Kinesin- and Myosin-driven Steps of Vesicle Recruitment for Ca2+-regulated Exocytosis

doi:10.1083/jcb.138.5.999

This Article

	Abstract
	Full Text (PDF, 651K)
	PPT slides of all figures
	Alert me when this article is cited
	Citation Map

Services

	Email this article
	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new content in the JCB
	Download to citation manager

Citing Articles

	Citing Articles via HighWire
	Citing Articles via CrossRef
	Citing Articles via Google Scholar

Google Scholar

	Articles by Bi, G.-Q.
	Articles by Steinhardt, R. A.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Bi, G.-Q.
	Articles by Steinhardt, R. A.


Social Bookmarking

	What's this?

© The Rockefeller University Press, 0021-9525/1997//999 $5.00
The Journal of Cell Biology, Volume 138, Number 5, , 1997 999-1008

Article

Kinesin- and Myosin-driven Steps of Vesicle Recruitment for Ca²⁺-regulated Exocytosis

Guo-Qiang Bi^*, Robert L. Morris, Guochun Liao^*, Janet M. Alderton^*, Jonathan M. Scholey, and Richard A. Steinhardt^*

^* Department of Molecular and Cell Biology, University of California, Berkeley, California 94720-3200; and Section of Molecular and Cellular Biology, University of California, Davis, California 95616

Kinesin and myosin have been proposed to transport intracellularorganelles and vesicles to the cell periphery in several cellsystems. However, there has been little direct observationof the role of these motor proteins in the delivery of vesiclesduring regulated exocytosis in intact cells. Using a confocalmicroscope, we triggered local bursts of Ca²⁺-regulated exocytosisby wounding the cell membrane and visualized the resultingindividual exocytotic events in real time. Different temporalphases of the exocytosis burst were distinguished by theirsensitivities to reagents targeting different motor proteins.The function blocking antikinesin antibody SUK4 as well as thestalk-tail fragment of kinesin heavy chain specifically inhibiteda slow phase, while butanedione monoxime, a myosin ATPase inhibitor,inhibited both the slow and fast phases. The blockage of Ca²⁺/calmodulin-dependentprotein kinase II with autoinhibitory peptide also inhibitedthe slow and fast phases, consistent with disruption of a myosin-actin–dependent step of vesicle recruitment. Membrane resealing afterwounding was also inhibited by these reagents. Our direct observationsprovide evidence that in intact living cells, kinesin and myosinmotors may mediate two sequential transport steps that recruitvesicles to the release sites of Ca²⁺-regulated exocytosis,although the identity of the responsible myosin isoform is not yet known. They also indicate the existence of three semistablevesicular pools along this regulated membrane trafficking pathway.In addition, our results provide in vivo evidence for the cargo-bindingfunction of the kinesin heavy chain tail domain.

Abbreviations used in this paper: BDM, 2,3-butanedione monoxime; CaM kinase II, Ca²⁺/calmodulin-dependent protein kinase II; KHC, kinesin heavy chain; KRP, kinesin-related protein.

TO dock and fuse with the plasma membrane in response to localizedcalcium influx, vesicles for Ca²⁺-regulated exocytosis mustfirst be recruited to the cell surface from intracellular pools.Although much has been learned about the molecular mechanismsof the docking and fusion reactions of regulated exocytosis(Sudhof et al., 1993; Bennett and Scheller, 1994; De Camilli, 1995),the few studies of the vesicle recruitment process have focusedon membrane recycled from endocytosis (Betz and Bewick, 1992;Ryan et al., 1993; Betz and Wu, 1995), and as yet there hasbeen little direct in vivo observation of the roles of motorproteins in recruiting vesicles to exocytotic sites (Scholey, 1996;Vallee and Sheetz, 1996).

The motor protein kinesin is a good candidate for part of thetransport machinery in the pathway of regulated exocytosis.Kinesin has been demonstrated to move along microtubule trackstowards the plus end by hydrolyzing ATP in several in vitroassays (Goldstein, 1993; Bloom and Endow, 1995). It has alsobeen shown to associate with vesicle and organelle membranesin different cell types (Bloom and Endow, 1995). Several antikinesinantibodies were able to inhibit fast axonal transport (Vale et al., 1985b;Brady et al., 1990), the centrifugal migration of pigment granules(Rodionov et al., 1991), and the formation of tubular lysosomalstructure (Hollenbeck and Swanson, 1990). Mutations in Drosophilakinesin impaired the transport of membrane proteins to theirappropriate cellular locations (Saxton et al., 1991; Gho et al., 1992).Based on these findings, it has been widely predicted thatthis motor protein will be shown to play an essential rolein transporting vesicles to sites of Ca²⁺-regulated exocytosis.

A kinesin holoenzyme is composed of two identical heavy chainsand two light chains. The kinesin heavy chain (KHC)¹ consistsof an amino-terminal globular head domain that is linked tothe carboxyl-terminal tail domain through a stalk region thatdimerizes two KHCs to form the kinesin motor (Fig. 1) (Yang et al., 1989).The KHC head domain is highly conserved among different kinesin-relatedproteins (KRPs) and has been shown to be responsible for ATPhydrolysis and force generation (Yang et al., 1990). The taildomain is more variable and is thought to be important forkinesin cargo binding (Hirokawa et al., 1989; Bloom and Endow, 1995).This was further supported by in vitro observations that thebacterially expressed stalk-tail fragment, but not the stalkfragment of sea urchin KHC, was able to bind microsomal membranes isolated from sea urchin eggs in a saturable manner and competewith native kinesin for membrane binding (Skoufias et al., 1994).However, an in vivo demonstration has been difficult becausethe in vivo function of sea urchin kinesin was not known.

View larger version (27K):
[in this window]
[in a new window]
[Download PPT slide]

Figure 1 Primary sequence of KHC. Arrows indicate approximate sites for antibody recognition. Numbers refer to KHC amino acid sequence number starting from the amino terminus. The "Stalk-Tail" and "Stalk" are the two KHC fragments used in this experiment.

The actin-based motor myosin is another candidate that maydrive vesicle recruitment in regulated exocytotic pathways(Fath and Burgess, 1994; Hasson and Mooseker, 1995; Langford, 1995).Evidence that some of the myosin isoforms may power membranetransport came from several systems including yeast (Johnston et al., 1991;Drubin and Nelson, 1996), algae (Adams and Pollard, 1986; Grolig et al., 1988),squid axoplasm (Kuznetsov et al., 1992), and polarized epithelialcells (Fath et al., 1994). There was also evidence for thepresence of both microtubule- and actin-based motors on thesame membranous organelles (Fath et al., 1994). However, withone exception, there has been no in vivo demonstration forthe role of myosin in regulated exocytosis, and the exact interrelationshipbetween the microtubule-based and actin-based systems has yetto be elucidated (Langford, 1995). The one exception is a study in which a smooth muscle antimyosin II antibody microinjectedinto presynaptic neurons inhibited synaptic transmission (Mochida et al., 1994).Transmission was also inhibited in a dose-dependent mannerby two inhibitors of myosin light chain kinase. The identityof the neuronal myosin subtype affected in this study remainsan open question since other studies have failed to find myosinII presynaptically (Miller et al., 1992).

Ca²⁺/calmodulin-dependent protein kinase II (CaM kinase II)has been implicated in the regulation of exocytosis at an actinbinding step (Ceccaldi et al., 1995). CaM kinase II injectedpresynaptically in squid giant synapse was found to facilitatetransmitter release (Llinas et al., 1991). Additionally, extracellularapplication of synthetic peptide inhibitors of CaM kinase IIpreferentially suppressed the phosphorylation of synapsin Iat the CaM kinase II–specific site and decreased excitatorysynaptic responses elicited in the CA1 region of hippocampalslices (Waxham et al., 1993). Recently, Ceccaldi showed thatthe presence of dephosphorylated synapsin I is necessary forsynaptic vesicles to bind actin, and the effect is abolishedupon its phosphorylation by CaM kinase II (Ceccaldi et al., 1995). Therefore, CaM kinase II is postulated to play an essential role in recruitment of vesicles since its action would be requiredto free vesicles from the actin-bound pool.

Using a confocal microscope, we were able to visualize andquantify individual exocytotic events in real time by triggeringlocal bursts of regulated exocytosis in early sea urchin embryoniccells by wounding the cell membrane with a laser beam and inducingCa²⁺ influx through the wound (Bi et al., 1995; Terasaki, 1995).This system allowed us to directly investigate the in vivo rolesof protein motors in the recruitment of vesicles to exocytoticsites and address several related issues. By analyzing thetemporal patterns of exocytosis when the functions of kinesin, myosin, and CaM kinase were inhibited, we concluded that exocytoticvesicles were recruited by a two-step transport mechanism mediatedby kinesin and myosin sequentially. Our results also revealeddistinct intermediate vesicle pools along the transport pathway.In addition, our results demonstrated the in vivo cargo bindingfunction of the KHC tail domain.

Materials and Methods

Top
Abstract
Materials and Methods
Results
Discussion
References

Materials
For isolation and purification of bacterially expressed KHCfragments, P11 cellulose phosphate cation exchanger was obtainedfrom Whatman International Ltd. (Maidstone, Kent, UK). DEAEBio-Gel A (100–200 mesh) anion exchange resin was obtainedfrom Bio-Rad Laboratories (Hercules, CA). All other reagentswere from Sigma Chemical Co. (St. Louis, MO) unless otherwisespecified. SUK4 and SUK2 monoclonal antibody stocks were purifiedIgG isolated on protein A columns at 4.5 and 3 mg/ml in PBS.They were mixed with Fura-2 salt and aspartate buffer (containing100 mM potassium aspartate, 20 mM Hepes, pH 7.2) to make theinjection solutions that contained 2.7 mg/ml of either antibody.

2, 3-butanedione monoxime (BDM, from Sigma Chemical Co.) wasdissolved into natural sea water to make a fresh stock of 0.5M on the same day of the experiment. It was then added intosea water to reach required final concentrations. Washes wereperformed by replacing the extracellular BDM solution with freshnatural sea water at least three times in 5 min. Both the powderand solutions of BDM were kept in dark to avoid light inactivation.

CaM kinase peptides CaMK(273-302) and CaMK(284-302) were synthesizedusing an automated synthesizer (Applied Biosystems, Inc., Foster City, CA), purified by HPLC, and assessed by sequencing. CaMK(273-302)and CamK(284-302) peptide stocks were 2.5 and 5 mM in aspartate buffer (containing 100 mM potassium aspartate, 20 mM Hepes,pH 7.2). They were mixed with Fura-2 potassium salt to makethe injection solutions that contained 0.25 and 0.5 mM of eitherpeptide.

Isolation and Purification of Bacterially Expressed KHC Fragments
Previously, two Escherichia coli bacterial strains were transformedwith T7 vectors containing partial inserts of sea urchin conventionalkinesin heavy chain: one 1.4-kb insert encoded the tail anda portion of the stalk (amino acids 579–1031) and one0.8-kb insert encoded a portion of the stalk only (amino acids579–858), as described (Skoufias et al., 1994). Isolationof the KHC fragments was performed as previously described (Skoufias et al., 1994) with the following modifications. Frozentransformed cell stocks were grown up in Luria Broth containing50 µg/ml each of ampicillin and chloramphenicol. Bacteriawere induced, harvested, washed as before, and then lysed bysonication followed by three rounds of freezing and thawingin lysis buffer as described (Skoufias et al., 1994). Stalkand stalk-tail fragments were isolated by ion exchange chromatographyin 20 mM Tris, pH 8, 6 M urea, 1 mM DTT and eluted as before,except DEAE Bio-Gel A was substituted for DE52 DEAE. Columnelutates were dialyzed sequentially with 1 liter of 3 and 1.5M urea in 20 mM Tris, pH 8, 1 mM EGTA, 1 mM EDTA, 150 mM NaCl,1 mM MgSO₄, 2 mM DTT, plus protease inhibitors (0.1 mM phenylmethylsulfonylfluoride, 1 µg/ml leupeptin, 1 µg/ml pepstatin,2 µg/ml aprotinin, 20 µg/ml benzamidine, and 1mg/ml TAME). Final purification was performed by sedimentationthrough a 1–15% sucrose density gradient in the same buffer with 1.5 M urea. Peak gradient samples were pooled anddialyzed sequentially against 1 liter each of 1.5, 0.75, and0 M urea in aspartate buffer that contained 100 mM L-asparticacid, 20 mM Hepes, pH 7.2, plus protease inhibitors. Finalconcentrations of KHC stalk fragment was 2.7 mg/ml = 80 µM;stalk-tail fragment was 0.75 mg/ml = 14.5 µM.

Cells, Microinjection, and Test of Resealing
Lytechinus pictus sea urchins (from Marinus Inc., Long Beach,CA) were handled as previously described (Bi et al., 1995).Microinjections and resealing tests were performed as described(Steinhardt et al., 1994; Bi et al., 1995). Briefly, eggs andsperm were obtained by injection of 0.55 M KCl into the seaurchin interperitoneal cavity. Sperm was collected dry and stored at 4°C for up to 1 wk. Eggs were collected in naturalsea water, dejellied by passing through 80-µm Nitex mesh(Tetko Inc., Depew, NY), washed three times in natural seawater, and were allowed to settle onto glass coverslips coatedwith 10 mg/ml poly-DL-lysine (Sigma Chemical Co.). Kinesinreagents or buffer were pressure-injected into unfertilized or newly fertilized sea urchin eggs. All injection solutionscontained 2.5 mM Fura-2 salt (Molecular Probes, Eugene, OR)as a fluorescent marker for injected cells. Injection volumewas about 5% of cell volume. For tests of resealing, injectedcells were wounded in natural sea water with a glass micropipettethat penetrated the plasma membrane and was withdrawn immediatelyafter wounding. The size of this wounding is similar to that produced by a typical microinjection. Resealing was monitoredby photometric measurement of Fura-2 emission fluorescence at510 nm after alternate excitation with 357- and 385-nm ultravioletlight (Steinhardt et al., 1994) and subsequently confirmedvisually.

Confocal Microscopy
Confocal microscopy was performed using a confocal microscope(model MRC-600; Bio-Rad Labs) equipped with a 40x Neofluorobjective (NA = 1.3, oil immersion; Carl Zeiss, Inc., Thornwood,NY), a 15 mW argon ion laser, and a UV epifluorescence system(Carl Zeiss, Inc.). For microscopy, eggs settled on poly-lysine–coatedcoverslips were injected within 5 min after fertilization andwere allowed to develop to two-cell stage ( $~$ 2 h at 16.5°C)before being mounted into a handmade chamber that held $~$ 150 µl of natural sea water containing 100 µM rhodaminedextran (3,000 molecular weight; Molecular Probes). Confocalexperiments were performed at 20°C. Two- to four-cell stageembryos with relatively flat surfaces adhering to the coverslipwere selected for experiments. Injected embryos could be easilyidentified by their Fura-2 fluorescence with UV epifluorescencefilters (360 nm excitation and >400 nm emission).

During each imaging series, the cell was first wounded by "parking"the confocal beam at maximum power (neutral density filtersetting at ND 0) focused at a selected position on the cellsurface for 10–25 s to trigger local exocytosis. Neutraldensity filter setting ND 3 was then used for subsequent imagingto attenuate the beam power and reduce cell damage. The confocalscanning plane was focused just inside the cell surface to visualize the formation of bright fluorescent "disks." These disks havebeen shown to be exocytotic vesicle pockets filled with extracellularfluorescent dextrans, based on their rapid formation and theirsensitivity to proteolytic neurotoxins that specifically targetthe exocytosis machinery (Bi et al., 1995). Cells were scannedcontinuously (1 frame/s), and image frames were collected andstored when new exocytotic events occurred or after a periodof time ( $~$ 20 s) without new events. A semiautomatic macro programwas written to perform these operations. Images were processedby NIH Image (Bethesda, MD) and Adobe Photoshop (San Jose,CA). Quantification was performed manually during playbackof recorded image series by direct counting the number of newexocytotic events in each frame.

Results

Top
Abstract
Materials and Methods
Results
Discussion
References

A Slow Phase of Ca²⁺-triggered Exocytosis Requires a Functional Kinesin Motor
We used the laser beam of a confocal microscope to wound themembranes of embryonic sea urchin cells so that Ca²⁺ influxthrough the wound would trigger a burst of local exocytosis(Bi et al., 1995). By setting the confocal scanning plane rightunderneath the cell surface, individual exocytotic events couldbe visualized as bright disks in the confocal images (Bi et al., 1995;Terasaki, 1995). In Fig. 2, each newly emerged bright diskindicated by an arrow represents a single newly exocytosed vesicle.Under normal conditions, the exocytotic burst usually lastsfor about a minute and ceases after the wound reseals, Ca²⁺ influx stops, and intracellular free Ca²⁺ levels return to normal (Fig. 2 A). To investigate the possible transport roleof the motor protein kinesin (Scholey et al., 1985; Vale et al., 1985a)in this exocytotic pathway, we injected cells with SUK4, amonoclonal antibody targeting the motor domain of KHC (Fig.1) (Wright et al., 1991). This antibody had been shown to blockthe kinesin-mediated microtubule motility in vitro (Ingold et al., 1988)and to inhibit exocytosis-dependent membrane resealing (Steinhardt et al., 1994).Surprisingly, the early exocytotic events were virtually unaffectedby the antibody injection (5 to 10 s in Fig. 2 B). However,the later exocytotic events were inhibited (Fig. 2 B, 26 sand later). As a control, some cells were injected with anotherantikinesin antibody, SUK2, that targets the kinesin stalkdomain (Fig. 1) (Wright et al., 1991) and does not interferewith the motor function (Ingold et al., 1988) or membrane resealing(Steinhardt et al., 1994) at similar intracellular concentrations.These cells exhibited a normal pattern of exocytosis in responseto Ca²⁺ influx through the laser wound (Fig. 2 C).

View larger version (116K):
[in this window]
[in a new window]
[Download PPT slide]

Figure 2 Effect of reagents targeted against motor proteins on Ca²⁺-regulated exocytosis induced by laser wounding. The pseudocolor pictures are confocal fluorescence images of extracellular rhodamine dextran showing the exocytotic pockets into confocal focal plane just under the plasma membrane (Bi et al., 1995). Exocytotic events are visualized as the appearance of bright disks (0.5–1 µm diameter) against the dark intracellular background indicated by arrows. Blue arrows indicate early events, while green arrows indicate later events. (A) The exocytotic pattern of a sea urchin embryonic cell in natural sea water. In other series, the embryos were previously injected with (B) SUK4, (C) SUK2 antikinesin, (D) stalk-tail fragment, and (E) stalk fragment of KHC and were kept in natural sea water. In series F, the embryo was treated with 50 mM BDM. In series G, the embryo was injected with CaMK(273-302), an autoinhibitory peptide from the regulatory domain of CaM kinase type II. The large central stain in G is dye entering the unhealed wound. The first frame in each series was collected before wounding. Time 0 is defined as the moment immediately after wounding. The unit for time labels is seconds. Arrows indicate new exocytotic events that occurred since the previous frame. Bar, 5 µm.

Fig. 3 A shows examples of the quantified time course of exocytosisafter individual membrane wounds. Fig. 3 B averages the resultsfrom 17 or more experiments and reveals two distinct phasesin the temporal pattern of this regulated exocytosis: a slowphase that is inhibited by SUK4 and a fast one not affectedby this function-blocking antibody. Although we can not excludethe possibility that kinesin may play some role in the organizationof intracellular structure, which may in turn affect the temporalpattern of exocytosis, it appears more likely that this slow phase simply represents a kinesin-mediated step in the regulatedexocytosis pathway, the step of vesicle recruitment on microtubulesdirected toward the release site of membrane wounding and Ca²⁺influx. Furthermore, since conventional kinesin is currentlythe only known KRP that is recognized by SUK4, we suspect thatthis most abundant KRP is responsible for the transport ofvesicles in this ubiquitous regulated exocytosis pathway.

View larger version (39K):
[in this window]
[in a new window]
[Download PPT slide]

Figure 3 Specific inhibition of a slow phase of Ca²⁺-regulated exocytosis by function-blocking antikinesin antibody SUK4. A quantifies cumulative number of exocytotic events in individual cells from typical experiments. The control cell (Ctrl) was not injected with any reagent. B summarizes the average number of exocytotic events that occurred within different time ranges from n experiments. n = 37 for Ctrl, 17 for SUK4, and 23 for SUK2. A biphasic temporal pattern of exocytosis is seen by comparing the SUK4 injection data with the Ctrl or SUK2 injection data. The slow phase (after 16 s), but not the fast phase (0–15 s) of exocytosis is inhibited by SUK4 antikinesin. Error bars are standard errors.

Kinesin Mediates Vesicle Transport for Ca²⁺-regulated Exocytosis through Its Cargo-binding Tail Domain
To confirm that the effect of SUK4 was due to inhibition ofkinesin-mediated vesicle transport and to further identify themolecular identity of the responsible KRP isoform, we generatedthe stalk-tail and stalk only fragments of KHC expressed inbacteria (Fig. 1). Here the term "kinesin" refers to the conventionalkinesin, as opposed to other KRPs. In an in vitro assay, thisstalk-tail fragment, but not the stalk fragment, effectivelycompeted with kinesin for vesicle binding (Skoufias et al., 1994).If the KHC tail domain is responsible for vesicular cargo bindingin vivo, as has been postulated, introduction of the stalk-tailfragment, but not the stalk alone into the cell, should arrestkinesin-mediated transport by competition for the binding ofcargo receptors. If kinesin, but not other KRPs, does mediatevesicle recruitment for regulated exocytosis, this arrest oftransport should alter the temporal pattern of exocytosis,as did the SUK4 antibody.

We injected the cells with the stalk-tail fragment at $~$ 650 nMintracellular concentration. This is 32-fold greater than theK_d of stalk-tail binding to microsomes (Skoufias et al., 1994).These cells indeed showed a block in the slow phase of exocytosissimilar to that seen in cells injected with SUK4 (Figs. 2 Dand 4). In contrast, stalk fragment injection (intracellularconcentration $~$ 2.4 µM) had no effect on exocytosis (Fig.2 E and 4). Because the tail domain is less conserved amongdifferent KRPs, the stalk-tail competition for putative vesiclereceptors should be very specific. It is therefore highly likelythat conventional kinesin is the protein motor that drives vesiclerecruitment in Ca²⁺-regulated exocytosis. In addition, this result also provides direct in vivo evidence for the postulatedvesicular cargo binding function of the kinesin tail domain.

View larger version (38K):
[in this window]
[in a new window]
[Download PPT slide]

Figure 4 Specific inhibition of the slow phase of Ca²⁺-regulated exocytosis by KHC stalk-tail fragment. (A) Typical examples of the cumulative number of exocytotic events in individual cells. (B) The average number of exocytotic events that occurred within different time ranges from n experiments. n = 37 for Ctrl, 27 for Stalk-tail, and 33 for Stalk.

A Myosin Motor May Mediate Vesicle Transport at a Step Downstream to Kinesin Transport
Members of the myosin family have also been implicated in membranousorganelle transport in several systems (Adams and Pollard, 1986;Grolig et al., 1988; Kuznetsov et al., 1992). Does it playany role in the regulated exocytotic pathway? If yes, what isthe relationship between the kinesin–microtubule andactomyosin transport systems? To address these questions, wetreated the cells with BDM, a known reversible inhibitor ofmyosin ATPase that has been shown to block myosin-dependentcell spreading in epithelial cells (Cramer and Mitchison, 1995)and retrograde F-actin flow in neuronal growth cones (Lin et al., 1996)but has not been found to affect kinesin ATPase activity (Cramer and Mitchison, 1995).BDM is at present the only potent general inhibitor of myosinfunction available. In the absence of knowledge of specificmyosin isoforms and in the absence of more specifically targetedreagents, BDM is as close as one can get now to implicating myosin in a functional assay. BDM is fully reversible in functionalstudies of myosin. Exocytosis was reversibly inhibited by 50mM BDM (Figs. 2 F and 5). In contrast to the inhibition bySUK4 and KHC stalk-tail, BDM inhibited exocytotic events fromboth the slow and the fast phase (Fig. 5). This is particularlyobvious when comparing the exocytosis under these conditionswithin the 6–15-s range (Fig. 3–5). The onset ofBDM effect on exocytosis pattern took about 10 min. After that,the exocytosis pattern was stable for at least 1 h, until BDMwas washed away. Exocytosis recovered to its normal patternwithin 15 min after BDM was washed away (Fig. 5).

View larger version (37K):
[in this window]
[in a new window]
[Download PPT slide]

Figure 5 Reversible inhibition of both the slow and the fast phases of exocytosis by BDM. The cells were in 50 mM BDM for 10–60 min. For "Wash" experiments, cells were in 50 mM BDM for at least 45 min and were then transferred to BDM-free sea water for at least 15 min before imaging. (A) Quantified examples of individual experiments under different conditions. (B) Average number of exocytotic events that occurred within different time ranges from n experiments. n = 37 for Ctrl, 17 for BDM, and 8 for Wash.

To make sure that the BDM effect was not due to any inhibitionof the vesicle fusion step of exocytosis, we tested exocytosisof previously docked cortical granules found at the plasmamembrane in unfertilized sea urchin eggs at the same BDM concentration.Exocytosis of these vesicles was not affected. (Nine out ofnine cells tested showed normal exocytosis in response to membranewounding; data not shown.) This is also consistent with thefact that in embryonic cells, BDM inhibited later events (>5s after wounding) to a much higher degree than the initial burst(Fig. 5). The initial burst of exocytosis is most likely frompreviously docked vesicles. Therefore, we believe that BDM affectedthe regulated exocytosis at a step upstream of the final fusionevent. Furthermore, this step, possibly a myosin-mediated transportstep, appears to be downstream of the kinesin transport step,because in addition to the slow phase of exocytosis, BDM alsoinhibited the fast phase of exocytosis that was not affectedby our blocks of kinesin function.

To obtain further evidence consistent with an actin-based stepin vesicle recruitment, we investigated the possible role ofCaM kinase II by injecting cells with CaMK(273-302), an autoinhibitorypeptide from the regulatory domain of CaM kinase. Although CaMkinase II is a multifunctional enzyme and could have multipletargets, we examined its specific effect on vesicle recruitmentto sites of Ca²⁺-regulated exocytosis. CaMK(273-302) had beenpreviously shown to inhibit a CaM kinase II–specific Ca²⁺/calmodulin-dependent phosphorylation in cell extracts ofLytechinus pictus (Baitinger et al., 1990) and to inhibit exocytosis-dependentmembrane resealing (Steinhardt et al., 1994). Figs. 3 G and6 A show typical examples of cumulative exocytotic events.Fig. 6 B averages the results from 18 or more experiments andreveals that both fast and slow vesicle exocytosis have beeninhibited by CaMK(273-302). CaMK(273-302) did not block exocytosis completely, which is consistent with its action on CaM kinaseII in vitro (Baitinger et al., 1990). To demonstrate that theinhibition was not on the fusion of vesicles, we tested theeffect of CaMK(273-302) on laser wound–triggered exocytosisof previously docked cortical granules found at the plasmamembrane in unfertilized sea urchin eggs. Exocytosis of thesevesicles was not affected (four of four cells tested). As acontrol, some cells were injected with the shorter peptide,CaMK(284-302), which does not inhibit Ca²⁺/calmodulin-dependentphosphorylation in vitro (Baitinger et al., 1990) or membraneresealing (Steinhardt et al., 1994). Those cells exocytosednormally in response to Ca²⁺ influx through the laser wound(Fig. 6). It appears that CaMK(273-302) and BDM have similareffects on the recruitment of vesicles, a result consistentwith a block of the late step of the vesicle transportationprocess from the actin matrix to the plasma membrane.

View larger version (35K):
[in this window]
[in a new window]
[Download PPT slide]

Figure 6 Inhibition of both the slow and the fast phases of exocytosis by CaMK(273-302), an autoinhibitory peptide from the regulatory domain of CaM kinase type II. Control peptide CaMK(284-302) did not inhibit exocytosis. (A) Typical examples of cumulative number of exocytotic events in individual cells. (B) The average number of exocytotic events that occurred within different time ranges from n experiments. n = 18 for Ctrl, 39 for CaMK(273-302), and 22 for CaMK(284-302).

Three Semistable Vesicle Pools in the Pathway of Regulated Exocytosis
One interesting feature in the above results is that blockingeither motor system could not completely block injury-inducedregulated exocytosis. When kinesin transport was blocked, onlythe slow phase of exocytosis was inhibited. The fast phasewas virtually intact (Figs. 3 and 4). With BDM inhibition ofputative myosin transport, a significant portion of the veryfast events still persisted (Fig. 5). If the vesicle recruitmentprocess is a simple chain of constitutive sequential steps andthe regulation is only at the final exocytosis step, a blockadeat any point in the chain should similarly inhibit the wholeprocess. However, the above experiments showed distinct temporalpatterns when different motors were blocked, indicating theexistence of semistable intermediate vesicle pools that maybe regulated separately in the membrane transport pathway.

Quantification of the temporal patterns of exocytosis underdifferent conditions (Figs. 3–5) allows us to mathematicallyseparate these vesicle pools. As shown in Figure 7 A, an "Immediate"pool of vesicles could be defined as those that can exocytosein the presence of BDM because they respond to Ca²⁺ influxmost rapidly (within a few seconds) and do not seem to dependon either myosin or kinesin transport mechanisms. By subtractingthe myosin- independent (BDM-insensitive) component from thekinesin-independent exocytosis (average of SUK4 and stalk-tail data), a "Fast" pool could be defined as vesicles whose exocytosisare myosin-dependent but kinesin independent. Exocytosis ofvesicles from this fast pool usually took place within 10 safter Ca²⁺ influx. Finally, a "Slow" pool could be isolatedby subtracting the kinesin-independent exocytosis data (summationof immediate and the fast pools) from the average of controlexperiments including the control, SUK2, and Stalk data fromFigs. 3–5. Apparently, vesicles in this slow pool requirenormal levels of kinesin and myosin transport for their finalexocytosis. These vesicles take a much longer time to exocytose(peaking at 30 s) than those in the first two pools, presumablybecause of the delay in long-distance transport by the kinesin–microtubulesystem, as will be discussed later.

Motor-driven Vesicle Recruitment Is Essential for Cell Membrane Resealing
Although the main objective of this study was to directly observemotor-driven vesicle recruitment steps in a regulated pathwayin vivo, we also investigated the role of these steps in cellmembrane resealing (Steinhardt et al., 1994; Bi et al., 1995;Miyake and McNeil, 1995). After injection into the cell, thestalk-tail fragment of KHC inhibited membrane resealing in seaurchin embryonic cells or activated eggs (Table I) when testedby mechanical wounding with a glass needle, as did the SUK4antibody (Steinhardt et al., 1994). Stalk injection had nosignificant effect on resealing (Table I). As expected, BDMtreatment also inhibited membrane resealing in activated eggs or embryonic cells but not in unfertilized eggs, which all have thousands of cortical vesicles already docked at their plasma membrane (Table II). We also found that resealing inactivated eggs and embryonic cells was inhibited by cytoskeleton-disruptingdrugs. (Nine out of nine cells tested failed to reseal after0.5 h in 25–30 µM nocodozole, which disrupts microtubules;10 out of 10 cells failed to reseal after 0.5 h in 10–20µM cytochalasin D or B, which both disrupt actin filaments.)This is consistent with the function of microtubules and actinfilaments as tracks for appropriate protein motors. Therefore,both kinesin–microtubule and actomyosin transport systemsappeared to be not only important for the ubiquitous processof Ca²⁺-regulated exocytosis but were also essential for normalcell membrane resealing.

View this table:
[in this window]
[in a new window]

Table I Effect of KHC fragments on Cell Membrane Resealing in Activated Eggs of L. pictus

View this table:
[in this window]
[in a new window]

Table II Effect of BDM on Cell Membrane Resealing in Activated Eggs of L. pictus

	Discussion

Top Abstract Materials and Methods Results Discussion References

During the past few years, a great deal has been learned aboutvesicle docking and fusion mechanisms (Sudhof et al., 1993;Bennett and Scheller, 1994; De Camilli, 1995) in Ca²⁺-regulatedexocytosis. However, much less is known about the recruitmentof vesicles in the regulated exocytotic pathway (Scholey, 1996;Vallee and Sheetz, 1996). In these experiments, the distincttemporal patterns of inhibition of exocytosis by reagents targetingtwo different motor systems are consistent with two sequentialmotor-driven recruitment steps for vesicle exocytosis—akinesin-mediated transport step followed by an actomyosin-based step. Fig. 7 B summarizes the essential features of this transport/exocytosispathway. This picture is also consistent with the fact thatastral microtubules extend from the cell center to the cellperiphery, while short actin filaments form networks near thecell membrane (Hollenbeck and Cande, 1985), and with the coexistenceof kinesin–microtubule and actomyosin motor systems onthe same organelles (Fath et al., 1994; Morris and Hollenbeck, 1995). Similar mechanisms have been postulated in other systems basedon elegant in vitro observations (Fath et al., 1994; Allan, 1995;Langford, 1995). Our results, however, provide in vivo evidencefor this postulated two-step pathway in general vesicular trafficking.Furthermore, our results also indicate that the recruitmentof an average vesicle may need about 20 s of kinesin transportand about 5–10 s of myosin transport. Translating intospatial measures, these numbers correspond to about 20 µmof microtubule track and about 5–10 µm of actinfilament track, assuming the average motor speeds are botharound 1 µm/s (Vale et al., 1985b; Porter et al., 1987;Langford et al., 1994; Bearer et al., 1996). Considering thatthe cell size is $~$ 40 µm in diameter for a four-cell stageembryo, there is enough time to recruit vesicles from any intracellularlocation to the cell surface.

View larger version (35K):
[in this window]
[in a new window]
[Download PPT slide]

Figure 7 Three distinct vesicle pools and two-step vesicular recruitment for Ca²⁺-regulated exocytosis. (A) Three vesicle pools and their temporal distribution of exocytosis rates (number of exocytotic events per unit time) based on the data shown in Figs. 3–5. The "Immediate" pool of vesicles (squares) are BDM insensitive (and also kinesin reagents insensitive) and are therefore not dependent of either kinesin or myosin transport mechanism. The "Fast" pool (diamonds) is myosin dependent but kinesin independent. It was calculated by subtracting the myosin-independent (BDM-insensitive) component from the kinesin-independent exocytosis (average of SUK4 and Stalk-tail data). The "Slow" pool (circles) is kinesin dependent and was obtained by subtracting the kinesin-independent exocytosis from the average of control, SUK2, and Stalk data. (B) The proposed relative distribution of different vesicle pools and the kinesin- and myosin-mediated transport mechanisms.

Conventional kinesin is the most abundant member in the largefamily of KRPs. In sea urchin embryonic cells, there is atleast 10-fold more kinesin than the next most abundant KRP,kinesin-2. (Scholey, J., unpublished observation). Conventionalkinesin associates with the vesicles in the mitotic spindleasters (Wright et al., 1991) but is apparently not essentialfor mitosis (Wright et al., 1993). Because SUK4 is specificfor kinesin and does not cross-react with any other known KRPs,and more importantly, because the KHC tail domain is variableamong different KRPs, the inhibition of exocytosis by SUK4and KHC stalk-tail domain strongly suggests that the conventional kinesin, rather than any other KRPs, is the protein motor for vesicle transport in regulated exocytosis. In addition, these results clearly demonstrate that the variable tail domainis responsible for in vivo vesicle cargo binding, as has beensuggested based on in vitro observations (Skoufias et al., 1994;Bloom and Endow, 1995; Vallee and Sheetz, 1996). Kinectin,an integral membrane protein of the endoplasmic reticulum, hasbeen identified as a membrane anchor protein for kinesin inthe chick brain (Kumar et al., 1995). A similar protein maybe responsible for the KHC tail binding in our system.

The myosin motor protein family consists of many structuraland functional distinct isoforms (Hasson and Mooseker, 1995).Which isoforms may be involved in vesicular transport is stillan open question (Hasson and Mooseker, 1995). BDM inhibitsmany myosin isoforms and could also have other effects. Possiblecomplications from BDM effects on membrane conductance do notplay a role in our preparation since Ca²⁺ influx is directlyfrom a membrane wound. By having the advantage of direct visualizationof regulated exocytotic events, our system provides a relativelysimple in vivo assay that may help more explicitly identifythe myosins responsible for vesicle recruitment when more specificreagents become available.

The inhibition of CaM kinase II has a similar effect on exocytosisas BDM, and this encourages us to believe both are affectingan actin-based step in vesicle delivery. However, the inhibitoryeffects we observed on exocytosis, while consistent with interruptionof vesicle transport at the myosin-actin–dependent step,cannot be conclusive. CaM kinase II has been shown to be ableto phosphorylate a number of targets in docking/fusion: synaptobrevin,synaptotagmin, and rabphilin-3A (Popoli, 1993; Fykse et al., 1995;Nielander et al., 1995; Hirling and Scheller, 1996; Popoli et al., 1997).Any of these proteins might conceivably be a target, and theirphosphorylation by CaM kinase II may yet be shown to play aregulatory role. However, at the moment, there is no evidencesuggesting that these phosphorylations must precede successfuldocking and fusion. More telling, in our results when we specifically tested the block of CaM kinase on previously docked corticalgranules, it had no effect on the fusion step of exocytosis.The most abundant synaptic phosphoprotein, synapsin and itshomologues, are more likely to be the targets affected by CaMkinase II in vesicle recruitment for exocytosis. Double knockoutsof synapsin I and II exhibited decreased posttetanic potentiationand severe synaptic depression upon repetitive stimulation (Rosahl et al., 1995). Peptide inhibitors of CaM kinase II preferentially suppressedthe phosphorylation of synapsin I at the CaM kinase II–specificsite and decreased excitatory synaptic responses elicited inthe CA1 region of hippocampal slices (Waxham et al., 1993).These inhibitory effects on exocytosis could be explained bydeficient recruitment of vesicles to the active zone, in linewith the need for phosphorylation of synapsin by CaM kinaseII to free vesicles from actin (Ceccaldi et al., 1995).

The three vesicle pools identified by the action of blockersof kinesin function and BDM are closely related to the two-steptransport mechanism. As shown in Fig. 7, the immediate poolrepresents vesicles that can exocytose when transport mechanismsare blocked. These vesicles must have passed the recruitmentsteps and are functionally docked on the plasma membrane, readyto fuse in response to Ca²⁺ influx. The fast pool, on the otherhand, should consist of vesicles that have just passed thekinesin transport step but still require myosin-mediated transport before docking and fusion. The slow pool is the most upstreamin this trafficking pathway. These vesicles must be first transportedvia a kinesin–microtubule system and then via an actomyosinsystem before approaching the plasma membrane. Recent studieson the nerve termini have defined vesicle pools using differentcriteria (Borges et al., 1995; Pieribone et al., 1995; Rosahl et al., 1995; Stevens and Tsujimoto, 1995; Rosenmund and Stevens, 1996).The time constant for replenishment of the readily releasablepool at nerve termini is also about 10 s (Stevens and Tsujimoto, 1995).It will be interesting to know how much of the vesicle recruitmentscheme described above is applicable to neuronal transmission.One study found that a smooth muscle antimyosin II antibodymicroinjected into presynaptic neurons inhibited synaptic transmission; however, the antibody fraction with this activity is no longeravailable (Mochida et al., 1994).

The fast pool, which we are labeling myosin dependent, mustbe relatively stable in the absence of Ca²⁺ influx because itwould otherwise have been depleted when kinesin transport wasblocked. Therefore, the myosin-mediated transport is not constitutivelyactive but is probably turned up by intracellular Ca²⁺ elevation.This may be accomplished, at least in part, by the activationof CaM kinase II since BDM and CaM kinase II autoinhibitorypeptide disrupt at the fast pool step. Likewise, the kinesin-mediated transport should also be activated by Ca²⁺ influx through the wounding because otherwise the vesicle pools after the kinesin transport step would have accumulated and would thereforebe much larger in the control cases than in the cases withSUK4 or KHC stalk-tail injection. The nature and kinetics ofthe regulation for either transport system are not clear. However,Ca²⁺ ions appear to play a key role in both steps because itis probably the first signal the cell can receive after membranewounding. This is also consistent with the observation of multiplecalcium-dependent processes related to secretion in bovine chromaffin cells (Neher and Zucker, 1993).

Finally, this study adds to our knowledge of the process thatreseals disrupted cell membrane. Recent experiments have indicatedthat Ca²⁺-regulated exocytosis is a ubiquitous process in manycell types (Dan and Poo, 1992; Steinhardt et al., 1994; Bi et al., 1995;Girod et al., 1995; Coorssen et al., 1996; Rodriguez et al., 1997)and is essential for cell membrane resealing (Steinhardt et al., 1994;Bi et al., 1995; Miyake and McNeil, 1995). Although the detailed physical picture of the resealing process is not clear, ithas been demonstrated that the addition of membrane lipids proximal to the wound site by vesicle exocytosis is necessaryfor the final "closure" of wounded membrane (Bi et al., 1995).The inhibition of membrane repair by block of CaM kinase II(Steinhardt et al., 1994) is now directly correlated with theinhibition of exocytosis. In addition, consistent with our earlierresults (Steinhardt et al., 1994), we found that cells couldnot reseal when their kinesin transport was inhibited (TableI), even though the early phases of exocytosis were intactunder the same conditions (Figs. 2–4). It therefore appearsthat exocytosis must be sustained and prolonged by the activetransport of vesicles to successfully reseal a disrupted membraneand ensure cell survival.

Acknowledgments

We thank A. Tieu and D. MacDermed for technical assistance.

This work was supported by the Committee on Research of theUniversity of California, Berkeley, the National Institutesof Health, and the American Cancer Society.

Submitted: 19 December 1996

Revised: 26 June 1997

Address all correspondence to Richard A. Steinhardt, Departmentof Molecular and Cell Biology, University of California, Berkeley,CA 94720-3200. Tel.: (510) 642-3517. Fax: (510) 643-6791. E-mail:rick{at}mendel.berkeley.edu

Guo-Qiang Bi's current address is Department of Biology, University of California at San Diego, La Jolla, CA 92093-0357.

References

Top
Abstract
Materials and Methods
Results
Discussion
References

Adams RJ & Pollard TD. Propulsion of organelles isolated from Acanthamoeba along actin filaments by myosin-I, Nature (Lond), 1986, 322, 754–756.[Medline]

Allan V. Membrane traffic motors, FEBS Lett, 1995, 369, 101–106.[Medline]

Baitinger C, Alderton J, Poenie M, Schulman H & Steinhardt RA. Multifunctional Ca²⁺/calmodulin-dependent protein kinase is necessary for nuclear envelope breakdown, J Cell Biol, 1990, 111, 1763–1773.[Abstract/Free Full Text]

Bearer EL, DeGiorgis JA, Medeiros NA & Reese TS. Actin-based motility of isolated axoplasmic organelles, Cell Motil Cytoskel, 1996, 33, 106–114.[Medline]

Bennett MK & Scheller RH. Molecular correlates of synaptic vesicle docking and fusion, Curr Opin Neurobiol, 1994, 4, 324–329.[Medline]

Betz WJ & Bewick GS. Optical analysis of synaptic vesicle recycling at the frog neuromuscular junction, Science (Wash DC), 1992, 255, 200–203.[Abstract/Free Full Text]

Betz WJ & Wu LG. Synaptic transmission. Kinetics of synaptic-vesicle recycling, Curr Biol, 1995, 5, 1098–1101.[Medline]

Bi GQ, Alderton JM & Steinhardt RA. Calcium-regulated exocytosis is required for cell membrane resealing, J Cell Biol, 1995, 131, 1747–1758.[Abstract/Free Full Text]

Bloom GS & Endow SA. Motor proteins 1: kinesins, Protein Profile, 1995, 2, 1105–1171.[Medline]

Borges S, Gleason E, Turelli M & Wilson M. The kinetics of quantal transmitter release from retinal amacrine cells, Proc Natl Acad Sci USA, 1995, 92, 6896–6900.[Abstract/Free Full Text]

Brady ST, Pfister KK & Bloom GS. A monoclonal antibody against kinesin inhibits both anterograde and retrograde fast axonal transport in squid axoplasm, Proc Natl Acad Sci USA, 1990, 87, 1061–1065.[Abstract/Free Full Text]

Ceccaldi PE, Grohovaz F, Benfenati F, Chieregatti E, Greengard P & Valtorta F. Dephosphorylated synapsin I anchors synaptic vesicles to actin cytoskeleton: an analysis by videomicroscopy, J Cell Biol, 1995, 128, 905–912.[Abstract/Free Full Text]

Coorssen JR, Schmitt H & Almers W. Ca²⁺triggers massive exocytosis in Chinese hamster ovary cells, EMBO (Eur Mol Biol Organ) J, 1996, 15, 3787–3791.[Medline]

Cramer LP & Mitchison TJ. Myosin is involved in postmitotic cell spreading, J Cell Biol, 1995, 131, 179–189.[Abstract/Free Full Text]

Dan Y & Poo MM. Quantal transmitter secretion from myocytes loaded with acetylcholine, Nature (Lond), 1992, 359, 733–736.[Medline]

De Camilli P. The eighth Datta Lecture. Molecular mechanisms in synaptic vesicle recycling, FEBS Lett, 1995, 369, 3–12.[Medline]

Drubin DG & Nelson WJ. Origins of cell polarity, Cell, 1996, 84, 335–344.[Medline]

Fath KR & Burgess DR. Membrane motility mediated by unconventional myosin, Curr Opin Cell Biol, 1994, 6, 131–135.[Medline]

Fath KR, Trimbur GM & Burgess DR. Molecular motors are differentially distributed on Golgi membranes from polarized epithelial cells, J Cell Biol, 1994, 126, 661–675.[Abstract/Free Full Text]

Fykse EM, Li C & Sudhof TC. Phosphorylation of rabphilin-3A by Ca²⁺/calmodulin- and cAMP-dependent protein kinases in vitro, J Neurosci, 1995, 15, 2385–2395.[Abstract]

Gho M, McDonald K, Ganetzky B & Saxton WM. Effects of kinesin mutations on neuronal functions, Science (Wash DC), 1992, 258, 313–316.[Abstract/Free Full Text]

Girod R, Popov S, Alder J, Zheng JQ, Lohof A & Poo MM. Spontaneous quantal transmitter secretion from myocytes and fibroblasts: comparison with neuronal secretion, J Neurosci, 1995, 15, 2826–2838.[Abstract]

Goldstein LS. With apologies to Scheherazade: tails of 1001 kinesin motors, Annu Rev Genet, 1993, 27, 319–351.[Medline]

Grolig F, Williamson RE, Parke J, Miller C & Anderton BH. Myosin and Ca²⁺-sensitive streaming in the alga Chara: detection of two polypeptides reacting with a monoclonal anti-myosin and their localization in the streaming endoplasm, Eur J Cell Biol, 1988, 47, 22–31.[Medline]

Hasson T & Mooseker MS. Molecular motors, membrane movements and physiology: emerging roles for myosins, Curr Opin Cell Biol, 1995, 7, 587–594.[Medline]

Hirling H & Scheller RH. Phosphorylation of synaptic vesicle proteins: modulation of the alpha SNAP interaction with the core complex, Proc Natl Acad Sci USA, 1996, 93, 11945–11949.[Abstract/Free Full Text]

Hirokawa N, Pfister KK, Yorifuji H, Wagner MC, Brady ST & Bloom GS. Submolecular domains of bovine brain kinesin identified by electron microscopy and monoclonal antibody decoration, Cell, 1989, 56, 867–878.[Medline]

Hollenbeck PJ & Cande WZ. Microtubule distribution and reorganization in the first cell cycle of fertilized eggs of Lytechinus pictus. , Eur J Cell Biol, 1985, 37, 140–148.[Medline]

Hollenbeck PJ & Swanson JA. Radial extension of macrophage tubular lysosomes supported by kinesin, Nature (Lond), 1990, 346, 864–866.[Medline]

Ingold AL, Cohn SA & Scholey JM. Inhibition of kinesin-driven microtubule motility by monoclonal antibodies to kinesin heavy chains, J Cell Biol, 1988, 107, 2657–2667.[Abstract/Free Full Text]

Johnston GC, Prendergast JA & Singer RA. The Saccharomyces cerevisiaeMYO2 gene encodes an essential myosin for vectorial transport of vesicles, J Cell Biol, 1991, 113, 539–551.[Abstract/Free Full Text]

Kumar J, Yu H & Sheetz MP. Kinectin, an essential anchor for kinesin-driven vesicle motility, Science (Wash DC), 1995, 267, 1834–1837.[Abstract/Free Full Text]

Kuznetsov SA, Langford GM & Weiss DG. Actin-dependent organelle movement in squid axoplasm, Nature (Lond), 1992, 356, 722–725.[Medline]

Langford GM. Actin- and microtubule-dependent organelle motors: interrelationships between the two motility systems, Curr Opin Cell Biol, 1995, 7, 82–88.[Medline]

Langford GM, Kuznetsov SA, Johnson D, Cohen DL & Weiss DG. Movement of axoplasmic organelles on actin filaments assembled on acrosomal processes: evidence for a barbed-end-directed organelle motor, J Cell Sci, 1994, 107, 2291–2298.[Abstract]

Lin CH, Espreafico EM, Mooseker MS & Forscher P. Myosin drives retrograde F-actin flow in neuronal growth cones, Neuron, 1996, 16, 769–782.[Medline]

Llinas R, Gruner JA, Sugimori M, McGuinness TL & Greengard P. Regulation by synapsin I and Ca(2+)-calmodulin-dependent protein kinase II of the transmitter release in squid giant synapse, J Physiol, 1991, 436, 257–282.[Abstract/Free Full Text]

Miller M, Bower E, Levitt P, Li D & Chantler PD. Myosin II distribution in neurons is consistent with a role in growth cone motility but not synaptic vesicle mobilization, Neuron, 1992, 8, 25–44.[Medline]

Miyake K & McNeil PL. Vesicle accumulation and exocytosis at sites of plasma membrane disruption, J Cell Biol, 1995, 131, 1737–1745.[Abstract/Free Full Text]

Mochida S, Kobayashi H, Matsuda Y, Yuda Y, Muramoto K & Nonomura Y. Myosin II is involved in transmitter release at synapses formed between rat sympathetic neurons in culture, Neuron, 1994, 13, 1131–1142.[Medline]

Morris RL & Hollenbeck PJ. Axonal transport of mitochondria along microtubules and F-actin in living vertebrate neurons, J Cell Biol, 1995, 131, 1315–1326.[Abstract/Free Full Text]

Neher E & Zucker RS. Multiple calcium-dependent processes related to secretion in bovine chromaffin cells, Neuron, 1993, 10, 21–30.[Medline]

Nielander HB, Onofri F, Valtorta F, Schiavo G, Montecucco C, Greengard P & Benfenati F. Phosphorylation of VAMP/synaptobrevin in synaptic vesicles by endogenous protein kinases, J Neurochem, 1995, 65, 1712–1720.[Medline]

Pieribone VA, Shupliakov O, Brodin L, Hilfiker-Rothenfluh S, Czernik AJ & Greengard P. Distinct pools of synaptic vesicles in neurotransmitter release [see comments], Nature (Lond), 1995, 375, 493–497.[Medline]

Popoli M. Synaptotagmin is endogenously phosphorylated by Ca²⁺/calmodulin protein kinase II in synaptic vesicles, FEBS Lett, 1993, 317, 85–88.[Medline]

Popoli M, Venegoni A, Vocaturo C, Buffa L, Perez J, Smeraldi E & Racagni G. Long-term blockade of serotonin reuptake affects synaptotagmin phosphorylation in the hippocampus, Mol Pharm, 1997, 51, 19–26.[Abstract/Free Full Text]

Porter ME, Scholey JM, Stemple DL, Vigers GP, Vale RD, Sheetz MP & McIntosh JR. Characterization of the microtubule movement produced by sea urchin egg kinesin, J Biol Chem, 1987, 262, 2794–2802.[Abstract/Free Full Text]

Rodriguez A, Webster P, Ortego J & Andrews NW. Lysosomes behave as Ca²⁺-regulated exocytic vesicles in fibroblasts and epithelial cells, J Cell Biol, 1997, 137, 93–104.[Abstract/Free Full Text]

Rodionov VI, Gyoeva FK & Gelfand VI. Kinesin is responsible for centrifugal movement of pigment granules in melanophores, Proc Natl Acad Sci USA, 1991, 88, 4956–4960.[Abstract/Free Full Text]

Rosahl TW, Spillane D, Missler M, Herz J, Selig DK, Wolff JR, Hammer RE, Malenka RC & Sudhof TC. Essential functions of synapsins I and II in synaptic vesicle regulation [see comments], Nature (Lond), 1995, 375, 488–493.[Medline]

Rosenmund C & Stevens CF. Definition of the readily releasable pool of vesicles at hippocampal synapses, Neuron, 1996, 16, 1197–1207.[Medline]

Ryan TA, Reuter H, Wendland B, Schweizer FE, Tsien RW & Smith SJ. The kinetics of synaptic vesicle recycling measured at single presynaptic boutons, Neuron, 1993, 11, 713–724.[Medline]

Saxton WM, Hicks J, Goldstein LS & Raff EC. Kinesin heavy chain is essential for viability and neuromuscular functions in Drosophila, but mutants show no defects in mitosis, Cell, 1991, 64, 1093–1102.[Medline]

Scholey JM. Kinesin-II, a membrane traffic motor in axons, axonemes, and spindles, J Cell Biol, 1996, 133, 1–4.[Free Full Text]

Scholey JM, Porter ME, Grissom PM & McIntosh JR. Identification of kinesin in sea urchin eggs, and evidence for its localization in the mitotic spindle, Nature (Lond), 1985, 318, 483–486.[Medline]

Skoufias DA, Cole DG, Wedaman KP & Scholey JM. The carboxyl-terminal domain of kinesin heavy chain is important for membrane binding, J Biol Chem, 1994, 269, 1477–1485.[Abstract/Free Full Text]

Steinhardt RA, Bi G & Alderton JM. Cell membrane resealing by a vesicular mechanism similar to neurotransmitter release, Science (Wash DC), 1994, 263, 390–393.[Abstract/Free Full Text]

Stevens CF & Tsujimoto T. Estimates for the pool size of releasable quanta at a single central synapse and for the time required to refill the pool, Proc Natl Acad Sci USA, 1995, 92, 846–849.[Abstract/Free Full Text]

Sudhof TC, De Camilli P, Niemann H & Jahn R. Membrane fusion machinery: insights from synaptic proteins, Cell, 1993, 75, 1–4.[Medline]

Terasaki M. Visualization of exocytosis during sea urchin egg fertilization using confocal microscopy, J Cell Sci, 1995, 108, 2293–2300.[Abstract]

Vale RD, Reese TS & Sheetz MP. Identification of a novel force-generating protein, kinesin, involved in microtubule-based motility, Cell, 1985a, 42, 39–50.[Medline]

Vale RD, Schnapp BJ, Mitchison T, Steuer E, Reese TS & Sheetz MP. Different axoplasmic proteins generate movement in opposite directions along microtubules in vitro, Cell, 1985b, 43, 623–632.[Medline]

Vallee RB & Sheetz MP. Targeting of motor proteins, Science (Wash DC), 1996, 271, 1539–1544.[Abstract]

Waxham MN, Malenka RC, Kelly PT & Mauk MD. Calcium/ calmodulin-dependent protein kinase II regulates hippocampal synaptic transmission, Brain Res, 1993, 609, 1–8.[Medline]

Wright BD, Henson JH, Wedaman KP, Willy PJ, Morand JN & Scholey JM. Subcellular localization and sequence of sea urchin kinesin heavy chain: evidence for its association with membranes in the mitotic apparatus and interphase cytoplasm [published erratum appears 114:following 863], J Cell Biol, 1991, 113, 817–833.[Abstract/Free Full Text]

Wright BD, Terasaki M & Scholey JM. Roles of kinesin and kinesin-like proteins in sea urchin embryonic cell division: evaluation using antibody microinjection, J Cell Biol, 1993, 123, 681–689.[Abstract/Free Full Text]

Yang JT, Laymon RA & Goldstein LS. A three-domain structure of kinesin heavy chain revealed by DNA sequence and microtubule binding analyses, Cell, 1989, 56, 879–889.[Medline]

Yang JT, Saxton WM, Stewart RJ, Raff EC & Goldstein LS. Evidence that the head of kinesin is sufficient for force generation and motility in vitro, Science (Wash DC), 1990, 249, 42–47.[Abstract/Free Full Text]

CiteULike

Complore

Connotea

Del.icio.us Add to Digg

Digg

Facebook

Technorati

Twitter What's this?

This article has been cited by other articles:

Cao, L., Yu, K., Banh, C., Nguyen, V., Ritz, A., Raphael, B. J., Kawakami, Y., Kawakami, T., Salomon, A. R. (2007). Quantitative Time-Resolved Phosphoproteomic Analysis of Mast Cell Signaling. J. Immunol. 179: 5864-5876 [Abstract] [Full Text]
Hehnly, H., Sheff, D., Stamnes, M. (2006). Shiga Toxin Facilitates Its Retrograde Transport by Modifying Microtubule Dynamics. Mol. Biol. Cell 17: 4379-4389 [Abstract] [Full Text]
Whitaker, M. (2006). Calcium at Fertilization and in Early Development. Physiol. Rev. 86: 25-88 [Abstract] [Full Text]
Vlahakis, N. E., Hubmayr, R. D. (2005). Cellular Stress Failure in Ventilator-injured Lungs. Am. J. Respir. Crit. Care Med. 171: 1328-1342 [Abstract] [Full Text]
Togo, T. (2004). Long-term Potentiation of Wound-induced Exocytosis and Plasma Membrane Repair Is Dependant on cAMP-response Element-mediated Transcription via a Protein Kinase C- and p38 MAPK-dependent Pathway. J. Biol. Chem. 279: 44996-45003 [Abstract] [Full Text]
Provance, D. W. Jr., Gourley, C. R., Silan, C. M., Cameron, L. C., Shokat, K. M., Goldenring, J. R., Shah, K., Gillespie, P. G., Mercer, J. A. (2004). From the Cover: Chemical-genetic inhibition of a sensitized mutant myosin Vb demonstrates a role in peripheral-pericentriolar membrane traffic. Proc. Natl. Acad. Sci. USA 101: 1868-1873 [Abstract] [Full Text]
Togo, T., Steinhardt, R. A. (2004). Nonmuscle Myosin IIA and IIB Have Distinct Functions in the Exocytosis-dependent Process of Cell Membrane Repair. Mol. Biol. Cell 15: 688-695 [Abstract] [Full Text]
Ali, M. K., Bergson, C. (2003). Elevated Intracellular Calcium Triggers Recruitment of the Receptor Cross-talk Accessory Protein Calcyon to the Plasma Membrane. J. Biol. Chem. 278: 51654-51663 [Abstract] [Full Text]
Manneville, J.-B., Etienne-Manneville, S., Skehel, P., Carter, T., Ogden, D., Ferenczi, M. (2003). Interaction of the actin cytoskeleton with microtubules regulates secretory organelle movement near the plasma membrane in human endothelial cells. J. Cell Sci. 116: 3927-3938 [Abstract] [Full Text]
Zhou, R., Watson, C., Fu, C., Yao, X., Forte, J. G. (2003). Myosin II is present in gastric parietal cells and required for lamellipodial dynamics associated with cell activation. Am. J. Physiol. Cell Physiol. 285: C662-C673 [Abstract] [Full Text]
Schmoranzer, J., Simon, S. M. (2003). Role of Microtubules in Fusion of Post-Golgi Vesicles to the Plasma Membrane. Mol. Biol. Cell 14: 1558-1569 [Abstract] [Full Text]
Danilchik, M. V., Bedrick, S. D., Brown, E. E., Ray, K. (2003). Furrow microtubules and localized exocytosis in cleaving Xenopus laevis embryos. J. Cell Sci. 116: 273-283 [Abstract] [Full Text]
Romagnoli, S., Cai, G., Cresti, M. (2003). In Vitro Assays Demonstrate That Pollen Tube Organelles Use Kinesin-Related Motor Proteins to Move along Microtubules. Plant Cell 15: 251-269 [Abstract] [Full Text]
Togo, T., Alderton, J. M., Steinhardt, R. A. (2003). Long-Term Potentiation of Exocytosis and Cell Membrane Repair in Fibroblasts. Mol. Biol. Cell 14: 93-106 [Abstract] [Full Text]
Jaiswal, J. K., Andrews, N. W., Simon, S. M. (2002). Membrane proximal lysosomes are the major vesicles responsible for calcium-dependent exocytosis in nonsecretory cells. JCB 159: 625-635 [Abstract] [Full Text]
Varadi, A., Ainscow, E. K., Allan, V. J., Rutter, G. A. (2002). Involvement of conventional kinesin in glucose-stimulated secretory granule movements and exocytosis in clonal pancreatic {beta}-cells. J. Cell Sci. 115: 4177-4189 [Abstract] [Full Text]
Vlahakis, N. E., Schroeder, M. A., Pagano, R. E., Hubmayr, R. D. (2002). Role of Deformation-induced Lipid Trafficking in the Prevention of Plasma Membrane Stress Failure. Am. J. Respir. Crit. Care Med. 166: 1282-1289 [Abstract] [Full Text]
Heidelberger, R., Sterling, P., Matthews, G. (2002). Roles of ATP in Depletion and Replenishment of the Releasable Pool of Synaptic Vesicles. J. Neurophysiol. 88: 98-106 [Abstract] [Full Text]
Shuster, C. B., Burgess, D. R. (2002). Targeted new membrane addition in the cleavage furrow is a late, separate event in cytokinesis. Proc. Natl. Acad. Sci. USA 99: 3633-3638 [Abstract] [Full Text]
McNeil, P. L. (2002). Repairing a torn cell surface: make way, lysosomes to the rescue. J. Cell Sci. 115: 873-879 [Abstract] [Full Text]
Scholey, J. M., Rogers, G. C., Sharp, D. J. (2001). Mitosis, microtubules, and the matrix. JCB 154: 261-266 [Abstract] [Full Text]
Vlahakis, N. E., Schroeder, M. A., Pagano, R. E., Hubmayr, R. D. (2001). Deformation-induced lipid trafficking in alveolar epithelial cells. Am. J. Physiol. Lung Cell. Mol. Physiol. 280: L938-L946 [Abstract] [Full Text]
Verhey, K. J., Meyer, D., Deehan, R., Blenis, J., Schnapp, B. J., Rapoport, T. A., Margolis, B. (2001). Cargo of Kinesin Identified as Jip Scaffolding Proteins and Associated Signaling Molecules. JCB 152: 959-970 [Abstract] [Full Text]
Miyake, K., McNeil, P. L., Suzuki, K., Tsunoda, R., Sugai, N. (2001). An actin barrier to resealing. J. Cell Sci. 114: 3487-3494 [Abstract] [Full Text]
Kawakami, K., Tatsumi, H., Sokabe, M. (2001). Dynamics of integrin clustering at focal contacts of endothelial cells studied by multimode imaging microscopy. J. Cell Sci. 114: 3125-3135 [Abstract] [Full Text]
Vlahakis, N. E., Hubmayr, R. D. (2000). Cellular Responses to Mechanical Stress: Invited Review: Plasma membrane stress failure in alveolar epithelial cells. J. Appl. Physiol. 89: 2490-2496 [Abstract] [Full Text]
Togo, T., Krasieva, T. B., Steinhardt, R. A. (2000). A Decrease in Membrane Tension Precedes Successful Cell-Membrane Repair. Mol. Biol. Cell 11: 4339-4346 [Abstract] [Full Text]
Bertelli, E., Regoli, M., Gambelli, F., Lucattelli, M., Lungarella, G., Bastianini, A. (2000). GFAP Is Expressed as a Major Soluble Pool Associated with Glucagon Secretory Granules in A-cells of Mouse Pancreas. J. Histochem. Cytochem. 48: 1233-1242 [Abstract] [Full Text]
Cai, G., Romagnoli, S., Moscatelli, A., Ovidi, E., Gambellini, G., Tiezzi, A., Cresti, M. (2000). Identification and Characterization of a Novel Microtubule-Based Motor Associated with Membranous Organelles in Tobacco Pollen Tubes. Plant Cell 12: 1719-1736 [Abstract] [Full Text]
Brendza, R. P., Sheehan, K. B., Turner, F.R., Saxton, W. M. (2000). Clonal Tests of Conventional Kinesin Function during Cell Proliferation and Differentiation. Mol. Biol. Cell 11: 1329-1343 [Abstract] [Full Text]
Alderton, J. M., Steinhardt, R. A. (2000). Calcium Influx through Calcium Leak Channels Is Responsible for the Elevated Levels of Calcium-dependent Proteolysis in Dystrophic Myotubes. J. Biol. Chem. 275: 9452-9460 [Abstract] [Full Text]
Valentijn, J. A., Valentijn, K., Pastore, L. M., Jamieson, J. D. (2000). Actin coating of secretory granules during regulated exocytosis correlates with the release of rab3D. Proc. Natl. Acad. Sci. USA 97: 1091-1095 [Abstract] [Full Text]
McNeil, P., Vogel, S., Miyake, K, Terasaki, M (2000). Patching plasma membrane disruptions with cytoplasmic membrane. J. Cell Sci. 113: 1891-1902 [Abstract]
Gyoeva, F., Bybikova, E., Minin, A. (2000). An isoform of kinesin light chain specific for the Golgi complex. J. Cell Sci. 113: 2047-2054 [Abstract]
Eddy, R., Pierini, L., Matsumura, F, Maxfield, F. (2000). Ca2+-dependent myosin II activation is required for uropod retraction during neutrophil migration. J. Cell Sci. 113: 1287-1298 [Abstract]
Kessels, M. M., Engqvist-Goldstein, A. E. Y., Drubin, D. G. (2000). Association of Mouse Actin-binding Protein 1 (mAbp1/SH3P7), an Src Kinase Target, with Dynamic Regions of the Cortical Actin Cytoskeleton in Response to Rac1 Activation. Mol. Biol. Cell 11: 393-412 [Abstract] [Full Text]
Signor, D., Wedaman, K. P., Orozco, J. T., Dwyer, N. D., Bargmann, C. I., Rose, L. S., Scholey, J. M. (1999). Role of a Class Dhc1b Dynein in Retrograde Transport of Ift Motors and Ift Raft Particles along Cilia, but Not Dendrites, in Chemosensory Neurons of Living Caenorhabditis elegans. JCB 147: 519-530 [Abstract] [Full Text]
Rodriguez, A., Martinez, I., Chung, A., Berlot, C. H., Andrews, N. W. (1999). cAMP Regulates Ca2+-dependent Exocytosis of Lysosomes and Lysosome-mediated Cell Invasion by Trypanosomes. J. Biol. Chem. 274: 16754-16759 [Abstract] [Full Text]
Costa, M. C. R., Mani, F., Santoro, W. Jr., Espreafico, E. M., Larson, R. E. (1999). Brain Myosin-V, a Calmodulin-carrying Myosin, Binds to Calmodulin-dependent Protein Kinase II and Activates Its Kinase Activity. J. Biol. Chem. 274: 15811-15819 [Abstract] [Full Text]
Esnault, K., el Moudni, B., Bouchara, J.-P., Chabasse, D., Tronchin, G. (1999). Association of a Myosin Immunoanalogue with Cell Envelopes of Aspergillus fumigatus Conidia and Its Participation in Swelling and Germination. Infect. Immun. 67: 1238-1244 [Abstract] [Full Text]
Rothwell, W., Zhang, C., Zelano, C, Hsieh, T., Sullivan, W (1999). The Drosophila centrosomal protein Nuf is required for recruiting Dah, a membrane associated protein, to furrows in the early embryo. J. Cell Sci. 112: 2885-2893 [Abstract]
Togo, T, Alderton, J., Bi, G., Steinhardt, R. (1999). The mechanism of facilitated cell membrane resealing. J. Cell Sci. 112: 719-731 [Abstract]
Tuma, M. C., Zill, A., Le Bot, N., Vernos, I., Gelfand, V. (1998). Heterotrimeric Kinesin II Is the Microtubule Motor Protein Responsible for Pigment Dispersion in Xenopus Melanophores. JCB 143: 1547-1558 [Abstract] [Full Text]
Verhey, K. J., Lizotte, D. L., Abramson, T., Barenboim, L., Schnapp, B. J., Rapoport, T. A. (1998). Light Chain- dependent Regulation of Kinesin's Interaction with Microtubules. JCB 143: 1053-1066 [Abstract] [Full Text]
Brown, D., Katsura, T., Gustafson, C. E. (1998). Cellular mechanisms of aquaporin trafficking. Am. J. Physiol. Renal Physiol. 275: F328-F331 [Abstract] [Full Text]
Wilson, J. R., Ludowyke, R. I., Biden, T. J. (1998). Nutrient Stimulation Results in a Rapid Ca2+-dependent Threonine Phosphorylation of Myosin Heavy Chain in Rat Pancreatic Islets and RINm5F Cells. J. Biol. Chem. 273: 22729-22737 [Abstract] [Full Text]
Finger, F. P., Novick, P. (1998). Spatial Regulation of Exocytosis: Lessons from Yeast. JCB 142: 609-612 [Full Text]
Rahman, A., Friedman, D. S., Goldstein, L. S.�B. (1998). Two Kinesin Light Chain Genes in Mice. IDENTIFICATION AND CHARACTERIZATION OF THE ENCODED PROTEINS. J. Biol. Chem. 273: 15395-15403 [Abstract] [Full Text]
Gindhart, J. G. Jr., Desai, C. J., Beushausen, S., Zinn, K., Goldstein, L. S.B. (1998). Kinesin Light Chains Are Essential for Axonal Transport in Drosophila. JCB 141: 443-454 [Abstract] [Full Text]
Liao, G., Gundersen, G. G. (1998). Kinesin Is a Candidate for Cross-bridging Microtubules and Intermediate Filaments. SELECTIVE BINDING OF KINESIN TO DETYROSINATED TUBULIN AND VIMENTIN. J. Biol. Chem. 273: 9797-9803 [Abstract] [Full Text]
Khodjakov, A., Lizunova, E. M., Minin, A. A., Koonce, M. P., Gyoeva, F. K. (1998). A Specific Light Chain of Kinesin Associates with Mitochondria in Cultured Cells. Mol. Biol. Cell 9: 333-343 [Abstract] [Full Text]
Morris, R. L., Scholey, J. M. (1997). Heterotrimeric Kinesin-II Is Required for the Assembly of Motile 9+2 Ciliary Axonemes on Sea Urchin Embryos. JCB 138: 1009-1022 [Abstract] [Full Text]
Ong, L.-L., Lim, A. P. C., Er, C. P. N., Kuznetsov, S. A., Yu, H. (2000). Kinectin-Kinesin Binding Domains and Their Effects on Organelle Motility. J. Biol. Chem. 275: 32854-32860 [Abstract] [Full Text]
Chui, K. K., Rogers, G. C., Kashina, A. M., Wedaman, K. P., Sharp, D. J., Nguyen, D. T., Wilt, F., Scholey, J. M. (2000). Roles of Two Homotetrameric Kinesins in Sea Urchin Embryonic Cell Division. J. Biol. Chem. 275: 38005-38011 [Abstract] [Full Text]
Emoto, M., Langille, S. E., Czech, M. P. (2001). A Role for Kinesin in Insulin-stimulated GLUT4 Glucose Transporter Translocation in 3T3-L1 Adipocytes. J. Biol. Chem. 276: 10677-10682 [Abstract] [Full Text]
Krylyshkina, O., Kaverina, I., Kranewitter, W., Steffen, W., Alonso, M. C., Cross, R. A., Small, J. V. (2002). Modulation of substrate adhesion dynamics via microtubule targeting requires kinesin-1. JCB 156: 349-360 [Abstract] [Full Text]

This Article

	Abstract
	Full Text (PDF, 651K)
	PPT slides of all figures
	Alert me when this article is cited
	Citation Map

Services

	Email this article
	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new content in the JCB
	Download to citation manager

Citing Articles

	Citing Articles via HighWire
	Citing Articles via CrossRef
	Citing Articles via Google Scholar

Google Scholar

	Articles by Bi, G.-Q.
	Articles by Steinhardt, R. A.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Bi, G.-Q.
	Articles by Steinhardt, R. A.


Social Bookmarking

	What's this?