Structural and functional effects of hydrostatic pressure on centrosomes from vertebrate cells.

In an attempt to better understand the role of centrioles in vertebrate centrosomes, hydrostatic pressure was applied to isolated centrosomes as a means to disassemble centriole microtubules. Treatments of the centrosomes were monitored by analyzing their protein composition, ultrastructure, their ability to nucleate microtubules from pure tubulin, and their capability to induce parthenogenetic development of Xenopus eggs. Moderate hydrostatic pressure (95 MPa) already affected the organization of centriole microtubules in isolated centrosomes, and also impaired microtubule nucleation. At higher pressure, the protein composition of the peri-centriolar matrix (PCM) was also altered and the capacity to nucleate microtubules severely impaired. Incubation of the treated centrosomes in Xenopus egg extract could restore their capacity to nucleate microtubules after treatment at 95 MPa, but not after higher pressure treatment. However, the centriole structure was in no case restored. It is noteworthy that centrosomes treated with mild pressure did not allow parthenogenetic development after injection into Xenopus eggs, even if they had recovered their capacity to nucleate microtubules. This suggested that, in agreement with previous results, centrosomes in which centriole architecture is impaired, could not direct the biogenesis of new centrioles in Xenopus eggs. Centriole structure could also be affected by applying mild hydrostatic pressure directly to living cells. Comparison of the effect of hydrostatic pressure on cells at the G1/S border or on the corresponding cytoplasts suggests that pro-centrioles are very sensitive to pressure. However, cells can regrow a centriole after pressure-induced disassembly. In that case, centrosomes eventually recover an apparently normal duplication cycle although with some delay.

Centrosome-dependent exit of cytokinesis in animal cells.

As an organelle coupling nuclear and cytoplasmic divisions, the centrosome is essential to mitotic fidelity, and its inheritance could be critical to understanding cell transformation. Investigating the behavior of the centrosome in living mitotic cells, we documented a transient and remarkable postanaphase repositioning of this organelle, which apparently controls the release of central microtubules from the midbody and the completion of cell division. We also observed that the absence of the centrosome leads to defects in cytokinesis. Together with recent results in yeasts, our data point to a conserved centrosome-dependent pathway that integrates spatial controls into the decision of completing cell division, which requires the repositioning of the centrosome organelle.

Centrosomes, microtubules and cell migration.

Directed cell movement is an immensely complex process that depends on the co-operative interaction of numerous cellular components. Work over the past three decades has suggested that microtubules play an important role in the establishment and maintenance of the direction of cell migration. This chapter summarizes recent work from our laboratory designed to determine the roles of the microtubules and centrosome position relative to the direction of cell migration in a variety of cell types, and discusses these observations in the context of work from other laboratories. The results suggest that microtubules are required for stabilization of the direction of migration in many, but not all, cell types. For the centrosome to act as a stabilizer of cell migration requires that it is repositioned behind the leading edge. However, the process of repositioning does not precede the extension of a leading edge and the establishment of a new direction of cell migration. Rather, the centrosome follows the repositioning of the leading edge in response to other stimuli and, in doing so, stabilizes cell movement.

Unusual centrosome cycle in Dictyostelium: correlation of dynamic behavior and structural changes.

Centrosome duplication and separation are of central importance for cell division. Here we provide a detailed account of this dynamic process in Dictyostelium. Centrosome behavior was monitored in living cells using a gamma-tubulin-green fluorescent protein construct and correlated with morphological changes at the ultrastructural level. All aspects of the duplication and separation process of this centrosome are unusual when compared with, e.g., vertebrate cells. In interphase the Dictyostelium centrosome is a box-shaped structure comprised of three major layers, surrounded by an amorphous corona from which microtubules emerge. Structural duplication takes place during prophase, as opposed to G1/S in vertebrate cells. The three layers of the box-shaped core structure increase in size. The surrounding corona is lost, an event accompanied by a decrease in signal intensity of gamma-tubulin-green fluorescent protein at the centrosome and the breakdown of the interphase microtubule system. At the prophase/prometaphase transition the separation into two mitotic centrosomes takes place via an intriguing lengthwise splitting process where the two outer layers of the prophase centrosome peel away from each other and become the mitotic centrosomes. Spindle microtubules are now nucleated from surfaces that previously were buried inside the interphase centrosome. Finally, at the end of telophase, the mitotic centrosomes fold in such a way that the microtubule-nucleating surface remains on the outside of the organelle. Thus in each cell cycle the centrosome undergoes an apparent inside-out/outside-in reversal of its layered structure.

Isolation of nucleation-competent centrosomes from Dictyostelium discoideum.

The centrosome of Dictyostelium discoideum is a box-shaped, layered core structure surrounded by a corona which is made up of dense nodules embedded in amorphous material. It is also known as nucleus-associated body. Because of its tight association with the nucleus the centrosome has resisted so far all attempts for isolation in sufficient purity and quantity for biochemical analysis. Here we report on the large-scale isolation of D. discoideum centrosomes after treatment of nucleus-centrosome complexes with a buffer containing sodium pyrophosphate. Following heparin treatment and a filtration step, centrosomes were further purified by density gradient centrifugation. Immunofluorescence analysis of the isolated centrosomes revealed the presence of the D. discoideum 350-kDa antigen, a centrosomal marker protein, gamma-tubulin, and the D. discoideum homologues of pericentrin, Spc110p, and Cdc31p. The structural integrity of the isolated centrosomes was demonstrated by confocal laser microscopy and electron microscopy. Microtubule nucleation assays with purified pig brain tubulin showed that the isolation procedure did not only preserve the structure but also the functionality of the isolated centrosomes. D. discoideum centrosomes should now become an attractive new model system in addition to, and for comparison with, centriolar centrosomes and yeast spindle pole bodies.

Dictyostelium gamma-tubulin: molecular characterization and ultrastructural localization.

The centrosome of Dictyostelium discoideum is a nucleus-associated body consisting of an electron-dense, three-layered core surrounded by an amorphous matrix, the corona. To elucidate the molecular and supramolecular architecture of this unique microtubule-organizing center, we have isolated and sequenced the gene encoding gamma-tubulin and have studied its localization in the Dictyostelium centrosome using immunofluorescence and postembedding immunoelectron microscopy. D. discoideum possesses a single copy of a gamma-tubulin gene that is related to, but more divergent from, other gamma-tubulins. The low-abundance gene product is localized to the centrosome in an intriguing pattern: it is highly concentrated in the corona in regularly spaced clusters whose distribution correlates with the patterning of dense nodules that are a prominent feature of the corona. These observations lend support to the notion that the corona is the functional homologue of the pericentriolar matrix of 'higher' eukaryotic centrosomes, and that nodules are the functional equivalent of gamma-tubulin ring complexes that serve as nucleation sites for microtubules in animal centrosomes.

Centrosome positioning and directionality of cell movements.

In several cell types, an intriguing correlation exists between the position of the centrosome and the direction of cell movement: the centrosome is located behind the leading edge, suggesting that it serves as a steering device for directional movement. A logical extension of this suggestion is that a change in the direction of cell movement is preceded by a reorientation, or shift, of the centrosome in the intended direction of movement. We have used a fusion protein of green fluorescent protein (GFP) and gamma-tubulin to label the centrosome in migrating amoebae of Dictyostelium discoideum, allowing us to determine the relationship of centrosome positioning and the direction of cell movement with high spatial and temporal resolution in living cells. We find that the extension of a new pseudopod in a migrating cell precedes centrosome repositioning. An average of 12 sec elapses between the initiation of pseudopod extension and reorientation of the centrosome. If no reorientation occurs within approximately 30 sec, the pseudopod is retracted. Thus the centrosome does not direct a cell's migration. However, its repositioning stabilizes a chosen direction of movement, most probably by means of the microtubule system.

Mechanism of centrosome positioning during the wound response in BSC-1 cells.

Locomoting cells are characterized by a pronounced external and internal anterior-posterior polarity. One of the events associated with cell polarization at the onset of locomotion is a shift of the centrosome, or MTOC, ahead of the nucleus. This position is believed to be of strategic importance for directional cell movement and cell polarity. We have used BSC-1 cells at the edge of an in vitro wound to clarify the causal relationship between MTOC position and the initiation of cell polarization. We find that pronounced cell polarization (the extension of a lamellipod) can take place in the absence of MTOC repositioning or microtubules. Conversely, MTOCs will reposition even after lamellar extension and cell polarization have occurred. Repositioning requires microtubules that extend to the cell periphery and is independent of selective detyrosination of microtubules extending towards the cell front. Significantly, MTOCs maintain, or at least attempt to maintain, a position at the cell's centroid. This is most clearly demonstrated in wounded monolayers of enucleated cells where the MTOC closely follows the centroid position. We suggest that the primary response to the would is the biased extension of a lamellipod, which can occur in the absence of microtubules and MTOC repositioning. Lamellipod extension leads to a shift of the cell's centroid towards the wound. The MTOC, in an attempt to maintain a position near the cell center, will follow. This will automatically put the MTOC ahead of the nucleus in the vast majority of cells. The nucleus as a reference for MTOC position may not be as meaningful as previously thought.

Viscoelastic properties of vimentin compared with other filamentous biopolymer networks.

The cytoplasm of vertebrate cells contains three distinct filamentous biopolymers, the microtubules, microfilaments, and intermediate filaments. The basic structural elements of these three filaments are linear polymers of the proteins tubulin, actin, and vimentin or another related intermediate filament protein, respectively. The viscoelastic properties of cytoplasmic filaments are likely to be relevant to their biologic function, because their extreme length and rodlike structure dominate the rheologic behavior of cytoplasm, and changes in their structure may cause gel-sol transitions observed when cells are activated or begin to move. This paper describes parallel measurements of the viscoelasticity of tubulin, actin, and vimentin polymers. The rheologic differences among the three types of cytoplasmic polymers suggest possible specialized roles for the different classes of filaments in vivo. Actin forms networks of highest rigidity that fluidize at high strains, consistent with a role in cell motility in which stable protrusions can deform rapidly in response to controlled filament rupture. Vimentin networks, which have not previously been studied by rheologic methods, exhibit some unusual viscoelastic properties not shared by actin or tubulin. They are less rigid (have lower shear moduli) at low strain but harden at high strains and resist breakage, suggesting they maintain cell integrity. The differences between F-actin and vimentin are optimal for the formation of a composite material with a range of properties that cannot be achieved by either polymer alone. Microtubules are unlikely to contribute significantly to interphase cell rheology alone, but may help stabilize the other networks.

Nucleotide specificities of anterograde and retrograde organelle transport in Reticulomyxa are indistinguishable.

Membrane-bound organelles move bidirectionally along microtubules in the freshwater ameba, Reticulomyxa. We have examined the nucleotide requirements for transport in a lysed cell model and compared them with kinesin and dynein-driven motility in other systems. Both anterograde and retrograde transport in Reticulomyxa show features characteristic of dynein but not of kinesin-powered movements: organelle transport is reactivated only by ATP and no other nucleoside triphosphates; the Km and Vmax of the ATP-driven movements are similar to values obtained for dynein rather than kinesin-driven movement; and of 15 ATP analogues tested for their ability to promote organelle transport, only 4 of them did. This narrow specificity resembles that of dynein-mediated in vitro transport and is dissimilar to the broad specificity of the kinesin motor (Shimizu, T., K. Furusawa, S. Ohashi, Y. Y. Toyoshima, M. Okuno, F. Malik, and R. D. Vale. 1991. J. Cell Biol. 112: 1189-1197). Remarkably, anterograde and retrograde organelle transport cannot be distinguished at all with respect to nucleotide specificity, kinetics of movement, and the ability to use the ATP analogues. Since the "kinetic fingerprints" of the motors driving transport in opposite directions are indistinguishable, the same type of motor(s) may be involved in the two directions of movement.

Force generation of organelle transport measured in vivo by an infrared laser trap.

Organelle transport along microtubules is believed to be mediated by organelle-associated force-generating molecules. Two classes of microtubule-based organelle motors have been identified: kinesin and cytoplasmic dynein. To correlate the mechanochemical basis of force generation with the in vivo behaviour of organelles, it is important to quantify the force needed to propel an organelle along microtubules and to determine the force generated by a single motor molecule. Measurements of force generation are possible under selected conditions in vitro, but are much more difficult using intact or reactivated cells. Here we combine a useful model system for the study of organelle transport, the giant amoeba Reticulomyxa, with a novel technique for the non-invasive manipulation of and force application to subcellular components, which is based on a gradient-force optical trap, also referred to as 'optical tweezers'. We demonstrate the feasibility of using controlled manipulation of actively translocating organelles to measure direct force. We have determined the force driving a single organelle along microtubules, allowing us to estimate the force generated by a single motor to be 2.6 x 10(-7) dynes.

An ATPase with properties expected for the organelle motor of the giant amoeba, Reticulomyxa.

The rapid, vectorial, microtubule-associated transport of organelles is believed to be mediated by specific mechanochemical transducers. Recent studies of various metazoan cells have allowed the identification of novel microtubule-dependent translocator molecules capable of promoting microtubule gliding across glass surfaces and translocation of inert beads along microtubules. These translocators could be involved in force generation for directional organelle movements in vivo. Here we report the identification of a microtubule-binding protein with characteristics expected for an organelle translocator in the giant freshwater amoeba Reticulomyxa. This factor has an apparent relative molecular mass (Mr) of 440,000 (440K) and sediments at 20-22S in sucrose-density gradients. It binds to microtubules under conditions of ATP depletion, possesses an ATPase activity and is sensitive to ultraviolet-induced, vanadate-dependent cleavage. Although its pharmacological properties differ from those of axonemal dynein, it can be considered to be a variant of cytoplasmic dynein. The Reticulomyxa high-molecular-weight protein (HMWP) promotes rapid, bidirectional movement of latex beads along Reticulomyxa microtubules in vitro at an average speed of 3.6 micron s-1. This protein, therefore, is a likely candidate for a microtubule-dependent motor.

Release of enzymes of intermediary metabolism from permeabilized cells: further evidence in support of a structural organization of the cytoplasmic matrix.

Cultured BSC-1 cells were exposed to the mild ionic detergent, Brij 58, and the time course of the release of three enzymes of intermediary metabolism (lactate dehydrogenase, aldolase, and creatine phosphokinase) was determined spectrophotometrically. Their release correlates well with the overall decrease in structural complexity of the cytoplasmic matrix. However, each of the three enzymes tested has its own characteristic time-dependent release profile, a result suggesting enzyme-specific variability in their association with the cytomatrix. Cells lysed for 5 min in Brij 58 and then transferred to detergent-free glycolysis medium were able to produce lactate from glucose, an observation consistent with the idea that all enzymes of the glycolytic pathway remained in the cytomatrix. These observations are consistent with a structural rather than viscous organization of the cytoplasm and suggest that cytoplasmic components other than cytoskeletal filaments are able to form parafilamentous, metastable complexes.

Active sliding between cytoplasmic microtubules.

Microtubules are versatile cellular polymers that play a role in cell shape determination and mediate various motile processes such as ciliary and flagellar bending, chromosome movements and organelle transport. That a sliding microtubule mechanism can generate force has been demonstrated in highly ordered structures such as axonemes, and microtubule-based force generation almost certainly contributes to the function of mitotic and meiotic spindles. Most cytoplasmic microtubule arrays, however, do not exhibit the structural regularity of axonemes and some spindles, and often appear disorganized. Yet many cellular activities (such as shape changes during morphogenesis, axonal extension and spindle assembly) involve highly coordinated microtubule behaviour and possibly require force generated by an intermicrotubule sliding mechanism, or perhaps use sliding to move microtubules rapidly into a protrusion for stabilization. Here we show that active sliding between cytoplasmic microtubules can occur in microtubule bundles of the amoeba Reticulomyxa. A force-producing mechanism of this sort could be used by this organism to facilitate the extension of cell processes and to generate the dynamic movements of the cytoplasmic network.

Cytoskeletal architecture and motility in a giant freshwater amoeba, Reticulomyxa.

Reticulomyxa is a large, multinucleated freshwater protozoan with striking intracellular transport. Cytoplasmic streaming and saltatory movements of individual organelles (at rates of up to 25 micron/sec) are observed within the naked cell body and the extensive reticulate peripheral network of fine cytoplasmic strands. As demonstrated by video-enhanced light microscopy, individual organelles move only when associated with cytoskeletal linear elements. The linear elements are composed of mixed colinear bundles of microtubules and actin filaments, which form the backbone of the reticulopodial network. The constant branching, sprouting, and fusion of network strands suggest unique membrane properties and an unusually dynamic cytoskeleton. The electrophoretic mobility of Reticulomyxa tubulins and the lack of crossreactivity with several antibodies known to react with many plant and animal tubulins suggest that they may differ from other tubulins more widely than might be expected. Reticulomyxa's large size, the rapidity and pervasiveness of the two forms of transport, and the simple and ordered cytoskeleton make the organism well suited for future studies on the mechanisms of intracellular transport.

Reticulomyxa: a new model system of intracellular transport.

Reticulomyxa is a large multinucleated freshwater protozoan that provides a new model system in which to study intracellular transport and cytoskeletal dynamics. Within the cell body and reticulopodial network, rapid, visually striking saltatory organelle motility as well as bulk cytoplasmic streaming can be readily observed. In addition, the cytoskeletal elements within these strands undergo dynamic splaying and fusing rearrangements, which can be visualized by video-enhanced light microscopy. A reactivatable lysed cell model has been developed that appears to preserve, and therefore permits examination of, these three forms of motility in a more controlled environment. Individual organelle movements are microtubule-based and have similarities to, but also differences from, the recently described kinesin-based transport. This lysed cell model can be further manipulated to provide native, ordered, completely exposed networks of either microtubules or microfilaments, or a combination of both, and thus may serve as a versatile motility assay system in which to examine the movement of exogenously added isolated organelles or latex beads.