Chromatophores--models for studying cytomatrix translocations

Sleep and cargo reorganization: A hypothesis

Several molecules that act in the nervous system to regulate sleep and wake were first identified based on their transport effects in pigmented cells. I compiled a list of such molecules like melatonin, melanin-concentrating hormone, and pigment dispersing factor, etc. Molecules that induce pigment aggregation promote sleep whereas molecules that induce pigment dispersal promote wake. I call these Sleep and PIgment Regulating Factors SPIRFs. SPIRFs regulate organelle trafficking in both pigmentary models and neurons. I propose that cargo transport fulfills necessary sleep functions such as remodeling synapses and restoring homeostasis in the distribution of cell components. I put forth the hypothesis that sleep-promoting SPIRFs induce states of increased cargo movement towards the cell body, and propose that this function is a critical neuron maintenance task for which animals must sleep.

How the zebrafish gets its stripes

The study of vertebrate pigment patterns is a classic and enduring field of developmental biology. Knowledge of pigment pattern development comes from a variety of systems, including avians, mouse, and more recently, the zebrafish (Danio rerio). Recent analyses of the mechanisms underlying the development of the neural crest-derived pigment cell type common to all vertebrates, the melanocyte, have revealed remarkable similarities and several surprising differences between amniotes and zebrafish. Here, we summarize recent advances in the study of melanocyte development in zebrafish, with reference to human, mouse, and avian systems. We first review melanocyte development in zebrafish and mammals, followed by a summary of the molecules known to be required for their development. We then discuss several relatively unaddressed issues in vertebrate pigment pattern development that are being investigated in zebrafish. These include determining the relationships between genetically distinct classes of melanocytes, characterizing and dissecting melanocyte stem cell development, and understanding how pigment cells organize into a patterned tissue. Further analysis of zebrafish pigment pattern mutants as well as new generations of directed mutant screens promise to extend our understanding of pigment pattern morphogenesis.

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. alpha-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.

Effect of cisplatin and ACTH4-9 on neural transport in cisplatin induced neurotoxicity

Cisplatin causes a dose limiting peripheral neuropathy, however, the biological mechanism by which this occurs is unknown. Murine N1E.115 neuroblastoma cells and neural crest derived pigment cells have similar transport mechanisms to human neural cells and were used to study the effect of cisplatin on cellular transport. Cisplatin reduced both the number and velocity of organelles moving in the anterograde and retrograde direction, compared to control cells. Cisplatin induced inhibition of transport was prevented by the simultaneous administration of ACTH4-9. This analog alone had no effect on N1E.115 organelle, or erythrophore granule, movement. In both N1E.115 and pigment cells cisplatin inhibited transport within 1 h of exposure to the drug. The degree of inhibition did not increase insignificantly if pigment cells were incubated in cisplatin for 48 h compared to acute exposure. Microtubules in both pigment cells and N1E.115 neurites retained their structural integrity suggesting that factors other than changes in gross microtubule morphology are responsible for cisplatin neurotoxicity. Cisplatin reduces N1E.115 neurite growth after 48 h incubation but this can be prevented by simultaneous use of ACTH4-9. This study demonstrates for the first time that cisplatin and ACTH4-9 affect fast axonal transport by specific mechanisms which appear related to their observed neurotoxic and neuroprotective roles, respectively.

Intracellular calcium and cAMP regulate directional pigment movements in teleost erythrophores

Teleost pigment cells (erythrophores and melanophores) are useful models for studying the regulation of rapid, microtubule-dependent organelle transport. Previous studies suggest that melanophores regulate the direction of pigment movements via changes in intracellular cAMP (Rozdzial and Haimo, 1986a; Sammak et al., 1992), whereas erythrophores may use calcium- (Ca(2+)-) based regulation (Luby-Phelps and Porter, 1982; McNiven and Ward, 1988). Despite these observations, there have been no direct measurements in intact erythrophores or any cell type correlating changes of intracellular free Ca2+ ([Ca2+]i) with organelle movements. Here we demonstrate that extracellular Ca2+ is necessary and that a Ca2+ influx via microinjection is sufficient to induce pigment aggregation in erythrophores, but not melanophores of squirrel fish. Using the Ca(2+)-sensitive indicator, Fura-2, we demonstrate that [Ca2+]i rises dramatically concomitant with aggregation of pigment granules in erythrophores, but not melanophores. In addition, we find that an erythrophore stimulated to aggregate pigment will immediately transmit a rise in [Ca2+]i to neighboring cells, suggesting that these cells are electrically coupled. Surprisingly, we find that a fall in [Ca2+]i is not sufficient to induce pigment dispersion in erythrophores, contrary to the findings obtained with the ionophore and lysed-cell models (Luby-Phelps and Porter, 1982; McNiven and Ward, 1988). We find that a rise in intracellular cAMP ([cAMP]i) induces pigment dispersion, and that this dispersive stimulus can be overridden by an aggregation stimulus, suggesting that both high [cAMP]i and low [Ca2+]i are necessary to produce pigment dispersion in erythrophores.

Characterization of a serotonin receptor endogenous to frog melanophores

The response of a cell line of Xenopus laevis melanophores to serotonin was examined. Serotonin increased intracellular levels of cAMP and induced pigment dispersion in the cells. The responses depended on both the concentration of serotonin applied and on the time for which the cells were exposed to serotonin. Using a recently described, microtiter-plate-based bioassay, a series of serotonin receptor ligands were evaluated as agonists or antagonists at the melanophore serotonin receptor. The pharmacological profile suggests the presence of a receptor which shares some properties with but appears different from other previously described serotonin receptors.

A paradigm for examining toxicant effects on viability, structure, and axonal transport of neurons in culture

N1E.115 murine neuroblastoma cells differentiating in serum-free medium were used to develop a paradigm for testing neurotoxicity in vitro. The paradigm was designed to test the effects of toxicants on four different aspects of cell function or structure: 1. Viability as shown by the retention of cellular radiolabel (51Cr); 2. Growth and maintenance of neurites as reflected by the incidence and average length of these processes; 3. Gross structure of neurites; and 4. Velocity and flux of rapid anterograde and retrograde axonal transport as judged by video-enhanced differential interference contrast microscopy. To evaluate this paradigm, colchicine and vinblastine were used as neurotoxicants with a well-understood mechanism of action. These agents were only weakly cytotoxic according to the Cr-release assay, but were able to interfere with neurite outgrowth at nanomolar concentrations. Neurites that were elaborated in the presence of vinblastine and colchicine were often disfigured by numerous swellings packed with organelles. In established neurites, micromolar concentrations of vinblastine inhibited organellar motility with great rapidity, blocking all signs of transport within 20 min. The effect of colchicine was slower and less complete, but still impressive. We suggest that this four-part analysis represents a highly sensitive in vitro test for neurotoxicity, and a means of analyzing the relation between abnormalities of transport and structural damage of nerve cells.

Probing the role of nonmuscle tropomyosin isoforms in intracellular granule movement by microinjection of monoclonal antibodies

Chicken embryo fibroblast (CEF) cells were microinjected with several different monoclonal antibodies that recognize certain nonmuscle isoforms of tropomyosin. Immediately after injection, cells were recorded with a time-lapse video imaging system; later analysis of the tapes revealed that particles in cells injected with one of these antibodies (CG1, specific for CEF tropomyosin isoforms 1 and 3) showed a dramatic decrease in instantaneous speed while moving, distance moved per saltation, and proportion of time spent in motion. Injection of Fab fragments of CG1 resulted in similar changes in the pattern of granule movement. This inhibition of granule movement by CG1 antibody was reversible; at 2.5 h after injection, granules in injected cells had already reached three-fourths of normal speed. The speed of granule movement in cells injected either with antibody specific for tropomyosin isoforms not present in CEF cells, or with CG1 antibody preabsorbed with tropomyosin, was not significantly different from the speed of granules in uninjected cells. When cells were injected with CG1 or Fab fragments of CG1, fixed, and counter-stained with rabbit antibodies to reveal the microtubule, microfilament, and intermediate filament systems, no obvious differences from the patterns normally seen in uninjected cells were observed. Examination of the ultrastructure of injected cells by EM confirmed the presence of apparently intact and normal microtubule, actin, and intermediate filament networks. These experiments suggest that tropomyosin may play an important role in the movement of vesicles and organelles in the cell cytoplasm. Also, we have shown previously that the CG1 determinant can undergo a motility-dependent change in reactivity, that may be important for the regulatory function of nonmuscle tropomyosin (Hegmann, T. E., J. L.-C. Lin, and J. J.-C. Lin. 1988. J. Cell Biol. 106:385-393). Therefore, in addition to postulated microtubule-based motors, microfilaments may play a critical role in regulating granule movement in nonmuscle cells.

Rearrangements of pterinosomes and cytoskeleton accompanying pigment dispersion in goldfish xanthophores

The cytoskeleton of goldfish xanthophores contains an abundance of unique dense structures (400 nm in diameter) that are absent in goldfish nonpigment cells and are probably remnants of pterinosomes. No major difference in protein composition between xanthophores and nonpigment cells (without these structures) was found that could account for these structures. In xanthophores, these structures are foci of radiating filaments. The addition or withdrawal of ACTH causes a radical rearrangement of the xanthophore cytoskeleton accompanying redistribution of carotenoid droplets, namely, the virtual exclusion of these dense bodies with associated filaments from the space occupied by the carotenoid droplet aggregate vs. a relatively even cytoplasmic distribution of these structures when the carotenoid droplets are dispersed. These changes in cytoskeletal morphology are not accompanied by any major changes in the protein or phosphoprotein composition of the cytoskeleton.

Calcium regulation of pigment transport in vitro

Calcium has been implicated in the regulation of many cellular motility events. In this study we have examined the role of different Ca2+ concentrations on the in vitro transport of pigment within cultured chromatophores. Cells treated with Brij detergent for 1-2 min were stripped of their plasma membranes, leaving their cytoskeleton and associated pigment granules exposed to the external milieu. We found that retrograde pigment transport (aggregation) is induced upon addition of 1 mM MgATP2- with 10(-7) M free Ca2+, while an orthograde transport (redispersal) of pigment results from lowering the concentration of free Ca2+ to 10(-8) M while maintaining 1 mM MgATP2-. These Ca2+-regulated movements are ATP dependent but are apparently independent of cAMP and insensitive to calmodulin inhibitors. The observations reported here provide novel evidence that the concentration of free Ca2+ acts to regulate the direction of intracellular organelle transport.

Cultured cell extracts support organelle movement on microtubules in vitro

Directed movements of organelles have been observed in a variety of cultured cells. To study the regulation and molecular basis of intracellular organelle motility, we have prepared extracts from cultured chick embryo fibroblasts (CEF cells) which support the movement of membraneous organelles along microtubules. The velocity, frequency and characteristics of organelle movements in vitro were similar to those within intact cells. Organelles and extract-coated anionic beads moved predominantly (80%) toward the minus ends of microtubules that had been regrown from centrosomes, corresponding to retrograde translocation. Similar microtubule-dependent organelle movements were observed in extracts prepared from other cultured cells (African green monkey kidney and 3T3 cells). Organelle motility was ATP and microtubule dependent. The frequency of organelle movement was inhibited by acidic (pH less than 7) or alkaline (pH greater than 8) solutions, high ionic strength ([ KCl] = 0.1 M), and the chelation of free magnesium ions. Treatment of the extracts with adenylyl imidodiphosphate (AMP-PNP, 7 mM), sodium orthovanadate (vanadate; Na3VO4, 20 microM), or N-ethylmaleimide (NEM, 2 mM) blocked all organelle motility. The decoration of microtubules with organelles was observed in the presence of AMP-PNP or vanadate. Motility was not affected by cytochalasin D (2 microM) or cAMP (1 mM). Kinesin (Mr = 116,000), an anterograde microtubule-based motor, was partially purified from the CEF extract by microtubule affinity purification in the presence of AMP-PNP, and was able to drive the movement of microtubule on glass coverslips. A similar preparation made in the presence of vanadate contained a different subset of proteins and did not support motility. These results demonstrate that intracellular organelle motility can be reproduced in vitro and provide the basis for investigating the roles of individual molecular components involved in the organelle motor complex.

Evidence that MAP-2 may be involved in pigment granule transport in squirrel fish erythrophores

We have demonstrated the presence of MAP-2 in squirrel fish erythrophores using SDS-PAGE, immunoblot, and immunoprecipitation techniques. The monoclonal antibodies used (AP-9, -13, -14) were raised against distinct antigenic sites on Chinese hamster brain MAP-2. Immunoprecipitation studies demonstrated that all three antibodies bind a 300 K protein found in crude cell extracts and in partially purified MAP fractions isolated from erythrophores of the squirrel fish Holocentrus rufus. Immunofluorescent studies confirmed that the 300 K protein was present in cultured erythrophores. Studies of cells induced to aggregate and disperse their pigment granules revealed that the 300 K protein comigrated with the pigment, suggesting that the 300 K protein may constitute part of the "alpha-cytomatrix" involved in pigment translocations.

Reactivated melanophore motility: differential regulation and nucleotide requirements of bidirectional pigment granule transport

To study the molecular basis for organized pigment granule transport, procedures were developed to lyse melanophores of Tilapia mossambica under conditions in which pigment granule movements could be reactivated. Gentle lysis of the melanophores resulted in a permeabilized cell model, which, in the absence of exogenous ATP, could undergo multiple rounds of pigment granule aggregation and dispersion when sequentially challenged with epinephrine and cAMP. Both directions of transport required ATP, since aggregation or dispersion in melanophores depleted of nucleotides could be reactivated only upon addition of MgATP or MgATP plus cAMP, respectively. Differences between the nucleotide sensitivities for aggregation and dispersion were demonstrated by observations that aggregation had a lower apparent Km for ATP than did dispersion and could be initiated at a lower ATP concentration. Moreover, aggregation could be initiated by ADP, but only dispersion could be reactivated by the thiophosphate ATP analog, ATP gamma S. The direction of pigment transport was determined solely by cAMP, since pigment granules undergoing dispersion reaggregated when cAMP was removed, and those undergoing aggregation dispersed when cAMP was added. These results provide evidence that pigment granule motility may be based on two distinct mechanisms that are differentially activated and regulated to produce bidirectional movements.

Mechanistic aspects on chemical induction of spindle disturbances and abnormal chromosome numbers

Work on the chemical induction of spindle disturbances and abnormal chromosome numbers, and work on the composition and biochemistry of the spindle are reviewed. Some early investigations have shown that there is an unspecific mechanism for chemical induction of spindle disturbances. This mechanism is based on the interaction of compounds with cellular hydrophobic compartments. Some compounds act differently and are more active than predicted from their lipophilic character. Selected compounds of that kind and their possible mechanisms of action are discussed. Changes in sulfhydryl and ATP levels, oxidative damage of membranes and impaired control of cytoplasmic Ca2+ levels are discussed in this context.

Polarized microtubule gliding and particle saltations produced by soluble factors from sea urchin eggs and embryos

In this report, we describe an in vitro system for analyzing microtubule-based movements in supernatants of sea urchin egg and embryo homogenates. Using video enhanced DIC microscopy, we have observed bidirectional saltatory particle movements on native taxol-stabilized microtubules assembled in low speed supernatants of Lytechinus egg homogenates, and gliding of these microtubules across a glass surface. A high speed supernatant of soluble proteins, depleted of organelles, microtubules, and their associated proteins supports the gliding of exogenous microtubules and translocation of polystyrene beads along these microtubules. The direction of microtubule gliding has been determined directly by observation of the gliding of flagellar axonemes in which the (+) and (-) ends could be distinguished by biased polar growth of microtubules off the ends. Microtubule gliding is toward the (-) end of the microtubule, is ATP sensitive, and inhibited only by high concentrations of vanadate. These characteristics suggest that the transport complex responsible for microtubule gliding in S2 is kinesin-like. The implications of these molecular interactions for mitosis and other motile events are discussed.

Changes in levels of polymeric tubulin associated with activation and dorsoventral polarization of the frog egg

The level of polymeric tubulin was measured during the first cell cycle of the electrically activated and the fertilized egg of Xenopus laevis. Eggs were homogenized in a microtubule-stabilizing medium, and the amount of tubulin pelleted by centrifugation was determined by quantitative Western blots. The pelleted tubulin (polymer) was in the form of microtubules based on the presence of microtubules in the pellet and on the effects of cold, nocodazole, and D2O. Unactivated eggs had a high level of polymer (greater than 0.1 microgram/egg) which disappeared within minutes of activation. The level of polymer stayed low (less than 0.02 microgram/egg) until halfway through the cell cycle (0.5 on a normalized time scale) when the level rose to the preactivation value. There was a decrease associated with metaphase (0.85 normalized time) and a return to a high level at first cleavage (1.0 normalized time). Fertilized eggs showed a similar pattern although the amount of polymer increased earlier (0.3-0.5 normalized time), presumably due to the spermaster. The depolymerization of microtubules at activation indicates that there is a dramatic change of the cytoskeleton at this time. The polymerization at 0.5 normalized time coincides with the start of the cytoplasmic shift leading to dorsoventral polarity. This result, together with previous inhibitor studies, shows that microtubules are involved in dorsoventral polarization of the embryo.