacted with microtubules in microtubule spin-down experiments, CP190
M did not (Fig. 6B). In mutant larval brains that expressed the pUbq-CP190 transgene (and so contain the full-length CP190 protein), anti-CP190 antibodies strongly stained mitotic centrosomes (Fig. 6C), whereas in mutant larvae expressing the pUbq-CP190
M transgene, anti-CP190 antibodies no longer stained centrosomes during mitosis (Fig. 6C). Taken together, these data confirm that CP190
M cannot interact with microtubules or centrosomes.
To our surprise, the pUbq-CP190 and Pubq-CP190M transgenes rescued the lethality associated with Cp190 mutations with equal efficiency (Fig. 7). This demonstrates that CP190
M is at least partially functional, and that the ability of CP190 to interact with centrosomes and microtubules is not absolutely essential for the viability of the fly. However, the homozygous Cp190 mutants rescued by the CP190
M transgene were unhealthy and lived for only a few days, implying that the ability of CP190 to bind to centrosomes may be of some functional significance (see Discussion).
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Overexpression of both CP190 and CP190M is lethal
During the course of our experiments, we noticed that three out of seven transgenic Pubq-CP190 lines and all seven of our Pubq-CP190M lines were homozygous lethal at late-pupal stages of development. Indeed, even in the four Pubq-CP190 lines that were homozygous viable, there was a noticeable increase in the level of pupal mortality. When we examined the levels of CP190 and CP190
M protein in these flies we found that CP190
M was overexpressed to a greater extent than CP190 (
10-fold compared with
3-5-fold) in all of the transgenic lines (Fig. 8A). Because the mRNAs for both proteins were expressed from the same promoter and contained the same 5' and 3' UTRs, it seems probable that the consistently higher levels of CP190
M overexpression could be because of intrinsic differences in stability between the two proteins. Whatever the underlying reason, the pupal mortality in these lines appears to be directly related to the level of overexpression of CP190 or CP190
M as we were unable to generate any combination of transgenic lines that contained one copy of Pubq-CP190
M and one copy of Pubq-CP190, or any combination of transgenic lines that contained more than two copies of Pubq-CP190. These findings strongly suggest that the overexpression of CP190 or CP190
M is lethal, and that both proteins probably cause pupal lethality by the same mechanism. Analysis of larval brains and larval testes, however, revealed no obvious defects in mitosis or meiosis in larvae overexpressing either CP190 or CP190
M (not shown).
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In view of the apparent toxicity associated with overexpression of CP190, we wondered if the relative levels of CP190 and CP60 in the fly might be important. We therefore tested whether overexpression of CP60 could rescue the pupal lethality caused by the overexpression of CP190. We found that flies carrying multiple copies of a Pubq-CP60 transgene had no detectable mitotic defects in larval brains and were perfectly viable, even though they overexpressed CP60 by >20-fold (not shown, see Fig. 8B). Moreover, several lines carrying two copies of the Pubq-CP190M transgene or two copies of a lethal Pubq-CP190 transgene (that were normally homozygous lethal) were viable as adults if they also carried a copy of the Pubq-CP60 transgene (Fig. 8B). Thus, the overexpression of CP60 appears to rescue the lethality associated with the overexpression of both CP190 and CP190
M.
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Discussion |
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Although CP190 does not appear to be required for mitotic spindle function, the protein is essential, and Cp190 mutants invariably die as pharate adults. Surprisingly, this essential function of CP190 does not depend on its localisation to centrosomes, or on its ability to bind to microtubules. The transgenic expression of a form of CP190 that can no longer interact with centrosomes or microtubules (CP190M) rescued the lethality of the Cp190 mutant almost as efficiently as the transgenic expression of full-length CP190. CP190 and CP60 are both concentrated in nuclei during interphase, and appear to be components of an extra-chromosomal nuclear domain (END). The two proteins do not extensively co-localise in the nucleus, and we show here that although CP190 is required to localise CP60 to centrosomes during mitosis, it is not required to localise CP60 to nuclei. Our RNAi experiments suggest that CP60 is also not required to localise CP190 to nuclei. Thus, both proteins appear to be recruited independently to separate ENDs within the nucleus. An attractive possibility is that the essential function of CP190 is to influence events within the nucleus.
In support of this possibility, CP190 has several domains common to proteins that influence nuclear events. CP190 contains four classical C2H2 zinc-finger domains and an N-terminal Broad complex/Tramtrack/Bric-a-brac (BTB) domain a domain often found in zinc-finger-containing proteins that bind to DNA and regulate transcription or chromatin structure. Interestingly, CP190M retains the BTB domain, one of the four zinc-fingers, and it can still localise to interphase nuclei, presumably explaining how CP190
M could still perform its putative nuclear function. Moreover, our data suggests that even relatively moderate (5-10-fold) overexpression of CP190 is lethal to flies. Again, the lethality caused by the overexpression of CP190 does not require that the protein binds to centrosomes or microtubules, as the overexpression of CP190
M also leads to the same pupal lethality that is associated with the overexpression of CP190. Interestingly, the overexpression of CP60 by >20-fold does not appear to be deleterious to flies, but the co-overexpression of CP60 can rescue the lethality associated with the overexpression of CP190 or CP190
M. This suggests that the relative levels of CP190 and CP60 in the nucleus may be important. Clearly, however, more work will be required to understand the function of CP190 in the nucleus.
Finally, it is worth considering why CP190 and CP60 may have evolved an ability to interact with centrosomes and microtubules when this apparently plays no role in their function. One possibility is that these proteins do play a role in some aspect of centrosome/microtubule function, but this function is only essential during early embryogenesis. The Drosophila CNN, for example, is essential for mitosis in early embryos, but appears to be dispensable for all other cell divisions in the organism. In the case of CNN it seems that the organisation of centrosomal microtubules is perturbed to some extent in larval neuroblasts, but this centrosomal disorganisation only causes lethal errors in mitosis during early syncytial development (Megraw et al., 1999; Megraw et al., 2001
). In contrast, we find no evidence to suggest a role for CP190 in mitosis in larval neuroblasts. Nevertheless, to analyse the potential function of CP190 in early embryos, we have recently made germ line clones (Chou and Perrimon, 1996
) with the Cp1901 and Cp1902 mutations. We find that mitosis is largely unperturbed in these embryos, but that they fail in axial expansion, an actin/myosin-dependent process that normally spreads the nuclei evenly throughout the early embryo. Clearly, more work is needed to assess the role of CP190 in axial expansion, but it is possible that this function may require that CP190 can interact with centrosomes and/or microtubules.
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Acknowledgments |
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Footnotes |
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Present address: Department of Zoology, University of Oxford, South Parks Rd, Oxford OX1 3PS, UK
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References |
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---|
Adams, R. R., Maiato, H., Earnshaw, W. C. and Carmena, M. (2001). Essential roles of Drosophila inner centromere protein (INCENP) and aurora B in histone H3 phosphorylation, metaphase chromosome alignment, kinetochore disjunction, and chromosome segregation. J. Cell Biol. 153, 865-880.
Ashburner, M. (1989). Drosophila, a Laboratory Handbook. New York: Cold Spring Harbor Laboratory Press.
Barbosa, V., Yamamoto, R. R., Henderson, D. S. and Glover, D. M. (2000). Mutation of a Drosophila gamma tubulin ring complex subunit encoded by discs degenerate-4 differentially disrupts centrosomal protein localization. Genes Dev. 14, 3126-3139.
Bonaccorsi, S., Giansanti, M. G. and Gatti, M. (2000). Spindle assembly in Drosophila neuroblasts and ganglion mother cells. Nat. Cell Biol. 2, 54-56.[CrossRef][Medline]
Chou, T. B. and Perrimon, N. (1996). The autosomal FLP-DFS technique for generating germline mosaics in Drosophila melanogaster. Genetics 144, 1673-1679.
Clemens, J. C., Worby, C. A., Simonson-Leff, N., Muda, M., Maehama, T., Hemmings, B. A. and Dixon, J. E. (2000). Use of double-stranded RNA interference in Drosophila cell lines to dissect signal transduction pathways. Proc. Natl. Acad. Sci. USA 97, 6499-6503.
Cooley, L., Kelley, R. and Spradling, A. (1988). Insertional mutagenesis of the Drosophila genome with single P elements. Science 239, 1121-1128.[Medline]
Donaldson, M. M., Tavares, A. A., Ohkura, H., Deak, P. and Glover, D. M. (2001). Metaphase arrest with centromere separation in polo mutants of Drosophila. J. Cell Biol. 153, 663-676.
Frasch, M., Glover, D. M. and Saumweber, H. (1986). Nuclear antigens follow different pathways into daughter nuclei during mitosis in early Drosophila embryos. J. Cell Sci. 82, 155-172.[Abstract]
Gergely, F., Kidd, D., Jeffers, K., Wakefield, J. G. and Raff, J. W. (2000). D-TACC: a novel centrosomal protein required for normal spindle function in the early Drosophila embryo. EMBO J. 19, 241-252.
Giet, R. and Glover, D. M. (2001). Drosophila aurora B kinase is required for histone H3 phosphorylation and condensin recruitment during chromosome condensation and to organize the central spindle during cytokinesis. J. Cell Biol. 152, 669-682.
Kellogg, D. R. and Alberts, B. M. (1992). Purification of a multiprotein complex containing centrosomal proteins from the Drosophila embryo by chromatography with low-affinity polyclonal antibodies. Mol. Biol. Cell 3, 1-11.[Abstract]
Kellogg, D. R., Field, C. M. and Alberts, B. M. (1989). Identification of microtubule-associated proteins in the centrosome, spindle, and kinetochore of the early Drosophila embryo. J. Cell Biol. 109, 2977-2991.[Abstract]
Kellogg, D. R., Oegema, K., Raff, J., Schneider, K. and Alberts, B. M. (1995). Cp60 a microtubule associated protein that is localized to the centrosome in a cell cycle specific manner. Mol. Biol. Cell 6, 1673-1684.[Abstract]
Laemmli, U. K. (1970). Cleavage of the structural proteins during the assembly of the head of bacteriophage T4. Nature 227, 680-685.[Medline]
Lee, M. J., Gergely, F., Jeffers, K., Peak-Chew, S. Y. and Raff, J. W. (2001). Msps/XMAP215 interacts with the centrosomal protein D-TACC to regulate microtubule behaviour. Nat. Cell Biol. 3, 643-649.[CrossRef][Medline]
Li, K. J. and Kaufman, T. C. (1996). The homeotic target gene Centrosomin encodes an essential centrosomal component. Cell 85, 585-596.[Medline]
Megraw, T. L., Kao, L. R. and Kaufman, T. C. (2001). Zygotic development without functional mitotic centrosomes. Curr. Biol. 11, 116-120.[CrossRef][Medline]
Megraw, T. L., Li, K., Kao, L. R. and Kaufman, T. C. (1999). The centrosomin protein is required for centrosome assembly and function during cleavage in Drosophila. Development 126, 2829-2839.
Oegema, K., Marshall, W. F., Sedat, J. W. and Alberts, B. M. (1997). Two proteins that cycle asynchronously between centrosomes and nuclear structures: Drosophila CP60 and CP190. J. Cell Sci. 110, 1573-1583.
Oegema, K., Whitfield, W. G. F. and Alberts, B. (1995). The cell cycle dependent localization of the Cp190 centrosomal protein is determined by the coordinate action of 2 separable domains. J. Cell Biol. 131, 1261-1273.[Abstract]
Preston, C. R., Sved, J. A. and Engels, W. R. (1996). Flanking duplications and deletions associated with P-induced male recombination in Drosophila. Genetics 144, 1623-1638.
Raff, J. W., Kellogg, D. R. and Alberts, B. M. (1993). Drosophila gamma-tubulin is part of a complex containing two previously identified centrosomal MAPs. J. Cell Biol. 121, 823-835.[Abstract]
Roberts, D. (1986). Drosophila, A Practical Approach. Oxford: IRL Press.
Wasser, M. and Chia, W. (2000). The EAST protein of Drosophila controls an expandable nuclear endoskeleton. Nat. Cell Biol. 2, 268-275.[CrossRef][Medline]
Whitfield, W. G., Chaplin, M. A., Oegema, K., Parry, H. and Glover, D. M. (1995). The 190 kDa centrosome-associated protein of Drosophila melanogaster contains four zinc finger motifs and binds to specific sites on polytene chromosomes. J. Cell Sci. 108, 3377-3387.
Whitfield, W. G., Millar, S. E., Saumweber, H., Frasch, M. and Glover, D. M. (1988). Cloning of a gene encoding an antigen associated with the centrosome in Drosophila. J. Cell Sci. 89, 467-480.[Abstract]
Williams, B. C. and Goldberg, M. L. (1994). Determinants of Drosophila zw10 protein localization and function. J. Cell Sci. 107, 785-798.