A Role for Spectrin in Dynactin‐dependent Melanosome Transport in Xenopus laevis Melanophores

The bi‐directional movement of pigment granules in frog melanophores involves the microtubule‐based motors cytoplasmic dynein, which is responsible for aggregation, and kinesin  II and myosin  V, which are required for dispersion of pigment. It was recently shown that dynactin acts as a link between dynein and kinesin  II and melanosomes, but it is not fully understood how this is regulated and if more proteins are involved. Here, we suggest that spectrin, which is known to be associated with Golgi vesicles as well as synaptic vesicles in a number of cells, is of importance for melanosome movements in Xenopus laevis melanophores. Large amounts of spectrin were found on melanosomes isolated from both aggregated and dispersed melanophores. Spectrin and two components of the oligomeric dynactin complex, p150^glued and Arp1/centractin, co‐localized with melanosomes during aggregation and dispersion, and the proteins were found to interact as determined by co‐immunoprecipitation. Spectrin has been suggested as an important link between cargoes and motor proteins in other cell types, and our new data indicate that spectrin has a role in the specialized melanosome transport processes in frog melanophores, in addition to a more general vesicle transport.     

A role for spectrin in dynactin-dependent melanosome transport in Xenopus laevis melanophores

The bi-directional movement of pigment granules in frog melanophores involves the microtubule-based motors cytoplasmic dynein, which is responsible for aggregation, and kinesin II and myosin V, which are required for dispersion of pigment. It was recently shown that dynactin acts as a link between dynein and kinesin II and melanosomes, but it is not fully understood how this is regulated and if more proteins are involved. Here, we suggest that spectrin, which is known to be associated with Golgi vesicles as well as synaptic vesicles in a number of cells, is of importance for melanosome movements in Xenopus laevis melanophores. Large amounts of spectrin were found on melanosomes isolated from both aggregated and dispersed melanophores. Spectrin and two components of the oligomeric dynactin complex, p150(glued) and Arp1/centractin, co-localized with melanosomes during aggregation and dispersion, and the proteins were found to interact as determined by co-immunoprecipitation. Spectrin has been suggested as an important link between cargoes and motor proteins in other cell types, and our new data indicate that spectrin has a role in the specialized melanosome transport processes in frog melanophores, in addition to a more general vesicle transport.     

Regulation of Organelle Movement in Melanophores by Protein Kinase A (PKA), Protein Kinase C (PKC), and Protein Phosphatase 2A (PP2A)

We used melanophores, cells specialized for regulated organelle transport, to study signaling pathways involved in the regulation of transport. We transfected immortalized Xenopus melanophores with plasmids encoding epitope-tagged inhibitors of protein phosphatases and protein kinases or control plasmids encoding inactive analogues of these inhibitors. Expression of a recombinant inhibitor of protein kinase A (PKA) results in spontaneous pigment aggregation. α-Melanocyte-stimulating hormone (MSH), a stimulus which increases intracellular cAMP, cannot disperse pigment in these cells. However, melanosomes in these cells can be partially dispersed by PMA, an activator of protein kinase C (PKC). When a recombinant inhibitor of PKC is expressed in melanophores, PMA-induced pigment dispersion is inhibited, but not dispersion induced by MSH. We conclude that PKA and PKC activate two different pathways for melanosome dispersion. When melanophores express the small t antigen of SV-40 virus, a specific inhibitor of protein phosphatase 2A (PP2A), aggregation is completely prevented. Conversely, overexpression of PP2A inhibits pigment dispersion by MSH. Inhibitors of protein phosphatase 1 and protein phosphatase 2B (PP2B) do not affect pigment movement. Therefore, melanosome aggregation is mediated by PP2A.     

Dynactin is required for bidirectional organelle transport

Kinesin II is a heterotrimeric plus end-directed microtubule motor responsible for the anterograde movement of organelles in various cell types. Despite substantial literature concerning the types of organelles that kinesin II transports, the question of how this motor associates with cargo organelles remains unanswered. To address this question, we have used Xenopus laevis melanophores as a model system. Through analysis of kinesin II-mediated melanosome motility, we have determined that the dynactin complex, known as an anchor for cytoplasmic dynein, also links kinesin II to organelles. Biochemical data demonstrates that the putative cargo-binding subunit of Xenopus kinesin II, Xenopus kinesin II-associated protein (XKAP), binds directly to the p150Glued subunit of dynactin. This interaction occurs through aa 530-793 of XKAP and aa 600-811 of p150Glued. These results reveal that dynactin is required for transport activity of microtubule motors of opposite polarity, cytoplasmic dynein and kinesin II, and may provide a new mechanism to coordinate their activities.     

A Highlights from MBoC Selection: Regulation of microtubule-based transport by MAP4

Microtubule (MT)-based transport of organelles driven by the opposing MT motors kinesins and dynein is tightly regulated in cells, but the underlying molecular mechanisms remain largely unknown. Here we tested the regulation of MT transport by the ubiquitous protein MAP4 using Xenopus melanophores as an experimental system. In these cells, pigment granules (melanosomes) move along MTs to the cell center (aggregation) or to the periphery (dispersion) by means of cytoplasmic dynein and kinesin-2, respectively. We found that aggregation signals induced phosphorylation of threonine residues in the MT-binding domain of the Xenopus MAP4 (XMAP4), thus decreasing binding of this protein to MTs. Overexpression of XMAP4 inhibited pigment aggregation by shortening dynein-dependent MT runs of melanosomes, whereas removal of XMAP4 from MTs reduced the length of kinesin-2–dependent runs and suppressed pigment dispersion. We hypothesize that binding of XMAP4 to MTs negatively regulates dynein-dependent movement of melanosomes and positively regulates kinesin-2–based movement. Phosphorylation during pigment aggregation reduces binding of XMAP4 to MTs, thus increasing dynein-dependent and decreasing kinesin-2–dependent motility of melanosomes, which stimulates their accumulation in the cell center, whereas dephosphorylation of XMAP4 during dispersion has an opposite effect.     

Dynactin polices two-way organelle traffic

How is the bidirectional motion of organelles controlled? In this issue, Deacon et al. (2003) reveal the unexpected finding that dynactin (previously known to control dynein-based motility) binds to kinesin II and regulates anterograde movement of Xenopus melanosomes. This result suggests that dynactin may be a key player in coordinating vesicle traffic in this system.The movement of intracellular cargo is essential for cell survival. In animal cells, membranous organelles are propelled through the cytoplasm by microtubule-based motor proteins. Anterograde movement toward microtubule plus ends at the cell periphery is driven by motor proteins of the kinesin superfamily, whereas retrograde movement toward minus ends at the cell center is largely accomplished by cytoplasmic dynein. In most cells, organelles do not travel smoothly in one direction but frequently switch between plus and minus end–directed travel. The net time spent traveling in the plus versus the minus end direction determines the steady-state distribution of an organelle population within a cell. A long-standing question for those studying organelle transport is how this bidirectional trafficking is coordinated. Is the binding of kinesin and dynein to vesicles mutually exclusive, or are these motors bound at the same time but with their activities coordinately regulated? What molecule(s) might be responsible for linking kinesin and dynein activities? In this issue, Vladimir Gelfand''s group (Deacon et al., 2003) addresses these questions by studying the motor proteins kinesin II and cytoplasmic dynein that move pigment granules in Xenopus melanophore cells. Their results are surprising; the dynactin complex, previously known to bind to cytoplasmic dynein and anchor it to organelles, also interacts with kinesin II and is necessary for plus end–directed motion. The ability of dynactin to physically interact with these two opposite polarity motors suggests that it may be the long sought-after molecular switch that coordinates bidirectional movement in this system.Previous studies hinted that the actions of dynein and kinesin may be controlled via dynactin. Dynactin is a large, multimeric protein complex. Its p150^Glued subunit has binding sites for both microtubules and the intermediate chain of dynein and is thought to be responsible for the association of dynein with many of its cargo organelles (Karki and Holzbaur, 1995; Vaughan and Vallee, 1995; Waterman-Storer et al., 1995). Curiously, the treatment of extruded squid axoplasm with antibodies against p150^Glued inhibited both the anterograde and retrograde movement of organelles along microtubules (Waterman-Storer et al., 1997). These antibodies were known to inhibit the interaction of dynactin with dynein, but their effect on anterograde movement was more difficult to explain. However, genetic studies yielded similar results. Martin et al. (1999) found that mutations in either p150^Glued, the cytoplasmic dynein heavy chain, or kinesin I inhibited both retrograde and anterograde fast axonal transport in Drosophila larvae. This phenotype potentially could be explained by stalled retrograde vesicles sterically blocking the movement of anterograde cargo, but the authors also suggested the possibility of a physical linkage between kinesin, dynein, and dynactin. This theory was further tested by tracking the movement of lipid droplets in Drosophila embryos (Gross et al., 2002b). A mild defect in the dynein heavy chain impaired several aspects of minus end–directed transport of lipid droplets: run lengths, velocities, and the opposing optical trap force required to halt droplet movement were all decreased. Surprisingly, this mutation produced similar effects on droplets moving toward the microtubule plus ends. Embryos expressing a mutant p150^Glued protein that partially impaired dynactin function also exhibited impaired movement in both the plus and minus end directions. Collectively, these results suggested that dynactin might be involved in coordinating the bidirectional movement of organelles. However, these studies did not provide a molecular explanation of how this mechanism might work.To study the mechanism of coordination of bidirectional vesicle movement, Deacon et al. (2003) used Xenopus melanophores due to the unique ability to experimentally control the directional movement of their pigmented melanosomes (Daniolos et al., 1990). Upon treatment of melanophores with melatonin, the cAMP concentration in the cytoplasm drops and the melanosomes move with a net minus end–directed bias and aggregate toward the cell center. Treatment with melanocyte-stimulating hormone (MSH)^* restores cAMP levels, and the melanosomes exhibit a plus end–directed bias and disperse throughout the cell. Aggregation is accomplished by cytoplasmic dynein (Nilsson and Wallin, 1997), whereas dispersion requires the combined actions of kinesin II and the actin-based motor myosin V (Rogers and Gelfand, 1998; Tuma et al., 1998; Gross et al., 2002a). Kinesin II is a heterotrimeric protein consisting of two motor subunits and a third nonmotor subunit known as kinesin-associated protein (KAP) (Cole et al., 1992). KAP is thought to be involved in binding kinesin II to its cargo, although the mechanism for this interaction is not known.The role of dynactin in melanosome transport was investigated by disrupting dynactin function via the overexpression of dynamitin (Echeverri et al., 1996), a crucial subunit that holds the dynactin complex together. To ensure that all observed melanosome movement occurred on the microtubule cytoskeleton, actin filaments were depolymerized with latrunculin B. Here, the authors report that melanosome movement to both the plus and minus ends of microtubules was inhibited by dynamitin overexpression, suggesting a role for dynactin in coordinating bidirectional movement. They considered whether this result might be explained if both kinesin II and dynein bound to dynactin and thereby docked onto membranes. To test this idea, kinesin II was immunoprecipitated with a series of antibodies, and the authors found that dynactin was pulled down along with this kinesin motor in all cases. The reverse experiment of immunoprecipitating with p150^Glued antibodies also brought down kinesin II. Blot overlays of purified melanosomes with p150^Glued detected an interaction with a 115-kD protein, the expected size of Xenopus KAP. Subsequent overlay and affinity pull-down experiments with purified proteins confirmed the direct binding of p150^Glued to KAP. By constructing a series of GST fusion proteins, Deacon et al. (2003) were able to map the site of this interaction to residues 600–811 of p150^Glued and the COOH-terminal domain of KAP. Interestingly, this region of p150^Glued also interacts with the dynein intermediate chain, which raised the question of whether kinesin II and dynein might compete for binding to dynactin. Using a blot overlay competition assay, the authors found that the COOH-terminal KAP domain blocked the binding of p150^Glued to the dynein intermediate chain, whereas the NH₂-terminal KAP domain, used as a control, did not. This result confirms that the two motors cannot bind dynactin simultaneously.If these biochemical results are relevant to melanosome movement, then overexpression of KAP should inhibit both anterograde and retrograde traffic. Indeed, overexpession of Xenopus KAP or just its COOH-terminal fragment inhibited bidirectional melanosome movement. As a control, NH₂-terminal KAP had no effect on retrograde movement and only a small effect on anterograde movement, perhaps due to interactions with the kinesin II motor subunits. Together, the results of Deacon et al. (2003) demonstrate that kinesin II, via its KAP subunit, binds to the p150^Glued subunit of dynactin and that this interaction is important for kinesin II–mediated movement of melanosomes.Although the authors identify the p150^Glued subunit of dynactin as a key player in coordinating the bidirectional movement of melanosomes, the mechanism is still unclear. Their biochemical results showing competitive binding to dynactin suggest that binding of kinesin II and dynein to melanosomes may be mutually exclusive events; however, previous work has shown that this is not the case. In a recent paper from the same authors (Gross et al., 2002a), as well as an earlier study from Reese and Haimo (Reese and Haimo, 2000), the relative amounts of kinesin II and dynein bound to purified melanosomes did not change when cells were treated with melatonin to stimulate aggregation or with MSH to stimulate dispersion. Thus, it is possible that proteins other than dynactin might bind kinesin II and dynein to melanosomes. This question also could be addressed by determining if motor binding to melanophores is diminished in cells overexpressing KAP or dynamitin. Unfortunately, Deacon et al. (2003) were not able to answer this question by biochemical isolation of melanosomes and motor quantitation because transfected cells were only a small percentage of the total population. Another possible model is that dynactin is not needed for recruiting kinesin II and dynein to melanosomes but is somehow involved in regulating the activation or organization of motors already bound to the membrane.Future studies will no doubt explore whether dynactin is involved in bidirectional transport in systems other than melanophores. In intraflagellar transport, kinesin II and cytoplasmic dynein 2 are involved in moving nonmembranous particles between the cell body and the tip of the flagella or cilia (Rosenbaum and Witman, 2002). It will be interesting to determine whether dynactin plays a role in this type of cargo transport. In neurons, kinesin I is responsible for moving organelles from the cell body to the axon terminal. As discussed above, Martin et al. (1999) found that mutations in either kinesin I heavy chain, dynein, or p150^Glued all produced the same phenotype in Drosophila larvae neurons, suggesting that dynactin may play a role in coordinating bidirectional movement in this system as well. Immunoprecipitation of neuronal p150^Glued, however, brought down only dynein but not kinesin I. This finding may result from the fact that kinesin I, which possesses a light chain unrelated to the KAP subunit, could be linked indirectly to dynactin by another protein. Thus, this study by Deacon et al. (2003) has opened up a new area of exploration and dynactin will undoubtedly receive closer scrutiny from kinesin researchers in the future.     

Dynein, dynactin, and kinesin II's interaction with microtubules is regulated during bidirectional organelle transport

The microtubule motors, cytoplasmic dynein and kinesin II, drive pigmented organelles in opposite directions in Xenopus melanophores, but the mechanism by which these or other motors are regulated to control the direction of organelle transport has not been previously elucidated. We find that cytoplasmic dynein, dynactin, and kinesin II remain on pigment granules during aggregation and dispersion in melanophores, indicating that control of direction is not mediated by a cyclic association of motors with these organelles. However, the ability of dynein, dynactin, and kinesin II to bind to microtubules varies as a function of the state of aggregation or dispersion of the pigment in the cells from which these molecules are isolated. Dynein and dynactin bind to microtubules when obtained from cells with aggregated pigment, whereas kinesin II binds to microtubules when obtained from cells with dispersed pigment. Moreover, the microtubule binding activity of these motors/dynactin can be reversed in vitro by the kinases and phosphatase that regulate the direction of pigment granule transport in vivo. These findings suggest that phosphorylation controls the direction of pigment granule transport by altering the ability of dynein, dynactin, and kinesin II to interact with microtubules.     

Organelle transport along microtubules in Xenopus melanophores: evidence for cooperation between multiple motors

Xenopus melanophores have pigment organelles or melanosomes which, in response to hormones, disperse in the cytoplasm or aggregate in the perinuclear region. Melanosomes are transported by microtubule motors, kinesin-2 and cytoplasmic dynein, and an actin motor, myosin-V. We explored the regulation of melanosome transport along microtubules in vivo by using a new fast-tracking routine, which determines the melanosome position every 10 ms with 2-nm precision. The velocity distribution of melanosomes transported by cytoplasmic dynein or kinesin-2 under conditions of aggregation and dispersion presented several peaks and could not be fit with a single Gaussian function. We postulated that the melanosome velocity depends linearly on the number of active motors. According to this model, one to three dynein molecules transport each melanosome in the minus-end direction. The transport in the plus-end direction is mainly driven by one to two copies of kinesin-2. The number of dyneins transporting a melanosome increases during aggregation, whereas the number of active kinesin-2 stays the same during aggregation and dispersion. Thus, the number of active dynein molecules regulates the net direction of melanosome transport. The model also shows that multiple motors of the same polarity cooperate during the melanosome transport, whereas motors of opposite polarity do not compete.     

Regulatory Control of Both Microtubule‐ and Actin‐dependent Fish Melanosome Movement

In fish melanophores, melanosomes can either aggregate around the cell centre or disperse uniformly throughout the cell. This organelle transport involves microtubule‐ and actin‐dependent motors and is regulated by extracellular stimuli that modulate levels of intracellular cyclic adenosine 3‐phosphate (cAMP). We analysed melanosome dynamics in Atlantic cod melanophores under different experimental conditions in order to increase the understanding of the regulation and relative contribution of the transport systems involved. By inhibiting dynein function via injection of inhibitory antidynein IgGs, and modulating cAMP levels using forskolin, we present cellular evidence that dynein is inactivated by increased cAMP during dispersion and that the kinesin‐related motor is inactivated by low cAMP levels during aggregation. Inhibition of dynein further resulted in hyperdispersed melanosomes, which subsequently reversed movement towards a more normal dispersed state, pointing towards a peripheral feedback regulation in maintaining the evenly dispersed state. This reversal was blocked by noradrenaline. Analysis of actin‐mediated melanosome movements shows that actin suppresses aggregation and dispersion, and indicates the possibility of down‐regulating actin‐dependent melanosome movement by noradrenaline. Data from immuno‐electron microscopy indicate that myosinV is associated with fish melanosomes. Taken together, our study presents evidence that points towards a model where both microtubule‐ and actin‐mediated melanosome transport are synchronously regulated during aggregation and dispersion, and this provides a cell physiological explanation behind the exceptionally fast rate of background adaptation in fish.     

The melanosome as a model to study organelle motility in mammals

Melanosomes are lysosome-related organelles within which melanin pigment is synthesized. The molecular motors that allow these organelles to move within melanocytes have been the subject of intense study in several organisms. In mammals, melanosomes travel bi-directionally along microtubule tracks. The anterograde movement, i.e., towards microtubule plus-ends at the periphery, is accomplished by proteins of the kinesin superfamily, whereas the retrograde movement, i.e., towards microtubule minus-ends at the cell center, is achieved by dynein and dynein-associated proteins. At the periphery, melanosomes interact with the actin cytoskeleton via a tripartite complex formed by the small GTPase Rab27a, melanophilin and myosin Va, an actin-based motor. This interaction is essential for the maintenance of a dispersed state of the melanosomes, as shown by the perinuclear clustering of organelles in mutants in any of the referred proteins. In the retinal pigment epithelium, a similar complex formed by Rab27a, a melanophilin homolog called MyRIP and myosin VIIa is probably responsible for the tethering of melanosomes to the actin cytoskeleton. The coordination of motor activities is still poorly characterized, although some models have emerged in recent years and are discussed here. Unraveling regulatory mechanisms responsible for melanosome motility in pigmented cells will provide general insights into organelles dynamics within eukaryotic cells.     

The effect of cytochalasin B on pigment dispersion and aggregation in perfused Xenopus laevis tailfin melanophores

A perfusion technique is described for the study of melanosome response in ventral tailfin melanophores of Xenopus laevis tadpoles. The melanosomes remain aggregated (punctate melanophores) in Ringer's. Theophylline (15 mM) and caffeine (30 mM) cause a reversible dispersion (stellate melanophores) of melanosomes which is partly blocked by cytochalasin B (10 μg/ml). When added with theophylline or caffeine to stellate cells, cytochalasin B causes a disrupted distribution of pigment granules, characterized by a melanosome free central region. C-AMP (20 mM) and dibutyryl c-AMP (1 mM) cause a reversible dispersion of melanosomes which is partly inhibited by cytochalasin. When cytochalasin plus a nucleotide are added to stellate cells, some show the disrupted distribution of melanosomes. Colchicine (5 mM) causes irreversible, while griseofulvin (0.2 mM) causes a slight, but reversible dispersion of melanosomes, and cytochalasin has little effect on these reactions. Perfused tailfin melanophores remain capable of responding to reversible reagents for at least 12 hours and are unresponsive to changes in illumination.     

Statistics of active transport in Xenopus melanophores cells

The transport of cell cargo, such as organelles and protein complexes in the cytoplasm, is determined by cooperative action of molecular motors stepping along polar cytoskeletal elements. Analysis of transport of individual organelles generated useful information about the properties of the motor proteins and underlying cytoskeletal elements. In this work, for the first time (to our knowledge), we study collective movement of multiple organelles using Xenopus melanophores, pigment cells that translocate several thousand of pigment granules (melanosomes), spherical organelles of a diameter of ∼1 μm. These cells disperse melanosomes in the cytoplasm in response to high cytoplasmic cAMP, while at low cAMP melanosomes cluster at the cell center. Obtained results suggest spatial and temporal organization, characterized by strong correlations between movement of neighboring organelles, with correlation length of ∼4 μm and pair lifetime ∼5 s. Furthermore, velocity statistics revealed strongly non-Gaussian velocity distribution with high velocity tails demonstrating exponential behavior suggestive of strong velocity correlations. Depolymerization of vimentin intermediate filaments using a dominant-negative vimentin mutant or actin with cytochalasin B reduced correlation of behavior of individual particles. Based on our analysis, we concluded that steric repulsion is dominant, but both intermediate filaments and actin microfilaments are involved in dynamic cross-linking organelles in the cytoplasm.     

Melanoregulin, Product of the dsu Locus, Links the BLOC-Pathway and Oa1 in Organelle Biogenesis

Humans with Hermansky-Pudlak Syndrome (HPS) or ocular albinism (OA1) display abnormal aspects of organelle biogenesis. The multigenic disorder HPS displays broad defects in biogenesis of lysosome-related organelles including melanosomes, platelet dense granules, and lysosomes. A phenotype of ocular pigmentation in OA1 is a smaller number of macromelanosomes, in contrast to HPS, where in many cases the melanosomes are smaller than normal. In these studies we define the role of the Mreg^dsu gene, which suppresses the coat color dilution of Myo5a, melanophilin, and Rab27a mutant mice in maintaining melanosome size and distribution. We show that the product of the Mreg^dsu locus, melanoregulin (MREG), interacts both with members of the HPS BLOC-2 complex and with Oa1 in regulating melanosome size. Loss of MREG function facilitates increase in the size of micromelanosomes in the choroid of the HPS BLOC-2 mutants ruby, ruby2, and cocoa, while a transgenic mouse overexpressing melanoregulin corrects the size of retinal pigment epithelium (RPE) macromelanosomes in Oa1^ko/ko mice. Collectively, these results suggest that MREG levels regulate pigment incorporation into melanosomes. Immunohistochemical analysis localizes melanoregulin not to melanosomes, but to small vesicles in the cytoplasm of the RPE, consistent with a role for this protein in regulating membrane interactions during melanosome biogenesis. These results provide the first link between the BLOC pathway and Oa1 in melanosome biogenesis, thus supporting the hypothesis that intracellular G-protein coupled receptors may be involved in the biogenesis of other organelles. Furthermore these studies provide the foundation for therapeutic approaches to correct the pigment defects in the RPE of HPS and OA1.     

Localization of the Kinesin-like Protein Xklp2 to Spindle Poles Requires a Leucine Zipper,a Microtubule-associated Protein,and Dynein

Xklp2 is a plus end–directed Xenopus kinesin-like protein localized at spindle poles and required for centrosome separation during spindle assembly in Xenopus egg extracts. A glutathione-S-transferase fusion protein containing the COOH-terminal domain of Xklp2 (GST-Xklp2-Tail) was previously found to localize to spindle poles (Boleti, H., E. Karsenti, and I. Vernos. 1996. Cell. 84:49–59). Now, we have examined the mechanism of localization of GST-Xklp2-Tail. Immunofluorescence and electron microscopy showed that Xklp2 and GST-Xklp2-Tail localize specifically to the minus ends of spindle pole and aster microtubules in mitotic, but not in interphase, Xenopus egg extracts. We found that dimerization and a COOH-terminal leucine zipper are required for this localization: a single point mutation in the leucine zipper prevented targeting. The mechanism of localization is complex and two additional factors in mitotic egg extracts are required for the targeting of GST-Xklp2-Tail to microtubule minus ends: (a) a novel 100-kD microtubule-associated protein that we named TPX2 (Targeting protein for Xklp2) that mediates the binding of GST-Xklp2-Tail to microtubules and (b) the dynein–dynactin complex that is required for the accumulation of GST-Xklp2-Tail at microtubule minus ends. We propose two molecular mechanisms that could account for the localization of Xklp2 to microtubule minus ends.     

Anomalous Dynamics of Melanosomes Driven by Myosin-V in Xenopus laevis Melanophores

The organization of the cytoplasm is regulated by molecular motors, which transport organelles and other cargoes along cytoskeleton tracks. In this work, we use single particle tracking to study the in vivo regulation of the transport driven by myosin-V along actin filaments in Xenopus laevis melanophores. Melanophores have pigment organelles or melanosomes, which, in response to hormones, disperse in the cytoplasm or aggregate in the perinuclear region. We followed the motion of melanosomes in cells treated to depolymerize microtubules during aggregation and dispersion, focusing the analysis on the dynamics of these organelles in a time window not explored before to our knowledge. These data could not be explained by previous models that only consider active transport. We proposed a transport-diffusion model in which melanosomes may detach from actin tracks and reattach to nearby filaments to resume the active motion after a given time of diffusion. This model predicts that organelles spend ∼70% and 10% of the total time in active transport during dispersion and aggregation, respectively. Our results suggest that the transport along actin filaments and the switching from actin to microtubule networks are regulated by changes in the diffusion time between periods of active motion driven by myosin-V.     

Height Changes Associated with Pigment Aggregation in <Emphasis Type="Italic">Xenopus laevis</Emphasis> Melanophores

Melanophores are pigment cells found in the skin of lower vertebrates. The brownish-black pigment melanin is stored in organelles called melanosomes. In response to different stimuli, the cells can redistribute the melanosomes, and thereby change colour. During melanosome aggregation, a height increase has been observed in fish and frog melanophores across the cell centre. The mechanism by which the cell increases its height is unknown. Changes in cell shape can alter the electrical properties of the cell, and thereby be detected in impedance measurements. We have in earlier studies of Xenopus laevis melanophores shown that pigment aggregation can be revealed as impedance changes, and therefore we were interested in investigating the height changes associated with pigment aggregation further. Accordingly, we quantified the changes in cell height by performing vertical sectioning with confocal microscopy. In analogy with theories explaining the leading edge of migrating cells, we investigated the possibility that the elevation of plasma membrane is caused by local swelling due to influx of water through HgC1₂-sensitive aquaporins. We also measured the height of the microtubule structures to assess whether they are involved in the height increase. Our results show that pigment aggregation in X. laevis melanophores resulted in a significant height increase, which was substantially larger when aggregation was induced by latrunculin than with melatonin. Moreover, the elevation of the plasma membrane did not correlate with influx of water through aquaporins or formation of new microtubules, Rather, the accumulation of granules seemed to drive the change in cell height.     

Interactions and regulation of molecular motors in Xenopus melanophores

Many cellular components are transported using a combination of the actin- and microtubule-based transport systems. However, how these two systems work together to allow well-regulated transport is not clearly understood. We investigate this question in the Xenopus melanophore model system, where three motors, kinesin II, cytoplasmic dynein, and myosin V, drive aggregation or dispersion of pigment organelles called melanosomes. During dispersion, myosin V functions as a "molecular ratchet" to increase outward transport by selectively terminating dynein-driven minus end runs. We show that there is a continual tug-of-war between the actin and microtubule transport systems, but the microtubule motors kinesin II and dynein are likely coordinated. Finally, we find that the transition from dispersion to aggregation increases dynein-mediated motion, decreases myosin V--mediated motion, and does not change kinesin II--dependent motion. Down-regulation of myosin V contributes to aggregation by impairing its ability to effectively compete with movement along microtubules.     

Dynamics of the redistribution of pigment granules in the dermal melanophores of anuran amphibians. 1. Dispersion

The dispersion of melanosomes in the dermal melanophores of the Xenopus laevis larvae has been studied by time--lapse cinematography. The process began with the appearance of distally directed melanosome flows in the cell cytoplasm. During the subsequent migration of pigment granules, the flows branched forming branches of the 2nd and higher orders. The whole cytoplasm became filled with a layer of melanosomes. During the dispersion, the movement of melanosomes in a flow is replaced by their dispersion all over the cytoplasm; these processes alternated. In the peripheral part of the cell devoid of melanosomes, membrane vesicles appeared and the cytoplasm was distinctly divided into ecto- and endoplasm. The ectoplasm contained numerous microfilaments and single microtubules, the endoplasm did not contain any cell organelles, except single electron-dense melanosomes. The active role of plasma membrane in the intracellular movement of melanin granules is suggested.     

Protein kinase A, which regulates intracellular transport, forms complexes with molecular motors on organelles

Major signaling cascades have been shown to play a role in the regulation of intracellular organelle transport . Aggregation and dispersion of pigment granules in melanophores are regulated by the second messenger cAMP through the protein kinase A (PKA) signaling pathway ; however, the exact mechanisms of this regulation are poorly understood. To study the role of signaling molecules in the regulation of pigment transport in melanophores, we have asked the question whether the components of the cAMP-signaling pathway are bound to pigment granules and whether they interact with molecular motors to regulate the granule movement throughout the cytoplasm. We found that purified pigment granules contain PKA and scaffolding proteins and that PKA associates with pigment granules in cells. Furthermore, we found that the PKA regulatory subunit forms two separate complexes, one with cytoplasmic dynein ("aggregation complex") and one with kinesin II and myosin V ("dispersion complex"), and that the removal of PKA from granules causes dissociation of dynein and disruption of dynein-dependent pigment aggregation. We conclude that cytoplasmic organelles contain protein complexes that include motor proteins and signaling molecules involved in different components of intracellular transport. We propose to call such complexes 'regulated motor units' (RMU).     

Pigment movements in fish melanophores: Morphological and physiological studies

Summary Cyclic adenosine monophosphate (cAMP) has been shown to cause pigment dispersion in amphibian and fish melanophores. Since pigment displacements in melanophores of Pterophyllum scalare are known to be accompanied by assembly and disassembly of microtubules, the effect of cAMP on this process was investigated. Melanophores of isolated scales were treated with cAMP in the presence of vinblastine, a potent antimicrotubular agent. During the initial phase of vinblastine action, cAMP as well as its dibutyryl derivative are capable of counteracting the inhibitory effects of vinblastine on pigment dispersion. In addition, cAMP retains the velocity of pigment dispersion at about the maximum level during 1 hour experiments. Pigment aggregation was unaffected by cAMP. Since pigment dispersion in Pterophyllum-melanophores is accompanied by assembly of microtubules, it is concluded that cAMP influences, at least in part, melanosome dispersion through facilitation of microtubule assembly.