Cell Movements and Mechanical Force Distribution During the Migration of Dictyostelium Slugs

Migration of Dictyostelium discoideum slugs results from coordinated movement of their constituent cells. It is generally assumed that each cell contributes to the total motive force of the slug. However, the basic mechanisms by which mechanical forces (traction and resistive forces) are transmitted to the substrate, their magnitude and their location, are largely unknown. In this work, we performed detailed observations of cell movements by fluorescence microscopy using two-dimensional (2D) slugs. We show that 2D slugs share most of the properties of 3D ones. In particular, waves of movement propagate in long 2D slugs, and slug speed correlates with slug length as found in 3D slugs. We also present the first measurements of the distribution of forces exerted by 2D and 3D slugs using the elastic substrate method. Traction forces are mainly exerted in the central region of the slug. The large perpendicular forces around slug boundary and the existence of parallel resistive forces in the tip and/or the tail suggest an important role of the sheath in the transmission of forces to the substrate.     

Migration in Dictyostelium polycephalum

By comparing two species of cellular slime molds that have stalkless migration stages it is possible to gain interesting insights into how the cells move. In contrast to the familiar behavior of Dictyostelium discoideum, Dictyostelium polycephalum slugs can travel greater distances through soil and even can migrate through agar. In addition to the interest in the differences, these differences shed light on the mechanism of slug movement. Unlike D. discoideum, D. polycephalum does not have prestalk and prespore zones and severed sections of any part of these slugs move at a rate proportional to their length. This leads to the hypothesis that longer slugs move faster because the amoebae aligned along the inside of the slime sheath each contribute a forward push and the more extended the amoebae line is the faster the slug moves.     

Analytical studies on migrating movement of the pseudo-plasmodium ofDictyostelium discoideum

Summary Migrating movement of a pseudoplasmodium (slug) of the cellular slime mouldDictyostelium discoideum was analyzed using a time-lapse video tape recorder. Since slugs usually migrated with repeated interruptions of advance, migrating velocities were measured only within a period of forward movement. On the basis of some known facts and assumptions, a dynamical model for slug movement was formulated, which consists of motive force generated by slug cells against their intrinsic resistance and resistance of slime sheath at the tip. The migrating velocity of a slug depended neither on its width nor its volume, but solely on its length. Under any experimental conditions tested, a linear relationship always held between reciprocals of the two variables. The results were in good agreement with predictions of the model. Quantitative analyses of experimental results by the use of the model lead to the conclusions that a decrease in velocity at a low temperature is due to an increase in resistance of slime sheath at the tip, but that a decrease in velocity during prolonged migration is due to a decrease in motive force of constituent cells. An anterior isolate dissected from a slug migrated at a velocity greater than that of an intact slug of the same length. This was interpreted by the model to be due to the fact that the anterior cells have greater motive forces and intrinsic resistances than the posterior cells. The heterogeneous distributions of the two variables in the cell mass is discussed in reference to the mechanism of sorting out of cells.     

Aerial migration of the Dictyostelium slug

The Dictyostelium slug lays down curved marks in its slime sheath trail as it migrates across an agar substrate. These 'footprints' are caused by elevation of the slug anterior as it initiates a period of aerial migration and can be used as a measure of the slug's propensity for this behavior. A variety of factors have been found to affect the number of footprints created per distance migrated. Smaller slugs produce a higher incidence of footprints than larger slugs. Migration in the light and lower temperatures during migration increase footprint incidence. Activated charcoal reduces, while exogenous addition of ammonia increases, the incidence of footprints. Simulation of the three-dimensional (3D) environment of the soil suggests that aerial migration plays a role in the slug's movement through the cavities of its natural environment. A model proposes that aerial migration is initiated by a small group of continually changing prestalk cells that acts as a pacemaker and is moved around the circumference of the slug tip by the rotation of the prestalk cells. As this pacemaker reaches the upper surface of the slug it can initiate aerial migration.     

Copine A is expressed in prestalk cells and regulates slug phototaxis and thermotaxis in developing Dictyostelium

Copines are calcium-dependent membrane-binding proteins found in many eukaryotic organisms. We are studying the function of copines using the model organism, Dictyostelium discoideum. When under starvation conditions, Dictyostelium cells aggregate into mounds that become migrating slugs, which can move toward light and heat before culminating into a fruiting body. Previously, we showed that Dictyostelium cells lacking the copine A (cpnA) gene are not able to form fruiting bodies and instead arrest at the slug stage. In this study, we compared the slug behavior of cells lacking the cpnA gene to the slug behavior of wild-type cells. The slugs formed by cpnA- cells were much larger than wild-type slugs and exhibited no phototaxis and negative thermotaxis in the same conditions that wild-type slugs exhibited positive phototaxis and thermotaxis. Mixing as little as 5% wild-type cells with cpnA- cells rescued the phototaxis and thermotaxis defects, suggesting that CpnA plays a specific role in the regulation of the production and/or release of a signaling molecule. Reducing extracellular levels of ammonia also partially rescued the phototaxis and thermotaxis defects of cpnA- slugs, suggesting that CpnA may have a specific role in regulating ammonia signaling. Expressing the lacZ gene under the cpnA promoter in wild-type cells indicated cpnA is preferentially expressed in the prestalk cells found in the anterior part of the slug, which include the cells at the tip of the slug that regulate phototaxis, thermotaxis, and the initiation of culmination into fruiting bodies. Our results suggest that CpnA plays a role in the regulation of the signaling pathways, including ammonia signaling, necessary for sensing and/or orienting toward light and heat in the prestalk cells of the Dictyostelium slug.     

Concerted Movement of Prestalk Cells in Migrating Slugs of Dictyostelium Revealed by the Localization of Myosin

Localization of myosin in slugs of the cellular slime mold Dictyostelium discoideum was investigated by an immunofluorescence technique. Myosin is thought to provide the molecular machinery for cellular movement. We found that myosin could be visualized as c-shaped fluorescence at the cortex of prestalk cells in a migrating slug, and that the open regions of all c-shaped fluorescence point in the direction of the slug's migration. We reported previously that the c-shaped fluorescence of myosin can be seen at the cortex of the tail region of actively locomoting cells at the unicellular stage (39, 41). These results suggest that prestalk cells move actively in the slug, and that their direction of movement, which can be identified from the polarity of c-shaped fluorescence, correspond with the direction of the slug's migration. The distribution of c-shaped fluorescence in slugs during migration, phototaxis and avoidance of ammonia strongly suggests that the slug's behavior is controlled by the concerted movement of prestalk cells.     

Decoupling Substrate Stiffness, Spread Area, and Micropost Density: A Close Spatial Relationship between Traction Forces and Focal Adhesions

Mechanical cues can influence the manner in which cells generate traction forces and form focal adhesions. The stiffness of a cell's substrate and the available area on which it can spread can influence its generation of traction forces, but to what extent these factors are intertwined is unclear. In this study, we used microcontact printing and micropost arrays to control cell spreading, substrate stiffness, and post density to assess their effect on traction forces and focal adhesions. We find that both the spread area and the substrate stiffness influence traction forces in an independent manner, but these factors have opposite effects: cells on stiffer substrates produce higher average forces, whereas cells with larger spread areas generate lower average forces. We show that post density influences the generation of traction forces in a manner that is more dominant than the effect of spread area. Additionally, we observe that focal adhesions respond to spread area, substrate stiffness, and post density in a manner that closely matches the trends seen for traction forces. This work supports the notion that traction forces and focal adhesions have a close relationship in their response to mechanical cues.     

Monoclonal antibody characterisation of slime sheath: the extracellular matrix of Dictyostelium discoideum

Proteins can be extracted from the slime sheath of Dictyostelium discoideum slugs by denaturing agents. A subset of these proteins is also released by cellulase digestion of the sheath, implying that protein-protein and protein-cellulose interactions are involved in sheath protein retention. It seems probable that the cellulose-associated sheath proteins are also associated with the cellulose of mature stalk cells. Monoclonal antibodies directed against sheath demonstrate extensive sharing of antigenic determinants between sheath proteins and a limited degree of antigenic sharing between sheath and slug cell proteins. All of the proteins recognised by these monoclonal antibodies are developmentally regulated. These results are discussed in terms of the structure of the sheath and its possible role(s) in D. discoideum development.     

Exploiting new terrain: an advantage to sociality in the slime mold Dictyostelium discoideum

Understanding the ecological benefits of social actions is centralto explaining the evolution of social behavior. The social amoebaDictyostelium discoideum has been well studied and is a modelfor social evolution and development, but surprisingly littleis known about its ecology. When starving, thousands of thenormally solitary amoebae aggregate to form a differentiatedmulticellular organism known as a slug. The slug migrates towardthe soil surface where it metamorphoses into a fruiting bodyof hardy spores held up by a dead stalk comprising about one-fifthof the cells. Multicellularity in D. discoideum is thought tohave evolved to lift the spores above the hazards of the soilwhere spores can be picked up for long-distance dispersal. Here,we show that multicellularity has another advantage: local dispersalto new food sources. We find that cells shed by D. discoideumslugs during migration consume and remove bacteria in the pathof the slug, although slugs themselves do not breakup. We alsoshow that slugs are adept at local dispersal by comparing migrationof slugs with migration of individual cells of the mutant, CAP2,which cannot aggregate and so rely only on cellular movement.In particular, the solitary cells of the aggregation mutantare unable to cross a soil barrier, easily crossed by slugs.We propose that the exploitation of local food patches is animportant selective benefit favoring multicellular cooperationin D. discoideum.     

How cellular movement determines the collective force generated by the Dictyostelium discoideum slug

How the collective motion of cells in a biological tissue originates in the behavior of a collection of individuals, each of which responds to the chemical and mechanical signals it receives from neighbors, is still poorly understood. Here we study this question for a particular system, the slug stage of the cellular slime mold Dictyostelium discoideum (Dd). We investigate how cells in the interior of a migrating slug can effectively transmit stress to the substrate and thereby contribute to the overall motive force. Theoretical analysis suggests necessary conditions on the behavior of individual cells, and computational results shed light on experimental results concerning the total force exerted by a migrating slug. The model predicts that only cells in contact with the substrate contribute to the translational motion of the slug. Since the model is not based specifically on the mechanical properties of Dd cells, the results suggest that this behavior will be found in many developing systems.     

Why does slug length correlate with speed during migration inDictyostelium discoideum?

Taking advantage of the fact that static electricity in plastic Petri dishes will produce very long, thin migrating slugs ofDictyostelium discoideum, it was shown that these slugs moved particularly rapidly. This is consistent with the demonstration of Inouye and Takeuchi that speed varies with length for slugs migrating on agar. Based on these observations it is suggested that slug speed is controlled by both the resistance at the tip and some factor that correlates With slug size, such as the concentration of endogenously produced ammonia     

Propagating chemoattractant waves coordinate periodic cell movement in Dictyostelium slugs.

Migration and behaviour of Dictyostelium slugs results from coordinated movement of its constituent cells. It has been proposed that cell movement is controlled by propagating waves of cAMP as during aggregation and in the mound. We report the existence of optical density waves in slugs; they are initiated in the tip and propagate backwards. The waves reflect periodic cell movement and are mediated by cAMP, as injection of cAMP or cAMP phosphodiesterase disrupts wave propagation and results in effects on cell movement and, therefore, slug migration. Inhibiting the function of the cAMP receptor cAR1 blocks wave propagation, showing that the signal is mediated by cAR1. Wave initiation is strictly dependent on the tip; in decapitated slugs no new waves are initiated and slug movement stops until a new tip regenerates. Isolated tips continue to migrate while producing waves. We conclude from these observations that the tip acts as a pacemaker for cAMP waves that coordinate cell movement in slugs.     

Cell Sorting daring Pattern Formation in Dictyostelium

Formation of the prestalk-prespore pattern in Dictyostelium was investigated in slugs and submerged clumps of cells. Prestalk and prespore cells were identified by staining with vital dyes, which are shown to be stable cell markers. Dissociated slug cells reaggregate and form slugs that contain a prestalk-prespore pattern indistinguishable from the original pattern. The pattern forms by sorting out of stained prestalk cells from unstained prespore cells. Sorting also occurs in clumps of dissociated slug cells submerged in liquid or agar. A pattern arises in 2 h in which a central core of stained cells is surrounded by a periphery of unstained cells. Sorting appears to be due to differential chemotaxis of stained and unstained cells to cAMP since exogenous cAMP (>10⁻⁷ M) reverses the normal direction of sorting-out such that stained cells sort to the periphery of the clumps.
Isolated portions of slugs regenerate a new prestalk-prespore pattern. Posterior isolates regenerate a pattern within 2 h due to sorting of a population of vitally stained 'anterior-like' cells present in posteriors. Anterior-like cells do not sort in intact slugs due to the influence of a diffusible inhibitor secreted by the anterior region. During posterior regeneration this signal is absent and anterior-like cells rapidly acquire the ability to sort. Anterior isolates regenerate a staining pattern more slowly than posterior isolates by a process that requires conversion of stained prestalk cells to unstained prespore cells.
The results suggest that pattern formation in Dictyostelium consists of two processes: establishment of appropriate proportions of two cell types and establishment of the pattern itself by a mechanism of sorting-out.     

Nature and distribution of the morphogen DIF in the Dictyostelium slug

The Dictyostelium slug contains a simple anterior-posterior pattern of prestalk and prespore cells. It is likely that DIF, the morphogen which induces stalk cells, is involved in establishing this pattern. Previous work has shown that a number of distinct species of DIF are released by developing cells and that cell-associated DIF activity increases rapidly during the slug stage of development. In this paper we describe a comparison of the DIF extracted from slugs with the DIF released into the medium. Analysis by high-pressure liquid chromatography (HPLC) using different solvent systems shows that the major species of DIF activity extracted from slugs coelutes with DIF-1, the major species of released DIF and is similarly sensitive to sodium borohydride reduction. Since DIF specifically induces the differentiation of prestalk cells, the anterior cells of the slug, it could be anticipated that DIF is localized in the prestalk region. We have therefore determined the distribution of DIF within the slug. Migrating slugs from strain V12M2 were manually dissected into anterior one-third and posterior two-third fragments and the DIF activity extracted. Surprisingly, we found that DIF was not restricted to the prestalk fragment. Instead there appears to be a reverse gradient of DIF in the slug with at least twice the specific activity of total DIF in the prespore region than in the prestalk region.     

Cell migrations during morphogenesis: Some clues from the slug of Dictyostelium discoideum

Starvation induces free-living Dictyostelium discoideum amoebae to form slugs that typically contain 100,000 cells. Only recently have sufficient clues become available to suggest how coordinated cell actions might result in slug movement. We propose a “squeeze-pull” model that involves circumferential cells squeezing forward a cellular core, followed by pulling up of the rear. This model takes into account the different classes of cells in the slug; it is proposed that prestalk cells are engines and prespore cells are the cargo.     

A method to study slug predation on seedlings in the field

Dandelion is a common Asteraceae species that populates disturbed sites and gaps within swards where it becomes an important competitor of grasses. The natural control against dandelion includes seedling predation, with slugs, particularly Arion lusitanicus, being the most important in the Czech Republic. However, the study of slug seedling consumption is difficult because naturally established seedlings are not always available. Therefore, we developed a method of exposing laboratory‐grown seedlings as bait for slug predation. Dandelion seeds were sown in plastic cups containing a bottom layer of moist substrate. The emerged seedlings were thinned to 20 and displayed in an open area. During 2008–2010, the seedling baits were placed at 15 sites at 1 month intervals throughout the dandelion vegetative season, in parallel with plasticine baits that monitored slug feeding activity. For each 1 month interval, seedling survival was observed for a period of 8 days, and the estimated time to death was calculated; the percentage of surviving seedlings was then recorded. This method of seedling presentation demonstrated that local and temporal variation in seedling survival is correlated with slug feeding activity. The advantage of this technique is that the seedlings in baits may be presented at any place and time, as required by the experimental design; however, we found that the estimated time to seedling death was shorter for the exposed baits than for the naturally established seedlings. The method is suitable for the study of plant species other than dandelion, and also for aims other than the study of spatiotemporal trends in seedling consumption by slugs.     

Isolation and characterization of a component of the surface sheath of Dictyostelium discoideum

Aggregates of Dictyostelium discoideum are surrounded by a surface sheath which functions to maintain polarity and integrity during development. We have isolated and partially characterized a component of the surface sheath. It is composed of 60% cellulose, 15% protein, 3% heteropolysaccharide (heteropolymer), 5% lipid, and 1% sulfate when isolated from migrating slugs. The sheath, isolated from aggregates prior to tip formation, has less protein, a different heteropolymer, and cellulose of a lower crystallinity than the sheath of migrating slugs. The increase in crystallinity of the cellulose during development may be important in determining the strength of the surface sheath.     

Pushing versus pulling: division of labour between tarsal attachment pads in cockroaches

Adhesive organs on the legs of arthropods and vertebrates are strongly direction dependent, making contact only when pulled towards the body but detaching when pushed away from it. Here we show that the two types of attachment pads found in cockroaches (Nauphoeta cinerea), tarsal euplantulae and pretarsal arolium, serve fundamentally different functions. Video recordings of vertical climbing revealed that euplantulae are almost exclusively engaged with the substrate when legs are pushing, whereas arolia make contact when pulling. Thus, upward-climbing cockroaches used front leg arolia and hind leg euplantulae, whereas hind leg arolia and front leg euplantulae were engaged during downward climbing. Single-leg friction force measurements showed that the arolium and euplantulae have an opposite direction dependence. Euplantulae achieved maximum friction when pushed distally, whereas arolium forces were maximal during proximal pulls. This direction dependence was not explained by the variation of shear stress but by different contact areas during pushing or pulling. The changes in contact area result from the arrangement of the flexible tarsal chain, tending to detach the arolium when pushing and to peel off euplantulae when in tension. Our results suggest that the euplantulae in cockroaches are not adhesive organs but 'friction pads', mainly providing the necessary traction during locomotion.     

Cell type proportioning in Dictyostelium slugs: lack of regulation within a 2.5-fold tolerance range

The proportion of prestalk and prespore cells in Dictyostelium discoideum slugs is often cited as an example of "almost perfect" regulation. The pattern is similar over a very wide range of cell number; furthermore, removal of either of the cell types leads to compensatory transdifferentiation. Several studies of Dictyostelium fruiting bodies, however, have suggested that proportioning in Dictyostelium differs systematically from true constancy. We have confirmed this in the slug stage using a short-lived beta-galactosidase as a reporter of the prestalk specific ecmA gene expression: the prestalk proportion decreases from 24+/-5% in slugs of 10(3) cells to 10+/-3% when 10(5) cells are present. Regeneration experiments suggest that this difference is not due to a modulation of the proportioning set-point by size, as one might have expected; instead there appears to be a regulatory "tolerance zone" at all sizes. After amputation of the whole posterior region, transdifferentiation stops after the fraction of prestalk has been reduced from 100% to 28+/-20%, well above the initial value of 10+/-3%, while after anterior removal the transdifferentiation endpoint is about 10%. Most strikingly, we find no regulation at all after partial amputations of the prespore region. It seems that any prestalk proportion is stable between a approximately 10% lower threshold and a approximately 30% upper threshold. To explain this, we propose a regulation mechanism based on a negative feedback plus cell type bistability. In both intact and regenerating slugs we find that the slug morphology is regulated so that the length-to-width ratio of the anterior region is constant.