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Cdc42-dependent actin polymerization duringcompensatory endocytosis in Xenopus eggsAnna Marie Sokac1,5, Carl Co2, Jack Taunton3 and William Bement1,4
The actin filament (F-actin) cytoskeleton associatesdynamically with the plasma membrane and is thus ideallypositioned to participate in endocytosis. Indeed, a wealth ofgenetic and biochemical evidence has confirmed that actininteracts with components of the endocytic machinery1,although its precise function in endocytosis remains unclear.Here, we use 4D microscopy to visualize the contribution ofactin during compensatory endocytosis in Xenopus laevis eggs.We show that the actin cytoskeleton maintains exocytosingcortical granules as discrete invaginated compartments, suchthat when actin is disrupted, they collapse into the plasmamembrane. Invaginated, exocytosing cortical granulecompartments are directly retrieved from the plasmamembrane by F-actin coats that assemble on their surface.These dynamic F-actin coats seem to drive closure of theexocytic fusion pores and ultimately compress the corticalgranule compartments. Active Cdc42 and N-WASP arerecruited to exocytosing cortical granule membranes before F-actin coat assembly and coats assemble by Cdc42-dependent, de novo actin polymerization. Thus, F-actin maypower fusion pore resealing and function in two novelendocytic capacities: the maintenance of invaginatedcompartments and the processing of endosomes.
In yeast, actin is firmly implicated as a mediator of endocytosis, as
genes necessary for a viable actin cytoskeleton are required for endocy-
tosis and vice versa2. In vertebrate cells, proteins associated with the
endocytic machinery interact with F-actin or with activators of
Arp2/3-dependent actin polymerization1. Conversely, the membranes
of endosomes and pinosomes are endowed with activators of actin
polymerization and can stimulate actin polymerization3–9. These
molecular links have led to numerous proposed roles for actin in
endocytosis10: for example, F-actin may function as a scaffold to con-
centrate endocytic machinery at sites of uptake. Alternatively, actin
polymerization and/or myosin-dependent processes may generate
force to drive membrane invagination, membrane fission and endo-
some trafficking. Indeed, temporal and spatial high-resolution analy-
ses of actin during endocytosis are consistent with these proposed
roles. In Swiss 3T3 cells11, actin gathers at clathrin-coated pits after
dynamin and coincident with the departure of pits/nascent coated
vesicles from the plasma membrane. If this actin is in the form of
dynamic comet tails, it may propel coated vesicles away from the
plasma membrane and into the cell interior, as previously described
for trafficking of macropinosomes in rat basophilic leukaemia cells12.
In Xenopus oocytes and eggs, the en masse membrane insertion
incurred during cortical granule exocytosis is countered by compensa-
tory endocytosis that generates large endosomes of the same size as
cortical granules13, possibly by resealing the exocytic fusion pores.
Such a mechanism, whereby emptied secretory granule membranes
are directly retrieved from the plasma membrane by reversal of fusion
pore formation, was previously described for sea urchin eggs14, as well
as mammalian neurons and endocrine cells10, and is implicit in the
‘kiss-and-run’ model of compensatory endocytosis15. To determine
whether large endosomes are directly derived from exocytosed cortical
granules in Xenopus eggs, we followed formation of large endosomes
during cortical granule exocytosis. In these cells, a wave of cortical
granule exocytosis will emanate from a site of local calcium increase16.
Thus, eggs were pricked in calcium-containing buffer supplemented
with fluorescein–dextran (F–dex) and then fixed and stained for corti-
cal granules with rhodamine–lectin. Conventional confocal
microscopy showed that cortical granule exocytosis near the prick site
correlates with the appearance of F–dex-filled large endosomes
(Fig. 1a). Large endosomes were approximately the same size as corti-
cal granules and, as revealed by imaging regions far from the prick site,
large endosome formation required earlier cortical granule exocytosis.
Strikingly, some large endosomes contained both F–dex and rho-
damine–lectin, demonstrating that large endosomes are derived from
cortical granules and so represent the exocytosis–endocytosis interme-
diate generated when emptied cortical granule membranes are directly
retrieved from the plasma membrane.
To investigate the role of actin in large endosome formation, eggs
pricked in extracellular Texas Red–dextran (TR–dex) were fixed and
stained for F-actin with Alexa488–phalloidin. In single optical plane,
en face views, F-actin rings encircled large endosomes (Fig. 1b). Z-
sections revealed that the F-actin rings are spherical coats that encase
the large endosomes (Fig. 1c).
Cortical actin dynamics during large endosome formation were
then examined in living eggs by time-lapse confocal microscopy in a
single optical plane. Eggs were injected with Alexa488-labelled G-actin
(Alexa488–G-actin) and caged inositol-1,4,5-trisphosphate (caged
1Department of Zoology, University of Wisconsin, Madison, WI 53706, USA. 2Program in Biological Sciences, University of California, San Francisco, CA 94107,USA. 3Department of Cellular and Molecular Pharmacology, University of California, San Francisco, CA 94107, USA. 4Program in Molecular and Cellular Biology,University of Wisconsin, Madison, WI 53706, USA. 5Current address: Department of Molecular Biology, Princeton University, Princeton, NJ 08544, USA.6Correspondence should be addressed to A.M.S. ([email protected]).
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728 NATURE CELL BIOLOGY VOLUME 5 | NUMBER 8 | AUGUST 2003
InsP3), which when photolysed, increases local calcium levels17 and so
induces cortical granule exocytosis. Eggs were mounted in TR–dex and
imaged. Almost immediately after caged-InsP3 photolysis, exocytosing
cortical granules filled with TR–dex (Fig. 1d; also see Supplementary
Information, Movie 1). Within 16.3 ± 0.2 s of filling, actin encircled
the exocytosing cortical granules (mean ± s.e.m., n = 60 exocytosing
cortical granules from three experiments). The actin rings grew more
robust and then constricted until the TR–dex-filled compartments
disappeared and only plugs of actin remained.
Although single optical plane, time-lapse analysis demonstrated that
F-actin coats are dynamic and transient, it did not allow us to ade-
quately examine their function. Hence, we collected image stacks of
cortical actin during cortical granule exocytosis/large endosome forma-
tion and then prepared these data as time-lapse volumetric renderings
(4D). In 4D renderings, looking on to the external surface of the plasma
membrane (apical; Fig. 2a, b; also see Supplementary Information,
Movies 2 and 3), exocytosing cortical granules incorporated TR–dex,
around which actin accumulated in circumferential ridges. As the
ridges heightened and constricted, sheets of actin were also observed
sweeping over the TR–dex-filled compartments. At higher magnifica-
tion (Fig. 2b, note 40-s timepoint; also see Supplementary Information,
Movie 3), it was apparent that these actin structures closed over the
TR–dex-filled compartments to form large endosomes.
For an alternative perspective, 4D volumes were rotated 180° from
apical, (basal; Fig. 2c; also see Supplementary Information, Movie 4),
thus providing a view from the cell interior towards the inner surface
of the plasma membrane. In this view, exocytosing cortical granules
were enveloped by actin sheets that extended progressively along their
surfaces, meeting basally to form complete coats. Assembled actin
coats compressed apically to squeeze the compartments until TR–dex
was no longer detectable and the spent coat remained as only an actin
ball at the plasma membrane. Although some TR–dex was most prob-
ably expelled extracellularly during coat compression, a portion was
also endocytosed and trafficked into a sub-cortical membrane com-
partment detectable in fixed eggs (data not shown).
Actin coat dynamics appeared rather similar from both the apical
and basal views, even though the coats encounter different tasks
depending on the perspective: In the apical view, fusion of the cortical
granule with the plasma membrane is followed by closure of actin over
the fusion pore. In the basal view, the entire granule surface becomes
encased in actin and is squeezed. The coat activities observed from
these distinct views are summarized in 4D cross-sections (Fig. 2d; also
see Supplementary Information, Movie 5), where actin coat constric-
tion within the plane of the plasma membrane was obvious, as well as
the apically directed compression throughout the entire coat.
Interestingly, coat assembly always started at the apical surface of the
exocytosing cortical granule (for example see Fig. 2c; also see
Supplementary Information, Movie 4), where components of the cor-
tical granule membrane and plasma membrane could mix most rap-
idly after fusion, and actin coats could simultaneously initiate their
apical constriction and basal encasement.
To further assess the role of F-actin in the recovery of exocytosing
cortical granule compartments, eggs injected with Alexa488–G-actin
and caged-InsP3 were treated with 5 µM latrunculin B and imaged as
above. Single optical plane, time-lapse analysis demonstrated that
latrunculin blocked coat assembly, but not cortical granule exocytosis
(Fig. 3a). When F-actin was disrupted, adjacent exocytosing cortical
granules seemed to fuse together, an event rarely observed in control
eggs (118 ± 11.4 fusions per 85 µm2 field for latrunculin versus 0.6 ± 0.3
for controls; mean ±s.e.m., n ≥ 3 eggs from three experiments;
P < 0.005). In 4D cross-section (Fig. 3b), some exocytosing cortical
granules rapidly collapsed into the plasma membrane, rather than
remaining as invaginated compartments. Whether fusion between adja-
cent exocytosing cortical granules represents a distinct phenomenon or
is simply a different manifestation of collapse into the plasma mem-
brane is currently unresolved.
Apical view, 4D renderings then demonstrated that latrunculin
treatment and the resulting failure to assemble actin coats resulted in
massive cortical disintegration after cortical granule exocytosis
(Fig. 3c), presumably because of the uncompensated insertion of
excess membrane into the plasma membrane. Thus, F-actin maintains
exocytosing cortical granules as discrete invaginated compartments
that are subsequently retrieved by dynamic actin coats. Although the
actin coats could themselves maintain the invaginated compartments,
the cortical F-actin network most probably also imposes physical
restraints that favour maintenance rather than collapse.
F-actin coats may assemble on the exocytosing cortical granule
compartments by recruiting pre-existing F-actin or by de novo poly-
merization. To discriminate between these possibilities18,19, eggs
were co-injected with Alexa488–G-actin and Alexa568–phalloidin.
As the association rate of phalloidin for F-actin is relatively slow20,
Alexa488–G-actin should selectively label newly polymerized
F-actin before phalloidin. Single optical plane, time-lapse imaging
revealed that Alexa488–G-actin incorporates into coats 2.3 ± 0.4 s
Figure 1 Large endosomes are surrounded by dynamic coats of F-actin.(a) Single-plane confocal images showing that large endosomes (F–dex,green) form as cortical granules (rhodamine–lectin, red) are exocytosed.Some large endosomes contain both F–dex and rhodamine–lectin(arrowheads). (b) Single-plane confocal images showing that F-actinrings (Alexa488–phalloidin, green) encircle large endosomes (TR–dex,
red). (c) A z-section showing F-actin coats (green) surrounding largeendosomes (red). (d) Single-plane, time-lapse confocal images showingexocytosing cortical granules (TR–dex, red) being rapidly encircled byactin rings that constrict (Alexa488–G-actin, green, arrowheads).Photolysis was performed at 0 s. Scale bars represent 5 µm in a, b andd, and 2.5 µm in c.
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NATURE CELL BIOLOGY VOLUME 5 | NUMBER 8 | AUGUST 2003 729
before Alexa568–phalloidin (mean ± s.e.m., n = 65 coats from three
experiments; Fig. 4a, b; P < 0.005). Thus, actin polymerization
drives coat assembly.
In Xenopus eggs6 and egg extracts6,21–23, actin polymerizes on vesi-
cles through the Cdc42–N-WASP–Arp2/3 pathway. We therefore
probed for active Cdc42 during compensatory endocytosis with the
GTPase-binding domain of WASP (wGBD), which binds only the
active (GTP-bound) form of Xenopus Cdc42 (ref. 24). Single optical
plane, time-lapse imaging revealed that enhanced green fluorescent
protein (eGFP)-tagged wGBD is recruited to exocytosing cortical
granule membranes 10.0 ± 0.4 s after TR–dex filling (Fig. 4c; mean ±s.e.m., n = 60 exocytosing cortical granules from three experiments). A
marker for endogenous N-WASP, Alexa488–N-WASP-truncate, was
similarly recruited to exocytosing cortical granules 11.1 ± 0.2 s after
TR–dex filling (Fig. 4d; mean ± s.e.m., n = 60 exocytosing cortical
granules from three experiments).
The recruitment of active Cdc42 and N-WASP to exocytosing corti-
cal granules precedes coat assembly (see above), as predicted if the
Cdc42–N-WASP–Arp2/3 pathway effects coat assembly25. To function-
ally implicate this pathway, we injected eggs with dominant-negative
Figure 2 F-actin coats close over and compress exocytosing corticalgranule compartments. (a) A low-magnification, apical view (as if lookingonto the external surface of the plasma membrane from outside of thecell), 4D image showing actin coats (Alexa488–G-actin, green) manifestedas circumferential ridges that form around and close over exocytosingcortical granules (TR–dex, red; arrowheads). (b) High-magnification,apical view, 4D images showing that the actin ridge rises then constrictsto close over the cortical granule compartment (arrowhead). (c) High-magnification, basal view (rotated 180° from apical; as if looking onto the
internal surface of the plasma membrane from inside of the cell), 4Dimages of same exocytosing cortical granule, showing that the actin coatencases the compartment and compresses apically. (d) High-magnification, 4D images of a coat in cross-section, showing the coatdynamics seen in both the apical and basal views and indicatingconstriction in the plane of the plasma membrane, as well as apicallydirected compression throughout. Photolysis was performed at 0 s. Scalebar represents 5 µm in a, and 2.5 µm in b and c. Scale in d is identical tothe scale in b and c.
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730 NATURE CELL BIOLOGY VOLUME 5 | NUMBER 8 | AUGUST 2003
Cdc42 (Cdc42T17N)26. As viewed by single optical plane, time-lapse
microscopy, Cdc42T17N blocked coat assembly, but not cortical granule
exocytosis (Fig. 4e). The Cdc42T17N phenotype mimicked that induced
by latrunculin, resulting in fusions between adjacent exocytosing cortical
granules (45 ± 8.8 fusions per 85 µm2 field for Cdc42T17N versus 0.6 ± 0.3
for controls; mean ± s.e.m., n ≥ 3 eggs from three experiments;
P < 0.005). Thus, a Cdc42-dependent pathway drives coat assembly.
For propagation of the Cdc42–N-WASP–Arp2/3 pathway, N-WASP
requires input from both active Cdc42 and phosphatidylinositol-4,5-
bisphosphate (PtdInsP2)25. In the egg, PtdInsP2 is restricted to the
plasma membrane (A.M.S., unpublished observations), but may dif-
fuse laterally into cortical granule membranes immediately after exo-
cytosis to trigger actin coat assembly. Such ‘compartment mixing’
could represent a general mechanism to target local actin polymeriza-
tion on membranes. In this case, targeted actin polymerization on the
cortical granule membrane is associated with normal compensatory
endocytosis, as the actin coat seems to close over the fusion pore and
clearly compresses the exocytosing cortical granule compartment, per-
haps as a first step in endosomal processing. Additional insight into the
role of actin in compensatory endocytosis will certainly be gained by
simultaneously visualizing actin, the plasma membrane and cortical
granule/large endosome membranes throughout the process.
Unfortunately, we have thus far found actin coat assembly to be
severely inhibited by conventional lipid markers (data not shown).
For actin to achieve its compensatory endocytic roles, we suggest
that actin coat polymerization must be coupled to the membranes of
fusion pores and exocytosing cortical granule compartments so as to
exert force on the membranes, as previously described in cell migra-
tion, phagocytosis, and pathogen and vesicle motility1. The exerted
force is especially remarkable during coat compression, when the vol-
ume of TR–dex-filled cortical granule compartments is reduced by
0.5–1.2 µm3 s (n = 7 compartments from three eggs), and may provide
the first in vivo confirmation of the recent in vitro observations that
actin polymerization directly squeezes plastic beads27 and synthetic
lipid vesicles28,29. However, we cannot discount the possibility that
coat polymerization may also indirectly contribute to force production
by providing substrate for myosin activity30,31.
METHODSEgg procurement and injection. Oocytes were harvested as previously
described32 and cultured in OR2 (82.5 mM sodium chloride, 2.5 mM potas-
sium chloride, 1 mM calcium chloride, 1 mM magnesium chloride, 1 mM
Na2HPO4 and 5 mM Hepes at pH 7.4). If required, injections of 40 nl per
oocyte were delivered using a PLI-100 picoinjector (Medical Systems,
Greenvale, NY). To obtain eggs, meiotic maturation was induced by incubating
oocytes in OR2 with 5 µg ml−1 progesterone for 10–14 h.
Egg fixation and staining. Eggs were pricked with a fine glass needle in OR2
supplemented with 1 mM 3,000 Mr, lysine-fixable TR–dex or F–dex (Molecular
Probes, Eugene, OR). After 2 min, cells were washed vigorously and then fixed
for 4 h in 3.7% paraformaldehyde, 0.1% glutaraldehyde, 10 mM EGTA, 100mM
potassium chloride, 3 mM magnesium chlrode, 10 mM Hepes at pH 7.6 and
150 mM sucrose. Fix also included 0.4 units ml−1 Alexa488–phalloidin
(Molecular Probes) or 0.5% Triton X-100 for F-actin or cortical granule stain-
ing, respectively. Eggs were bisected before staining. F-actin was labelled with
1U ml−1 Alexa488–phalloidin. The heavily glycosylated cortical granule con-
tents were labelled with 10 µg ml−1 rhodamine–Dolichos biflorus Agglutinin
(Vector Labs, Burlingame, CA).
Probe preparation. Human WASP GBD (residues 219–311; provided by H.
Higgs, Dartmouth Medical School) was cloned carboxy-terminal to eGFP in the
custom vector pCS2+-eGFP, and capped eGFP-wGBD mRNA was synthesized
from this construct in vitro (mMessage mMachine transcription kit; Ambion,
Austin, TX).
Truncated rat N-WASP (residues 151–501) was cloned carboxy-terminal to a
His6-tag followed immediately by a Tobacco Etch Virus (TEV) protease cleavage
site in the expression vector pBH4. Protein expressed in Escherichia coli strain
BL21 was batch-purified using Nickel–NTA agarose (Qiagen, Valencia, CA) and
eluted with 250 mM imidazole. The His6-tag was removed by TEV protease
cleavage and the N-WASP protein then conjugated to Alexa488. This probe
mimics full-length N-WASP in that it rescues comet formation in Xenopus egg
extracts immunodepleted for endogenous N-WASP (data not shown).
Cell preparation for live imaging. Oocytes were injected with NPE caged-InsP3
(Molecular Probes) to attain a final intracellular concentration of 10 µM.
Protein probes and inhibitor were simultaneously injected with caged InsP3 to
attain final intracellular concentrations as follows: 96 µg ml−1 Alexa488–G-
actin (Molecular Probes), 6.7U ml−1 Alexa568–phalloidin (Molecular Probes),
2 µM Alexa488–N-WASP truncate and 3.2 µM human Cdc42T17N–glutathione
Figure 3 Retrieval of cortical granule membranes is F-actin-dependent.(a) Single-plane, time-lapse confocal images showing that latrunculininhibits actin (Alexa488–G-actin, green) coat assembly and inducesfusion between adjacent exocytosing cortical granules (TR–dex, red;arrowheads). (b) High-magnification, 4D images of an exocytosingcortical granule in cross-section, showing that latrunculin treatment
induces collapse of exocytosing cortical granules into the plasmamembrane. (c) Apical view, 4D images, showing complete disintegrationof the cortex in latrunculin-treated eggs after cortical granule exocytosis.Exocytosing cortical granules fuse with adjacent compartments(arrowheads). Photolysis was performed at 0 s. Scale bar represents10 µm in a, and 5 µm in b and c.
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NATURE CELL BIOLOGY VOLUME 5 | NUMBER 8 | AUGUST 2003 731
S-transferase (GST; Cytoskeleton, Denver, CO). Capped eGFP-wGBD mRNA
was injected at 6 ng per cell after caged InsP3 injection and expression pro-
ceeded concomitant with meiotic maturation. For latrunculin analysis, eggs
were pre-treated with 5 µM latrunculin B for 30 min then imaged in the pres-
ence of 5 µM latrunculin B.
Microscopy and image analysis. Imaging was performed with a Zeiss Axiovert
100 M microscope (Carl Zeiss, Thornwood, NY) with Bio-Rad 1024 × 1024
Lasersharp Confocal software (Bio-Rad, Hercules, CA) using a numerical aper-
ture 1.4, 63× objective lens. Eggs were mounted in OR2 with 100 µg ml−1 wheat
germ agglutinin (Sigma, St Louis, MO) to suppress cortical flow32. When
appropriate, mounting media also contained 100 µM 3,000 Mr neutral TR–dex
(Molecular Probes). After imaging commenced, caged InsP3 was photolysed by
focusing UV light through the objective and on to the egg cortex for 3–5 s. UV
light was derived from an HBO 100W AttoArc power supply (Atto Bioscience,
Rockville, MD) set at 15% intensity. The time-lapse, single optical plane data
was collected at 1.5 s intervals and the 4D data collected at 5 s intervals. The z-
step for 4D data collection ranged from 0.3–0.5 µm. For quantification of fluo-
rescence intensities, the NIH Object-Image v2.06 software was used. Z-series
and time-lapse, single optical plane movies and 4D renderings were generated
with Volocity v10 software (Improvision, Lexington, MA). All other image pro-
cessing was performed with Adobe Photoshop 3.0.
Note: Supplementary Information is available on the Nature Cell Biology website.
ACKNOWLEDGEMENTS
We thank H. Higgs for providing the original WASP GBD clone and P. Krieg for the
backbone Xenopus expression plasmid pCS2+. This work was supported by grants
from the National Institutes of Health to both W.B. and J.T.
COMPETING FINANCIAL INTERESTS
The authors declare that they have no competing financial interests.
Received 30 April 2003; Accepted 27 June 2003;Published online: 20 July 2003; DOI: 10.1038/ncb1025.
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Figure 4 Actin coats assemble by de novo polymerization in associationwith active Cdc42 and N-WASP. (a) Single-plane, time-lapse confocalimages showing G-actin (Alexa488–G-actin, green) incorporates into coatsbefore phalloidin (Alexa568–phalloidin, red). (b) Incorporation of G-actin(G-act) or phalloidin (Phall), measured as signal intensity. Results arerepresentative of three experiments. Inset demonstrates incorporationduring earliest coat assembly. 0 s is just before coat assembly in a and b.(c) Single-plane, time-lapse confocal images showing active Cdc42
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supplementary information
1
Movie 1. F-actin coats are highly dynamic. Single-plane, time-lapse confocal imag-ing shows that prior to CG exocytosis, cortical actin (Alexa488-G-actin, green)appears as a honeycomb, the CGs as black silhouettes. The black flash indicatescaged-IP3 photolysis to stimulate CG exocytosis. Actin coats assemble around exo-cytosing CGs (TR-dex, red) and constrict. Images collected ~2 µm in from the PM.(1.5 s intervals over 01:36).
Movie 2. Actin coats close over exocytosing CG compartments. Low-magnifica-tion, apical view, 4D imaging shows that the apical edges of the actin coats(Alexa488-G-actin, green) rise in ridges around the exocytosing CGs (TR-dex, red).The circumferential ridges constrict and actin sheets close over the compartmentinteriors. The black flash indicates caged-IP3 photolysis. (5 s intervals over 01:40)
Movie 3. Actin coats close over exocytosing CG compartments. High-magnification,apical view, 4D imaging shows that the circumferential ridge of the actin coat(Alexa488-G-actin, green) rises around the exocytosing CG (TR-dex, red) and con-stricts to close over the compartment. The black flash indicates caged-IP3 photoly-sis. (5 s intervals over 01:40)
Movie 4. Actin coats compress exocytosing CG compartments. High-magnification,basal view, 4D imaging shows that actin (Alexa488-G-actin, green) extends basallyalong the surface of the exocytosing CG (TR-dex, red) to form the coat that com-presses apically. The black flash indicates caged-IP3 photolysis. (5 s intervals over01:40)
Movie 5. Actin coats close over and compress exocytosing CG compartments.High-magnification 4D imaging of an exocytosing CG (TR-dex, red) in cross-sectionshows that the actin coat (Alexa488-G-actin, green) constricts in the plane of thePM and apically compresses throughout its entirety to squeeze the CG compart-ment. The black flash indicates caged-IP3 photolysis. (5 s intervals over 01:40)
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