Targeted disruption of the ABP-120 gene leads to cells with altered motility.

The actin-binding protein ABP-120 has been proposed to play a role in cross-linking F-actin filaments during pseudopod formation in motile Dictyostelium amebas. We have tested this hypothesis by analyzing the phenotype of mutant cell lines which do not produce ABP-120. Two different transformation vectors capable of targeted disruption of the ABP-120 gene locus have been constructed using a portion of an ABP-120 cDNA clone. Three independent cell lines with different disruption events have been obtained after transformation of amebas with these vectors. The disruption of the ABP-120 gene by vector sequences results in either the production of a small amount of truncated ABP-120 or no detectable protein at all. The phenotypes of two different clones lacking ABP-120, generated in strains AX3 and AX4, have been characterized and show identical results. ABP-120- cells tend to remain rounder before and after cAMP stimulation, and do not reextend pseudopods normally after rapid addition of cAMP. In addition, ABP-120- cells translocating in buffer exhibit defects in both the rate and extent of pseudopod formation. The amount of F-actin cross-linked into the cytoskeleton after cAMP stimulation of ABP-120- cells is reduced at times when ABP-120 has been shown to be incorporated into the cytoskeleton, and this correlates temporally with the absence of reextension of pseudopods after cAMP stimulation. The instantaneous velocity is significantly reduced both before and after cAMP stimulation in the ABP-120- cells, and the cells show decreased chemotactic efficiency compared to ABP-120+ controls. This phenotype is consistent with a role for ABP-120 in pseudopod extension by cross-linking actin filaments as proposed by the "cortical expansion model" (Condeelis, J., A. Bresnick, M. Demma, C. Dharmawardhane, R. Eddy, A. L. Hall, R. Sauterer, and V. Warren. 1990. Dev. Genet. 11:333-340).

Antisense RNA inactivation of myosin heavy chain gene expression in Dictyostelium discoideum.

The role of myosin in the contraction of striated muscle cells is well known, but its importance in nonmuscle cells is not yet clear. The function of myosin in Dictyostelium discoideum has been investigated by isolating cells which specifically lack myosin heavy chain (MHC A) protein. Cells were transformed with a vector encoding RNA complementary to mhcA messenger RNA (antisense RNA). Stable transformants have a dramatic reduction in the amount of MHC A protein, grow slowly, and generate giant multinucleated progeny, indicating an impairment in cytokinesis. Surprisingly, the cells adhere to surfaces, extend pseudopods and are capable of ameboid locomotion. The developmental sequence that is initiated by starving cells is severely impaired by the lack of myosin. The cells are unable to form multicellular aggregates normally and do not undergo subsequent morphogenesis. By changing the food source from liquid medium to bacteria, expression of the endogenous mhcA messenger RNA can be increased relative to expression of antisense RNA. When grown in this way, the transformed cells accumulate MHC A protein, remain mononucleate, and proceed through development normally.

ReAsH: another viable option for in vivo protein labelling in Dictyostelium.

Biarsenical-tetracysteine fluorescent protein tagging has been effectively used in a variety of cell types. It has the advantage of requiring a much smaller peptide alteration to existing proteins than fusion to green fluorescent protein (GFP) or monomeric red fluorescent protein (mRFP). However, there are no reports of the tetracysteine tagging system being used in Dictyostelium. In order to establish this tagging system in Dictyostelium, the filamin gene (FLN) was modified to express a C-terminal tetracysteine sequence and then transfected into cells. After addition of either FlAsH-EDT(2) or ReAsH-EDT(2), the fluorescence intensity of cells increased in a time-dependent manner and reached a plateau after 3 h of incubation. ReAsH had a much stronger and more specifically localized fluorescent signal compared with FlAsH. After removal of the ReAsH-EDT(2) reagent, the fluorescence signal remained detectable for at least 24 h. The localization of filamin labelled by ReAsH was similar to that of an FLN-mRFP fusion protein, but the fluorescence signal from the ReAsH-labelled protein was stronger. Our findings suggest that the ReAsH-tetracysteine tagging system can be a useful alternative for in vivo protein tagging in Dictyostelium.

Use of a fusion protein between GFP and an actin-binding domain to visualize transient filamentous-actin structures.

Many important processes in eukaryotic cells involve changes in the quantity, location and the organization of actin filaments [1] [2] [3]. We have been able to visualize these changes in live cells using a fusion protein (GFP-ABD) comprising the green fluorescent protein (GFP) of Aequorea victoria and the 25 kDa highly conserved actin-binding domain (ABD) from the amino terminus of the actin cross-linking protein ABP-120 [4]. In live cells of the soil amoeba Dictyostelium that were expressing GFP-ABD, the three-dimensional architecture of the actin cortex was clearly visualized. The pattern of GFP-ABD fluorescence in these cells coincided with that of rhodamine-phalloidin, indicating that GFP-ABD specifically binds filamentous (F) actin. On the ventral surface of non-polarized vegetative cells, a broad ring of F actin periodically assembled and contracted, whereas in polarized cells there were transient punctate F-actin structures; cells cycled between the polarized and non-polarized morphologies. During the formation of pseudopods, an increase in fluorescence intensity coincided with the initial outward deformation of the membrane. This is consistent with the models of pseudopod extension that predict an increase in the local density of actin filaments. In conclusion, GFP-ABD specifically binds F actin and allows the visualization of F-actin dynamics and cellular behavior simultaneously.

Developmental regulation of Dictyostelium discoideum actin gene fusions carried on low-copy and high-copy transformation vectors.

The Dictyostelium discoideum genome contains an estimated 17 to 20 actin genes. We report the identification of a new member of this multigene family, actin 15, and its complete nucleotide sequence and transcription initiation sites. We constructed transformation vectors carrying either the actin 15 promoter fused to the neomycin phosphotransferase gene from transposon Tn903 or the actin 6 promoter fused to the neomycin phosphotransferase gene from Tn5. Cells transformed with the actin 15 vector carried less than five copies of vector DNA, while cells transformed with the actin 6 vector carried more than 200 copies. In both cases, the vector appeared to be integrated into the chromosome as a tandem array. Gene fusion RNAs transcribed from the actin 15 and actin 6 vectors were regulated like endogenous actin genes during D. discoideum development. DNA sequences required for temporal and cell type-specific regulation of these genes were contained within 2.8 kilobases of 5' noncoding DNA for actin 15 and 0.7 kilobases of 5' noncoding DNA for actin 6.

The rosy locus in Drosophila melanogaster: xanthine dehydrogenase and eye pigments.

The rosy gene in Drosophila melanogaster codes for the enzyme xanthine dehydrogenase (XDH). Mutants that have no enzyme activity are characterized by a brownish eye color phenotype reflecting a deficiency in the red eye pigment. Xanthine dehydrogenase is not synthesized in the eye, but rather is transported there. The present report describes the ultrastructural localization of XDH in the Drosophila eye. Three lines of evidence are presented demonstrating that XDH is sequestered within specific vacuoles, the type II pigment granules. Histochemical and antibody staining of frozen sections, as well as thin layer chromatography studies of several adult genotypes serve to examine some of the factors and genic interactions that may be involved in transport of XDH, and in eye pigment formation. While a specific function for XDH in the synthesis of the red, pteridine eye pigments remains unknown, these studies present evidence that: (1) the incorporation of XDH into the pigment granules requires specific interaction between a normal XDH molecule and one or more transport proteins; (2) the structural integrity of the pigment granule itself is dependent upon the presence of a normal balance of eye pigments, a notion advanced earlier.

Cytoskeletal alterations in Dictyostelium induced by expression of human cdc42.

The rho family of small G proteins has been shown to be involved in controlling actin filament dynamics in cells. To evaluate the functional overlap between human and Dictyostelium G proteins, we conditionally expressed constitutively active human cdc42 (V12-cdc42) in Dictyostelium cells. Upon induction, cells adopted a unique morphology: a flattened shape with wrinkles running from the cell edge toward the center. The appearance of these wrinkles is highly dynamic so that the cells cycle between the wrinkled and relatively normal morphologies. Phalloidin staining indicates that the stellate wrinkles contain dense actin structures and also that numerous filopods project vertically from the center of these cells. Consistent with the hypothesis that cdc42 induces actin polymerization in vivo, cells expressing V12-cdc42 show an increase in the amount of F-actin associated with the cytoskeleton. This is accompanied by an increase in the association of the actin-binding proteins 34-kDa bundler, ABP-120 and alpha-actinin with the cytoskeleton. In conclusion, human cdc42 has various effects on the Dictyostelium actin cytoskeleton consistent with a conserved role of small GTPases in control of the cytoskeleton.

Regulated expression of myosin II heavy chain and RacB using an inducible tRNA suppressor gene.

An inducible expression system that indirectly regulates gene expression through the use of an inducible suppressor tRNA has been used to express both endogenous and exogenous genes in Dictyostelium. The tetracycline repressor and tRNA suppressor (Glu) are expressed from a single G418 selectable vector, while a gene engineered to contain a stop codon is expressed from a separate hygromycin selectable vector. beta-Galactosidase could be induced over 300 fold with this system, and the extent of induction could be varied depending upon the amount of tetracycline added. It took 3 days to fully induce expression, and about 3 days for expression to decrease to baseline after removal of the tetracycline. Dictyostelium myosin II heavy chain could also be expressed in an inducible manner, although the induction ratio was not as high as beta-galactosidase and the maximum expression level was not as high as wild-type levels. A significant accumulation of the truncated peptide indicates that complete suppression of the stop codon was not achieved. Partial phenotypic reversion was observed in null mutants inducibly expressing myosin II. RacB could also be inducibly expressed, whereas the protein could not be expressed from a constitutive promoter, presumably because expression at high levels is lethal. Therefore, the inducible tRNA system can be used to control expression of endogenous Dictyostelium genes.

Secretory mutants in the cellular slime mold Dictyostelium discoideum.

Our initial studies have shown that the cellular slime mold Dictyostelium discoideum is a particularly suitable organism for the study of lysosomal enzyme secretion. During appropriate stages in the life cycle, secretion is prominent for a number of lysosomal enzymes. The methods described here have been developed to investigate various aspects of the secretion process. Moreover, our evidence that regulation of the secretory system is influenced by environmental changes and by cell differentiation indicates that this organism may be useful for studying the functional regulation of this organellar system. To a large degree these types of studies have been limited in the past due to the lack of an appropriate experimental system. The ability to isolate secretory mutants affecting the secretion of lysosomal enzymes adds another dimension to investigations using D. discoideum. In our initial attempts we have been successful in isolating a variety of different types of mutants that alter the secretion of one or more lysosomal enzymes. While the results are in agreement with the results of our physiological investigations, they also indicate much more heterogeneity in the lysosomal system than we had previously suspected. The indications that many of our secretory mutants may also affect modification of the enzymes is also intriguing. This observation may also help to explain the fact that many of these strains are defective in normal development. Together with the immunological methods available in this organism for studying posttranslational modification, the mutants may be valuable in deciphering the relationship between modification of lysosomal enzymes and their proper localization and secretion from the cell. Thus, Dictyostelium discoideum may become as useful for the study of some questions of cell biology as it has been for development.

Under-agarose folate chemotaxis of Dictyostelium discoideum amoebae in permissive and mechanically inhibited conditions.

Under-agarose chemotaxis has been used previously to assess the ability of neutrophils to respond to gradients of chemoattractant. We have adapted this assay to the chemotactic movement of Dictyostelium amoebae in response to folic acid. Troughs are used instead of wells to increase the area along which the cells can be visualized and to create a uniform front of moving cells. Imaging the transition zone where the cells first encounter the agarose, we find that the cells move perpendicular to the gradient and periodically manage to squeeze under the agarose and move up the gradient. As cells exit the troughs, their cross-sectional area increases as the cells become flattened. Three-dimensional reconstruction of confocal optical sections through GFP-labeled cells demonstrates that the increase in cross-sectional area is due to the flattening of the cells. Since the cells locally deform the agarose and become deformed by it, the concentration of the agarose, and therefore its stiffness, should affect the ability of the cells to migrate. Consistent with this hypothesis, cells in 0.5% agarose move faster and are less flat than cells under 2% agarose. Cells do not exit the troughs and move under 3% agarose at all. Therefore, this assay can be used to compare and quantify the ability of different cell types or mutant cell lines to move in a restrictive environment.

Automated real-time measurement of chemotactic cell motility.

We have developed a novel method, (ECIS/taxis), for monitoring cell movement in response to chemotactic and chemokinetic factors. In this system, cells migrate in an under-agarose environment, and their positions are monitored using the electric cell-substrate impedance sensor technology to measure the impedance change at a target electrode, that is lithographed onto the substrate, as the cells arrive at the target. In the studies reported here, Dictyostelium discoideum was used as a prototypical, motile eukaryotic cell. Using the ECIS/taxis system, the arrival of cells at the target electrode was proportional to the dose offolate used to stimulate the cells and could be assessed by changes in resistance at the electrode. ECIS/taxis was readily able to distinguish between wild-type cells and a mutant that is deficient in its chemotactic response. Finally, we have shown that an agent that interferes with chemotactic motility leads to the delayed arrival of cells at the target electrode. The multi-well assay configuration allows for simultaneous automated screening of many samples for chemotactic or anti-chemotactic activity. This assay system is compatible with measurements of mammalian cell movement and should be valuable in the assessment of both agonists and antagonists of cell movement.

Variables affecting antisense RNA inhibition of gene expression.

We have sought to determine what variables affect the extent of inhibition of gene expression by stable nuclear-derived antisense RNAs. Myosin heavy chain gene II (MHCII) expression in Dictyostelium was used as a model system, because previous results have shown that nearly complete inhibition of expression can be achieved under appropriate conditions. Various fragments of the myosin gene were inserted into several transformation vectors in both sense and antisense orientation, and the effects on expression of protein and RNA from the endogenous MHC II gene were assayed. The results indicate that the critical factor was the particular fragment of the gene used to produce the antisense RNA. Some fragments produced complete inhibition of expression, whereas others gave only slight inhibition. The fragments that produced the greatest inhibition were from the tail region of the gene. In addition, cells were capable of overcoming the inhibition while still expressing the antisense RNA. We hypothesize that the three-dimensional topology of the antisense and sense RNAs determines their accessibility for interstrand hybridization. Transformation with sense fragments of the myosin gene also caused inhibition of the endogenous myosin gene. The inhibition seen with sense expression is not as dramatic as that for antisense, but it had the same phenotypic consequences for the cells. This phenomenon, which has now been documented in other systems, may be mechanistically similar to inhibition by antisense RNA in our system.

Mechano-chemical signaling maintains the rapid movement of Dictyostelium cells.

The survival of Dictyostelium cells depends on their ability to efficiently chemotax, either towards food or to form multicellular aggregates. Although the involvement of Ca2+ signaling during chemotaxis is well known, it is not clear how this regulates cell movement. Previously, fish epithelial keratocytes have been shown to display transient increases in intracellular calcium ([Ca2+]i) that are mediated by stretch-activated calcium channels (SACs), which play a role in retraction of the cell body [J. Lee, A. Ishihara, G. Oxford, B. Johnson, and K. Jacobson, Regulation of cell movement is mediated by stretch-activated calcium channels. Nature, 1999. 400(6742): p. 382-6.]. To investigate the involvement of SACs in Dictyostelium movement we performed high resolution calcium imaging in wild-type (NC4A2) Dictyostelium cells to detect changes in [Ca2+]i. We observed small, brief, Ca2+ transients in randomly moving wild-type cells that were dependent on both intracellular and extracellular sources of calcium. Treatment of cells with the SAC blocker gadolinium (Gd3+) inhibited transients and decreased cell speed, consistent with the involvement of SACs in regulating Dictyostelium motility. Additional support for SAC activity was given by the increase in frequency of Ca2+ transients when Dictyostelium cells were moving on a more adhesive substratum or when they were mechanically stretched. We conclude that mechano-chemical signaling via SACs plays a major role in maintaining the rapid movement of Dictyostelium cells.

Developmental consequences of the lack of myosin heavy chain in Dictyostelium discoideum.

Two different Dictyostelium discoideum cell lines that lack myosin heavy chain protein (MHC A) have been previously described. One cell line (mhcA) was created by antisense RNA inactivation of the endogenous mRNA and the other (HMM) by insertional mutagenesis of the endogenous myosin gene. The two cell lines show similar developmental defects; they are delayed in aggregation and become arrested at the mound stage. However, when cells that lack myosin heavy chain are mixed with wild-type cells, some of the mutant cells are capable of completing development to form mature spores. The pattern of expression of a number of developmentally regulated genes has been examined in both mutant cell lines. Although morphogenesis becomes aberrant before aggregation is completed, all of the markers that we have examined are expressed normally. These include genes expressed prior to aggregation as well as prespore genes expressed later in development. It appears that the signals necessary for cell-type differentiation are generated in the aborted structures formed by cells lacking MHC A. The mhcA cells have negligible amounts of MHC A protein while the HMM cells express normal amounts of a fragment of the myosin heavy chain protein similar to heavy meromyosin (HMM). The expression of myosin light chain was examined in these two cell lines. HMM cells accumulate normal amounts of the 18,000-D light chain, while the amount of light chain in mhcA cells is dramatically reduced. It is likely that the light chains assemble normally with the HMM fragment in HMM cells, while in cells lacking myosin heavy chain (mhcA) the light chains are unstable.

Lysosomal enzymes possess a common antigenic determinant in the cellular slime mold, Dictyostelium discoideum.

Antisera have been prepared against two lysosomal enzymes of the cellular slime mold, Dictyostelium discoideum. The two purified enzyme preparations used for immunization, N-acetylglucosaminidase and beta-glucosidase-1, show no cross-contamination with each other and no significant contamination by other lysosomal enzymes. However, antisera raised against either enzyme bind equally well to seven different lysosomal enzymes and show no preference for the enzyme against which they were raised. A total of 10 different antisera have been examined and all show similar results. Preadsorption of antisera with either purified enzyme removes all antibody activity against the other enzyme. Evidence is presented which indicates that the same species of antibodies are responsible for the precipitation of seven lysosomal enzymes. These data are discussed in terms of the proposal that the antigen that is shared by the lysosomal enzymes is a post-translational modification of the enzyme proteins. We have sought to further characterize the distribution of this common antigen among cellular proteins. We show that N-acetylglucosaminidase and beta-glucosidase-1 represent less than 5% of the total common antigen containing proteins in the cell. Precipitation of 35S-labeled cellular proteins from vegetative cells indicates that as much as 15-30% of the total cell protein may possess the common antigen. Preadsorption experiments confirm that all of the proteins immunoprecipitated in these experiments are recognized by the same antibodies that precipitate the lysosomal enzyme activities. Most of the labeled proteins are secreted into the medium along with the lysosomal enzyme activities during axenic growth. During the developmental phase of the life cycle of Dictyostelium, the total amount of the common antigen decreases about 2-fold relative to total cell protein. However, the synthesis of antigenic proteins continues throughout most of development.

Visualization of antigenic proteins on Western blots.

A new technique for the detection of antibodies bound to proteins blotted onto nitrocellulose paper was developed. The method is rapid, sensitive, and does not require radioactive probes. Proteins transferred to nitrocellulose paper are first reacted with primary antibody followed by reaction with an alkaline phosphatase conjugated second antibody. The phosphatase activity is then visualized using an agar gel impregnated with the histochemical phosphatase stain 5-bromo-4-chloro-3-indolyl phosphate (BCIP) (J. P. Horwitz, J. Chua, M. Noel, J. T. Donatti, and J. Freisler (1966) J. Med. Chem. 9, 447; Sigma Chemical Co., Technical bulletin No. 710-EP (1978]. Antigen-antibody complexes give rise to sharp, permanent blue stained bands both on the nitrocellulose paper and in the agar overlay gel. This procedure allows detection of bands containing less than 20 ng of protein.