|
|
|
|
|
|
|
||
Report |
Xenopus tropicalis egg extracts provide insight into scaling of the mitotic spindle
Correspondence to Rebecca Heald: heald{at}socrates.berkeley.edu
 Top Abstract IntroductionResults and discussionMaterials and methodsReferences |
|---|
The African clawed frog Xenopus laevis has been instrumental to investigations of both development and cell biology, but the utility of this model organism for genetic and proteomic studies is limited by its long generation time and unsequenced pseudotetraploid genome. Xenopus tropicalis, which is a small, faster-breeding relative of X. laevis, has recently been adopted for research in developmental genetics and functional genomics, and has been chosen for genome sequencing. We show that X. tropicalis egg extracts reconstitute the fundamental cell cycle events of nuclear formation and bipolar spindle assembly around exogenously added sperm nuclei. Interestingly, X. tropicalis spindles were
30% shorter than X. laevis spindles, and mixing experiments revealed a dynamic, dose-dependent regulation of spindle size by cytoplasmic factors. Measurements of microtubule dynamics revealed that microtubules polymerized slower in X. tropicalis extracts compared to X. laevis, but that this difference is unlikely to account for differences in spindle size. Thus, in addition to expanding the range of developmental and cell biological experiments, the use of X. tropicalis provides novel insight into the complex mechanisms that govern spindle morphogenesis.
M.D. Blower's present address is Dept. of Molecular Biology, Massachusetts General Hospital, Boston, MA 02114.
Abbreviations used in this paper: CSF, cytostatic factor; HCG, human chori-onic gonadotropin; NuMA, nuclear mitotic apparatus protein; Xnf7, Xenopus nuclear factor 7.
 |
Introduction |
|---|
|
TopAbstractIntroductionResults and discussionMaterials and methodsReferences |
|---|
|
Results and discussion |
|---|
|
TopAbstractIntroductionResults and discussionMaterials and methodsReferences |
|---|
0.6 mm diam) are approximately one fifth the volume of those of X. laevis (1.2 mm diam). To test whether X. tropicalis eggs could be used to prepare functional cellular extracts, we collected, dejellied, and crushed unfertilized eggs, which, like those of X. laevis, are arrested in metaphase of meiosis II by cytostatic factor (CSF) activity (Murray, 1991). Metaphase-arrested X. tropicalis egg extracts assembled spindle structures around exogenously added sperm nuclei, entered interphase, and replicated DNA when released from the arrest, and then cycled back into mitosis (Fig. 1 A).
Although yields of extract per frog were 10–20% that of X. laevis, X. tropicalis egg extracts effectively recapitulated cell cycle events in vitro.
|
X. laevis biochemistry is not underpinned by genomic information, making identification of proteins by mass spectrometry difficult. To test whether X. laevis proteins could be identified using the X. tropicalis database, we immunoprecipitated the microtubule-associated developmental regulator Xenopus nuclear factor 7 (Xnf7; Maresca et al., 2005b) from both X. laevis and X. tropicalis extracts (Fig. 2 A), and then used MALDI mass spectrometry to identify each protein using databases from both species. Xnf7 was identified from both immunoprecipitates using either database (Fig. 2 B), although the number of peptides identified was higher when queried against the database of the same species. Conceptual trypsin digestion of Xnf7 from both species and comparison of the peptides revealed that although the two proteins are highly conserved (Fig. 2 C), only 45% of the peptides have identical masses (not depicted). This analysis suggests that although the X. tropicalis database will greatly facilitate the identification of X. laevis proteins by mass spectrometry, it will be more efficient to identify homologous X. tropicalis proteins.
|
30% shorter) than those assembled in X. laevis extract (Fig. 3 A).
Comparing the fluorescence area of the two types of spindles revealed an approximately threefold difference (unpublished data), indicating a substantially greater microtubule mass in X. laevis spindles compared with those of X. tropicalis. This prompted us to examine the poorly understood phenomenon of spindle scaling further.
|
55% that of X. laevis (3 x 109 bp; Hirsch et al., 2002), and found that spindles assembled around X. tropicalis chromosomes were 10% shorter in all cases (Fig. 3 B). Therefore, we conclude that although chromatin mass does influence spindle length, soluble cytoplasmic factors are the major determinant in Xenopus egg extracts.
To examine whether spindle size regulation is a static or dynamic process, we added fresh extract to preassembled spindles. To X. tropicalis extracts containing spindles that had incorporated X-rhodamine–labeled tubulin, we added three volumes of either X. tropicalis or X. laevis extract containing Alexa Fluor 488 tubulin, and examined spindle length at various time points after mixing. Whereas X. tropicalis extract did not affect spindle length over the course of the experiment, addition of X. laevis extract caused rapid growth of X. tropicalis spindles, by 5 µm in length within 2 min, and to the size of premixed (75% X. laevis, 25% X. tropicalis) reactions within 5 min (Fig. 4 A).
Reciprocally, the addition of X. tropicalis extract to preformed X. laevis spindles rapidly shrank them to the size of the premixed controls, whereas addition of X. laevis extract did not (Fig. 4 B). The added extract tubulin appeared to incorporate at the plus ends of growing microtubules in the central spindle (Fig. 4, A and B). These results demonstrate that soluble cytoplasmic factors dynamically govern spindle length in Xenopus extracts, in agreement with results obtained in Drosophila melanogaster cells (Goshima et al., 2005), and indicate that nonmicrotubule spindle matrix elements determining length, if they exist, cannot be purely static structures (Chang et al., 2004).
|
20% slower in the X. tropicalis extracts (14.7 µm/min vs. 18.5 µm/min in X. laevis; P < 0.015 in t test), catastrophe and rescue frequencies were similar, and the calculated steady-state microtubule lengths were not significantly different (Table I; Verde et al., 1992). Another mode of microtubule turnover in the spindle is poleward microtubule flux, which is when microtubules coordinately polymerize at their plus ends and depolymerize at their minus ends as antiparallel microtubules slide apart (Khodjakov and Kapoor, 2005). We measured these rates using speckle microscopy to mark the spindle microtubule lattice, and found values in both extracts similar to those previously described for X. laevis (Table I; 1.79 ± 0.33 µm/min for X. laevis; 2.25 ± 0. 25 µm/min for X. tropicalis; Desai et al., 1998). Thus, our results indicate that the coordinated microtubule sliding with balanced plus end polymerization and minus end depolymerization are not significantly different in the two extracts.
|
In conclusion, X. tropicalis provides molecular advantages over X. laevis as a genetically and proteomically tractable system that can be applied to address cell biological questions using in vitro approaches. Although it could be expected that the smaller X. tropicalis eggs would have smaller spindles, our results show that this is because of a difference in cytoplasmic factors, rather than the size of the cell itself. By comparing cytoplasmic activities that are intrinsic to X. laevis and X. tropicalis extracts, new insights can be gained into mechanisms regulating cellular morphogenesis.
|
Materials and methods |
|---|
|
TopAbstractIntroductionResults and discussionMaterials and methodsReferences |
|---|
16 h before a hormone boost of 200 U HCG. Laying commenced 4–5 h after the second HCG injection, and eggs were collected into water at 27–28°C (http://tropicalis.berkeley.edu/home/). Frogs were also squeezed 6 h after the second HCG injection, and we found no substantial difference in the quality of the laid versus squeezed eggs. Pooled eggs were dejellied using 3% cysteine in water adjusted to pH 7.8 with NaOH. Incubation of frogs at temperatures below 23°C inhibited egg laying, and resulted in poor extracts. Once the extract was prepared it was stored at 16°C, as extended storage at 4°C resulted in a loss of CSF arrest. Typical extract yield was 200–400 µl per frog.
Spindle size determination in mixed extract
X. laevis and X. tropicalis extracts were mixed in different proportions and supplemented with either X. laevis or X. tropicalis sperm nuclei prepared by standard procedures (Murray, 1991) at a concentration of 500 sperm/µl, and X-rhodamine tubulin at 0.125 mg/ml. Cycling reactions were performed, and reactions were diluted into spindle fix (30% glycerol, 1x BRB80, and 0.5% Triton X-100), spun onto coverslips, fixed in –20°C methanol, and mounted in Vectashield according to standard procedures (Desai et al., 1999). Images were collected with a fluorescence microscope (BX51; Olympus) and a cooled charge-coupled device camera (Orca II; Hamamatsu), and spindle lengths were measured using MetaMorph software (Molecular Devices). Spindle area measurements were made using thresholded images in MetaMorph. Mixing experiments were performed three independent times by three different investigators, and the results were averaged.
Immunoprecipitation and mass spectrometry of Xnf7
The Xnf7 polyclonal antibody was coupled to protein A dynabeads, as previously described (Maresca et al., 2005b). For immunoprecipitating Xnf7, 110 µl of either X. tropicalis or X. laevis CSF extract was subjected to three successive 45-min incubations on ice with anti-Xnf7–coated dynabeads. The beads from each round were pooled and washed extensively with XB before eluting for 5 min at room temperature into SDS sample buffer and retrieving the beads on a magnet. Half of the supernatant was subjected to SDS-PAGE, the gel was stained with Gradipure colloidal G-250 Coomassie blue stain (NuSep), and the indicated bands were excised and subjected to mass spectrometry at the University of California Berkeley Mass Spectrometry Facility.
Dynamics of spindle size determination
CSF reactions containing X. laevis sperm nuclei and 25 µl X. tropicalis extract (with X-rhodamine tubulin) or X. laevis extract (with Alexa Fluor 488 tubulin) were cycled through interphase and back into metaphase by the addition of 25 µl of the same type of extract (no sperm). Once metaphase spindles had assembled, the extract was split into two tubes, each containing 25 µl of the reaction mixture. As a control, 75 µl of the same type of extract supplemented with the other labeled tubulin was added to one of the tubes, while 75 µl of the opposing extract was added to the other 25-µl reaction. Each of the 100-µl reactions were quickly split into 4 separate tubes, and spindles from each condition were diluted and spun down onto coverslips as described in Spindle size determination in mixed extract for imaging and length measurements. All spindle reactions were incubated at 23°C.
Microtubule dynamics and flux measurements
Centrosomes were prepared from KE37 cells as previously described (Chretien et al., 1997) and stored at –80°C. CSF extracts were prepared as described in the section Preparation of CSF extracts from X. tropicalis, and supplemented with either rhodamine tubulin (Cytoskeleton) or Alexa Fluor 488 tubulin (a gift from T. Whittman, University of California, San Francisco, San Francisco, CA) at 0.2 mg/ml. Centrosome reactions consisted of 8 µl of extract plus labeled tubulin, 1 µl of centrosomes, and 1 µl of Oxyrase. X. laevis extracts were incubated at 20°C, and X. tropicalis extracts were incubated at 23°C. To image centrosomes, 1 µl of extract was squashed under a 22-mm2 coverslip and imaged using a 100x/1.3 NA objective. All glassware was base cleaned and stored in 95% ethanol until the time of use. Images were acquired every 3 s for 1–3 min. Microtubule lengths were measured if the microtubule could be followed for at least five successive frames. Microtubule lengths were measured as the distance from the center of the centrosome to the tip of the microtubule. Dynamics measurements were calculated using a custom-made spreadsheet (a gift from R. Tournebize, Institute Pasteur, Paris, France). Calculation of Fcat and Fres were made by manual inspection of raw growth and shrinkage measurements.
MT flux measurements were made using fluorescence speckle microscopy by incubation of cycled spindles with rhodamine-labeled tubulin at a concentration of 1 µg/ml (Kapoor and Mitchison, 2001). 2 µl of extract was gently squashed under a 22 x 22-mm coverslip previously outlined using a PAP pen. Images of speckles were collected every 5 s for 2 min using a 60x/1.4 NA objective. Speckle movements were tracked on kymographs to calculate the rate of flux. Measurements were made from at least five separate spindles from three different extracts for both X. laevis and X. tropicalis.
|
Acknowledgments |
|---|
This work was supported by National Institutes of Health (NIH) grants to R. Heald (GM057839 and DP1OD00081) and R.M. Harland (GM66684). M.D. Blower is supported by the Damon Runyon Cancer Research Foundation.
Submitted: 10 October 2006
Accepted: 31 January 2007
|
References |
|---|
|
TopAbstractIntroductionResults and discussionMaterials and methodsReferences |
|---|
Birsoy, B., L. Berg, P.H. Williams, J.C. Smith, C.C. Wylie, J.L. Christian, and J. Heasman. 2005. XPACE4 is a localized pro-protein convertase required for mesoderm induction and the cleavage of specific TGFbeta proteins in Xenopus development. Development. 132:591–602.
Blower, M.D., M. Nachury, R. Heald, and K. Weis. 2005. A Rae1-containing ribonucleoprotein complex is required for mitotic spindle assembly. Cell. 121:223–234.[CrossRef][Medline]
Brown, D.D. 2004. A tribute to the Xenopus laevis oocyte and egg. J. Biol. Chem. 279:45291–45299.
Chang, P., M.K. Jacobson, and T.J. Mitchison. 2004. Poly(ADP-ribose) is required for spindle assembly and structure. Nature. 432:645–649.[CrossRef][Medline]
Chretien, D., B. Buendia, S.D. Fuller, and E. Karsenti. 1997. Reconstruction of the centrosome cycle from cryoelectron micrographs. J. Struct. Biol. 120:117–133.[CrossRef][Medline]
Dasso, M., and J.W. Newport. 1990. Completion of DNA replication is monitored by a feedback system that controls the initiation of mitosis in vitro: studies in Xenopus. Cell. 61:811–823.[CrossRef][Medline]
Desai, A., P.S. Maddox, T.J. Mitchison, and E.D. Salmon. 1998. Anaphase A chromosome movement and poleward spindle microtubule flux occur at similar rates in Xenopus extract spindles. J. Cell Biol. 141:703–713.
Desai, A., A. Murray, T.J. Mitchison, and C.E. Walczak. 1999. The use of Xenopus egg extracts to study mitotic spindle assembly and function in vitro. Methods Cell Biol. 61:385–412.[Medline]
Funabiki, H., and A.W. Murray. 2000. The Xenopus chromokinesin Xkid is essential for metaphase chromosome alignment and must be degraded to allow anaphase chromosome movement. Cell. 102:411–424.[CrossRef][Medline]
Goshima, G., R. Wollman, N. Stuurman, J.M. Scholey, and R.D. Vale. 2005. Length control of the metaphase spindle. Curr. Biol. 15:1979–1988.[CrossRef][Medline]
Hannak, E., and R. Heald. 2006. Xorbit/CLASP links dynamic microtubules to chromosomes in the Xenopus meiotic spindle. J. Cell Biol. 172:19–25.
Hirsch, N., L.B. Zimmerman, and R.M. Grainger. 2002. Xenopus, the next generation: X. tropicalis genetics and genomics. Dev. Dyn. 225:422–433.[CrossRef][Medline]
Kapoor, T.M., and T.J. Mitchison. 2001. Eg5 is static in bipolar spindles relative to tubulin: evidence for a static spindle matrix. J. Cell Biol. 154:1125–1133.
Khodjakov, A., and T. Kapoor. 2005. Microtubule flux: what is it good for? Curr. Biol. 15:R966–R968.[CrossRef][Medline]
Klein, S.L., R.L. Strausberg, L. Wagner, J. Pontius, S.W. Clifton, and P. Richardson. 2002. Genetic and genomic tools for Xenopus research: The NIH Xenopus initiative. Dev. Dyn. 225:384–391.[CrossRef][Medline]
Maresca, T.J., B.S. Freedman, and R. Heald. 2005a. Histone H1 is essential for mitotic chromosome architecture and segregation in Xenopus laevis egg extracts. J. Cell Biol. 169:859–869.
Maresca, T.J., H. Niederstrasser, K. Weis, and R. Heald. 2005b. Xnf7 contributes to spindle integrity through its microtubule-bundling activity. Curr. Biol. 15:1755–1761.[CrossRef][Medline]
Merdes, A., K. Ramyar, J.D. Vechio, and D.W. Cleveland. 1996. A complex of NuMA and cytoplasmic dynein is essential for mitotic spindle assembly. Cell. 87:447–458.[CrossRef][Medline]
Murray, A.W. 1991. Cell cycle extracts. Methods Cell Biol. 36:581–605.[Medline]
Nicklas, R.B., and G.W. Gordon. 1985. The total length of spindle microtubules depends on the number of chromosomes present. J. Cell Biol. 100:1–7.
Nishitani, H., H. Kobayashi, M. Ohtsubo, and T. Nishimoto. 1990. Cloning of Xenopus RCC1 cDNA, a homolog of the human RCC1 gene: complementation of tsBN2 mutation and identification of the product. J. Biochem. (Tokyo). 107:228–235.
Srayko, M., E.T. O'Toole, A.A. Hyman, and T. Muller-Reichert. 2006. Katanin disrupts the microtubule lattice and increases polymer number in C. elegans meiosis. Curr. Biol. 16:1944–1949.[CrossRef][Medline]
Verde, F., M. Dogterom, E. Stelzer, E. Karsenti, and S. Leibler. 1992. Control of microtubule dynamics and length by cyclin A- and cyclin B-dependent kinases in Xenopus egg extracts. J. Cell Biol. 118:1097–1108.
CiteULike 
Complore 
Connotea 
Del.icio.us 
Digg 
Facebook 
Reddit 
Technorati 
Twitter What's this?
This article has been cited by other articles:
| |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
|
|
-H1 and 
