Actin and Tubulin Arrays in Cultured Xenopus Melanophores Responding to Melatonin

Melatonin induces pigment granule aggregation in amphibian melanophores. In the studies reported here, we have used fluorescence microscopic techniques to test the hypothesis that such melatonin-induced pigment movement is correlated with alterations in either the actin or tubulin cytoskeletal patterns of cultured Xenopus melanophores. In general, the cytoplasmic domains of the cultured melanophores were flat and thin except in the perinuclear region (especially when the pigment was aggregated). The microtubules and microfilaments were usually found in the same focal plane; however, on occasion, microfilaments were closer to the substratum. Microtubules were arranged in arrays radiating from what are presumed to be cytocenters. A small percentage of the melanophores were very large, had actin-rich circular perimeters and did not respond as rapidly to melatonin treatment as did the other melanophores. Melanophores with either aggregated or dispersed melanosomes had low intensity rhodamine-phalloidin staining of actin filaments compared to nonpigmented cells, whereas the FITC anti-tubulin intensities were comparable in magnitude to that seen in nonpigmented cells. When cells were fixed prior to complete melatonin-induced pigment granule aggregation there was no abrupt diminution in either the tubulin or actin staining at the boundary between pigment granule-rich and pigment granule-poor cytoplasmic domains. Nor could the actin and tubulin patterns in cells with partially aggregated melanosomes be reliably distinguished from those in melanophores in which the melanosomes were either completely dispersed or completely aggregated. These data argue against the hypothesis that melatonin causes consistent large-scale rearrangements of tubulin and actin polymers as it induces pigment aggregation in Xenopus melanophores.     

Effects of acrylamide, latrunculin, and nocodazole on intracellular transport and cytoskeletal organization in melanophores

The effects of acrylamide (ACR), nocodazole, and latrunculin were studied on intracellular transport and cytoskeletal morphology in cultured Xenopus laevis melanophores, cells that are specialized for regulated and bidirectional melanosome transport. We used three different methods; light microscopy, fluorescence microscopy, and spectrophotometry. ACR affected the morphology of both microtubules and actin filaments in addition to inhibiting retrograde transport of melanosomes but leaving dispersion unaffected. Using the microtubule-inhibitor nocodazole and the actin filament-inhibitor latrunculin we found that microtubules and actin filaments are highly dependent on each other, and removing either component dramatically changed the organization of the other. Both ACR and latrunculin induced bundling of microtubules, while nocodazole promoted formation of filaments resembling stress fibers organized from the cell center to the periphery. Removal of actin filaments inhibited dispersion of melanosomes, further concentrated the central pigment mass in aggregated cells, and induced aggregation even in the absence of melatonin. Nocodazole, on the other hand, prevented aggregation and caused melanosomes to cluster and slowly disperse. Dispersion of nocodazole-treated cells was induced upon addition of alpha-melanocyte-stimulating hormone (MSH), showing that dispersion can proceed in the absence of microtubules, but the distribution pattern was altered. It is well established that ACR has neurotoxic effects, and based on the results in the present study we suggest that ACR has several cellular targets of which the minus-end microtubule motor dynein and the melatonin receptor might be involved. When combining morphological observations with qualitative and quantitative measurements of intracellular transport, melanophores provide a valuable model system for toxicological studies.     

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.     

Distribution of polyglutamylated tubulin in the flagellar apparatus of green flagellates

Polyglutamylation is a widely distributed posttranslational modification of tubulin that can be demonstrated either by biochemical analysis or by the use of specific antibodies like GT335. Western blotting using GT335 demonstrated that polyglutamylated tubulin is enriched in isolated basal apparatus of Spermatozopsis similis. Single- and double-labeling experiments, using indirect immunofluorescence and immunogold electron microscopy of isolated cytoskeletons of S. similis and Chlamydomonas reinhardtii, revealed that polyglutamylated tubulin was predominately present in the basal bodies and the proximal part of the axonemes. Using immunogold labeling of whole mounts of Spermatozopsis cytoskeletons, we obtained evidence for a predominant occurrence of polyglutamylated tubulin in the B-tubule of the axonemal doublets. Polyglutamylation occurs early during premitotic basal body assembly in S. similis, whereas the probasal bodies of Chlamydomonas, which are present through interphase, showed a reduced staining with GT335 indicating that polyglutamylation is involved in basal body maturation. During flagella regeneration of C. reinhardtii, polyglutamylation preceded detyrosination and became visible shortly after the onset of flagellar regeneration. In C. reinhardtii and S. similis polyglutamylated tubulin was absent or highly reduced in the flagellar transition region, a specialized part of the flagellum linking the basal body to the axoneme. Furthermore, the transition region and the neighboring part of the axoneme showed reduced staining with L3, an antibody directed against detyrosinated tubulin. The results indicate that differences in the modification pattern can occur in a confined area of individual microtubules. The deficiency of polyglutamylated and detyrosinated tubulin in the transition region could have functional implications for flagellar turnover or excision.     

Interaction of STOP with neuronal tubulin is independent of polyglutamylation

In eukaryotes, the coordinated progress of the various cellular tasks along with the assembly of adapted cytoskeletal networks requires a tight regulation of the interactions between microtubules and their associated proteins. Polyglutamylation is the major post-translational modification of neuronal tubulin. Due to its oligomeric structure, polyglutamylation can serve as a potentiometer to modulate binding of diverse MAPs. In addition, it can exert a differential mode of regulation towards distinct microtubule protein partners. To find out to what extent polyglutamylation is a general regulator, we have analyzed its ability to affect the binding of STOPs, the major factors that confer cold- and nocodazole-resistance to microtubules. We have shown by blot overlay experiments that binding of STOP does not depend on the length of the polyglutamyl chains carried by tubulins. And contrary to the other microtubule-associated proteins tested so far, STOP can bind quantitatively to any tubulin isoform whatever its degree of polyglutamylation.     

In vitro reconstitution of fish melanophore pigment aggregation

Movement and positioning of melanophore pigment organelles depend on microtubule- and actin-dependent motors, but the regulation of these forces are poorly understood. Here, we describe a cell free and fixed time motility assay for the study of the regulation of microtubule-dependent pigment organelle positioning in vitro. The assay involves introduction of microtubule-asters assembled in clam oocyte lysates into lysates prepared from Fundulus heteroclitus melanophores with either aggregated or dispersed pigment. When asters were introduced in lysates prepared from melanophores with dispersed pigment, pigment organelles bound astral microtubules and were evenly distributed throughout the aster. In contrast, when asters were introduced into lysates prepared from melanophores with aggregated pigment, pigment organelles accumulated around the centrosome, mimicking a pigment aggregate. The addition of anti-dynein intermediate chain antibody (m74-1), previously shown to interfere with binding of dynactin to dynein and thereby causing detachment of dynein from organelles, blocked the ATP-dependent aggregation of pigment in vitro and induced a depletion of pigment from the centrosomal area. The results show that dynein is essential for pigment aggregation and involved in maintenance of evenly dispersed pigment in vitro, analogous to cellular evidence, and suggest a possible role for dynactin in these processes as well.     

Molecular Mechanisms of Pigment Transport in Melanophores

We present an overview of the research on intracellular transport in pigment cells, with emphasis on the most recent discoveries. Pigment cells of lower vertebrates have been traditionally used as a model for studies of intracellular transport mechanisms, because these cells transport pigment organelles to the center or to the periphery of the cell in a highly co-ordinated fashion. It is now well established that both aggregation and dispersion of pigment in melanophores require two elements of the cytoskeleton: microtubules and actin filaments. Melanosomes are moved along these cytoskeletal tracks by motor proteins. Recent studies have identified the motors responsible for pigment dispersion and aggregation in melanophores. We propose a model for the possible roles of the two cytoskeletal transport systems and how they might interact. We also discuss the putative mechanisms of regulation of pigment transport, especially phosphorylation. Last, we suggest areas of research that will receive attention in the future in order to elucidate the mechanisms of organelle transport.     

Molecular mechanisms of pigment transport in melanophores.

We present an overview of the research on intracellular transport in pigment cells, with emphasis on the most recent discoveries. Pigment cells of lower vertebrates have been traditionally used as a model for studies of intracellular transport mechanisms, because these cells transport pigment organelles to the center or to the periphery of the cell in a highly co-ordinated fashion. It is now well established that both aggregation and dispersion of pigment in melanophores require two elements of the cytoskeleton: microtubules and actin filaments. Melanosomes are moved along these cytoskeletal tracks by motor proteins. Recent studies have identified the motors responsible for pigment dispersion and aggregation in melanophores. We propose a model for the possible roles of the two cytoskeletal transport systems and how they might interact. We also discuss the putative mechanisms of regulation of pigment transport, especially phosphorylation. Last, we suggest areas of research that will receive attention in the future in order to elucidate the mechanisms of organelle transport.     

Aggregation of melanosomes in melanophores is accompanied by the reorganization of microtubules and intermediate filaments

The structure of the cytoskeleton in cultured melanophores of the fish Gymnocorymbus ternetzi during aggregation of melanosomes was studied. It has been shown that the motion of pigment granules is accompanied by a reorganization of microtubules and intermediate filament systems. In melanophores with dispersed pigment granules, microtubules are wavy and form a loose network whilst intermediate filaments in such cells form a dense network around the dispersed melanosomes. During aggregation microtubules and intermediate filaments become radially oriented. It was also shown that the surface area of melanophores increased during aggregation.     

Centrioles resist forces applied on centrosomes during G2/M transition

BACKGROUND INFORMATION: Centrosome movements at the onset of mitosis result from a balance between the pulling and pushing forces mediated by microtubules. The structural stability of the centrosome core structure, the centriole pair, is correlated with a heavy polyglutamylation of centriole tubulin. RESULTS: Using HeLa cells stably expressing centrin-green fluorescent protein as a centriole marker, we monitored the effect of microinjecting an anti-(polyglutamylated tubulin) monoclonal antibody, GT335, in G1/S or G2 cells. In contrast with the slow effect of the monoclonal antibody GT335 during interphase, a dramatic and rapid centrosome fragmentation occurred in cells microinjected in G2 that was both Eg5- and dynein-dependent. Inhibition of either one of these two motors significantly decreased the scattering of centrosome fragments, and inhibition of centrosome segregation by impairing microtubule dynamics abolished centrosome fragmentation. CONCLUSIONS: Our results demonstrate that the compact structure of the mitotic centrosome is capable of absorbing most of the pulling and pushing forces during G2/M transition and suggest that centrosomes could act as mechanosensors integrating tensions during cell division.     

Immunogold method evidences that kinesin and myosin bind to and couple microtubules and actin filaments in lipotubuloids of Ornithogalum umbellatum ovary epidermis

Lipotubuloids in ovary epidermis of Ornithogalum umbellatum which are a domain of cytoplasm containing a lot of lipid bodies, microtubules and actin filaments, ribosomes, endoplasmic reticulum as well as scarce mitochondria, microbodies, dictyosomes, autolytic vacuoles, exhibit progressive-rotary motion. The immunogold method demonstrated that microtubules and actin filaments of lipotubuloids might be connected with one another by myosin and kinesin. It was supposed that collaboration of motor proteins with actin filaments and microtubules makes autonomic high peripheral speed rotary motion of lipotubuloids in epidermis cells possible. Moreover, myosin was also detected in Golgi bodies in lipotubuloid. In lipotubuloids, the immunogold method demonstrated immunosignals after the use of an antibody to dynein light chains but spectroscopy mass analysis showed that in O. umbellatum epidermis lacked dynein heavy chains.     

Polyglutamylation: a fine‐regulator of protein function?

Polyglutamylation is a post-translational modification in which glutamate side chains of variable lengths are formed on the modified protein. It is evolutionarily conserved from protists to mammals and its most prominent substrate is tubulin, the microtubule (MT) building block. Various polyglutamylation states of MTs can be distinguished within a single cell and they are also characteristic of specific cell types or organelles. Polyglutamylation has been proposed to be involved in the functional adaptation of MTs, as it occurs within the carboxy-terminal tubulin tails that participate directly in the binding of many structural and motor MT-associated proteins. The discovery of a new family of enzymes that catalyse this modification has brought new insight into the mechanism of polyglutamylation and now allows for direct functional studies of the role of tubulin polyglutamylation. Moreover, the recent identification of new substrates of polyglutamylation indicates that this post-translational modification could be a potential regulator of diverse cellular processes.     

Actin-organelle interaction: association with chloroplast in arabidopsis leaf mesophyll cells.

The role of the cytoskeleton in the regulation of chloroplast motility and positioning has been investigated by studying: (1) structural relationship of actin microfilaments, microtubules, and chloroplasts in cryofixed and freeze-substituted leaf cells of Arabidopsis; and (2) the effects of anti-actin (Latrunculin B; LAT-B) and anti-microtubule (Oryzalin) drugs on intracellular distribution of chloroplasts. Immunolabeling of leaf cells with two plant-actin specific antibodies, which react equivalently with all the expressed Arabidopsis actins, revealed two arrangements of actin microfilaments: longitudinal arrays of thick actin bundles and randomly oriented thin actin filaments that extended from the bundles. Chloroplasts were either aligned along the actin bundles or closely associated with the fine filaments. Baskets of actin microfilaments were also observed around the chloroplasts. The leaf cells labeled with an anti-tubulin antibody showed dense transverse arrays of cortical microtubules that exhibited no apparent association with chloroplasts. The application of LAT-B severely disrupted actin filaments and their association with chloroplasts. In addition, LAT-B induced aberrant aggregation of chloroplasts in the mesophyll and bundle sheath cells. Double labeling of LAT-B treated cells with anti-actin and anti-tubulin antibodies revealed that the microtubules in these cells were unaffected. Moreover, depolymerization of microtubules with Oryzalin did not affect the distribution of chloroplasts. These results provide evidence for the involvement of actin, but not tubulin, in the movement and positioning of chloroplasts in leaf cells. We propose that using motor molecules, some chloroplasts migrate along the actin cables directly, while others are pulled along the cables by the fine actin filaments. The baskets of microfilaments may anchor the chloroplasts during streaming and allow control over proper three-dimensional orientation to light.     

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.     

Detyrosination of tubulin is not correlated to cold-adaptation of microtubules in cultured cells from the Atlantic cod (Gadus morhua)

Summary Isolated cod brain microtubules from the cold-adapted Atlantic cod (Gadus morhua) have previously been shown to be highly detyrosinated, a post-translational modification of tubulin usually found in stable subsets of microtubules. In this study we found this was not restricted only to isolated brain microtubules. Microtubules in primary cultures of brain and skin cells were composed of both tyrosinated (Tyr)- and detyrosinated (Glu)-tubulin seen by immunocytochemistry. Immunoelectron microscopy of isolated microtubules showed that individual microtubules were composed of a mixture of Tyr- and Glu-tubulin. Leukocytes with extending lamellopodia contained only microtubules stained with the antibody against Tyr-tubulin, and isolated heart tubulin lacked both Tyr- and Glu-tubulin, suggesting that a relative high level of detyrosination is a characteristic of most, but not all, cod microtubules. Brain cell microtubules were more resistant to mitotic inhibitors than skin cell microtubules, but this was not correlated to a difference in detyrosination. Brain and skin cell microtubules were only partially disassembled when incubated at 0°C. Upon reassembly of microtubules at 12°C, microtubules were still made of mixtures of Tyr- and Glu-tubulin, indicating that detyrosination of assembled microtubules is rapid and/or that in cod cells, in contrast to mammalian cells, Glu-tubulin can reassemble to microtubules. Our data show that most cod microtubules are highly detyrosinated, but this is not the cause of their cold adaptation or drug stability.     

Microtubule dynamics in fish melanophores

We have studied the dynamics of microtubules in black tetra (Gymnocorymbus ternetzi) melanophores to test the possible correlation of microtubule stability and intracellular particle transport. X- rhodamine-or caged fluorescein-conjugated tubulin were microinjected and visualized by fluorescence digital imaging using a cooled charge coupled device and videomicroscopy. Microtubule dynamics were evaluated by determining the time course of tubulin incorporation after pulse injection, by time lapse observation, and by quantitation of fluorescence redistribution after photobleaching and photoactivation. The time course experiments showed that the kinetics of incorporation of labeled tubulin into microtubules were similar for cells with aggregated or dispersed pigment with most microtubules becoming fully labeled within 15-20 min after injection. Quantitation by fluorescence redistribution after photobleaching and photoactivation confirmed that microtubule turnover was rapid in both states, t1/2 = 3.5 +/- 1.5 and 6.1 +/- 3.0 min for cells with aggregated and dispersed pigment, respectively. In addition, immunostaining with antibodies specific to posttranslationally modified alpha-tubulin, which is usually enriched in stable microtubules, showed that microtubules composed exclusively of detyrosinated tubulin were absent and microtubules containing acetylated tubulin were sparse. We conclude that the microtubules of melanophores are very dynamic, that their dynamic properties do not depend critically on the state of pigment distribution, and that their stabilization is not a prerequisite for intracellular transport.     

Interaction of Chlamydomonas dynein with tubulin

Studies were conducted to determine if dynein could bind to unpolymerized tubulin. Tubulin alone normally fractionated in the included volume of a molecular sieve Bio-Gel A-1.5m column. Incubated together, tubulin and dynein coeluted in the void volumn, suggesting that a complex had formed between the two. In addition, immunoelectron microscopy revealed preassembled microtubules were labeled with biotin antibody only when incubated in both dynein and biotinylated tubulin, evidence that dynein with bound biotinylated tubulin had decorated the microtubules. A fraction of the tubulin could be dissociated from dynein by addition of ATP and vanadate, as assayed by molecular sieve chromatography followed by densitometry of gels, suggesting that some tubulin bound to the B end of the dynein arm. Additional tubulin dissociated from the dynein under conditions of high salt. These studies, together with those indicating that tubulin blocked the A end of the dynein arm from binding to microtubules and promoted the interaction of two arms at their A ends, provide evidence that the A end of the arm also can bind tubulin. Thus, the tubulin subunits, themselves, on a microtubule rather than a particular surface lattice structure formed by adjacent protofilaments may provide the binding sites for both ends of the dynein arm.     

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).     

Models of motor-assisted transport of intracellular particles

One-dimensional models are presented for the macroscopic intracellular transport of vesicles and organelles by molecular motors on a network of aligned intracellular filaments. A motor-coated vesicle or organelle is described as a diffusing particle binding intermittently to filaments, when it is transported at the motor velocity. Two models are treated in detail: 1) a unidirectional model, where only one kind of motor is operative and all filaments have the same polarity; and 2) a bidirectional model, in which filaments of both polarities exist (for example, a randomly polarized actin network for myosin motors) and/or particles have plus-end and minus-end motors operating on unipolar filaments (kinesin and dynein on microtubules). The unidirectional model provides net particle transport in the absence of a concentration gradient. A symmetric bidirectional model, with equal mixtures of filament polarities or plus-end and minus-end motors of the same characteristics, provides rapid transport down a concentration gradient and enhanced dispersion of particles from a point source by motor-assisted diffusion. Both models are studied in detail as a function of the diffusion constant and motor velocity of bound particles, and their rates of binding to and detachment from filaments. These models can form the basis of more realistic models for particle transport in axons, melanophores, and the dendritic arms of melanocytes, in which networks of actin filaments and microtubules coexist and motors for both types of filament are implicated.