A Deep Hidden Diversity of Dictyostelia.

Dictyostelia is a monophyletic group of transiently multicellular (sorocarpic) amoebae, whose study is currently limited to laboratory culture. This tends to favour faster growing species with robust sorocarps, while species with smaller more delicate sorocarps constitute most of the group's taxonomic breadth. The number of known species is also small (∼150) given Dictyostelia's molecular depth and apparent antiquity (>600 myr). Nonetheless, dictyostelid sequences are rarely recovered in culture independent sampling (ciPCR) surveys. We developed ciPCR primers to specifically target dictyostelid small subunit (SSU or 18S) rDNA and tested them on total DNAs extracted from a wide range of soils from five continents. The resulting clone libraries show mostly dictyostelid sequences (∼90%), and phylogenetic analyses of these sequences indicate novel lineages in all four dictyostelid families and most genera. This is especially true for the species-rich Heterostelium and Dictyosteliaceae but also the less species-rich Raperosteliaceae. However, the most novel deep branches are found in two very species-poor taxa, including the deepest branch yet seen in the highly divergent Cavenderiaceae. These results confirm a deep hidden diversity of Dictyostelia, potentially including novel morphologies and developmental schemes. The primers and protocols presented here should also enable more comprehensive studies of dictyostelid ecology.

Structure of the 34†kDa F-actin-bundling protein ABP34 from Dictyostelium discoideum.

The crystal structure of the 34 kDa F-actin-bundling protein ABP34 from Dictyostelium discoideum was solved by Ca(2+)/S-SAD phasing and refined at 1.89 Šresolution. ABP34 is a calcium-regulated actin-binding protein that cross-links actin filaments into bundles. Its in vitro F-actin-binding and F-actin-bundling activities were confirmed by a co-sedimentation assay and transmission electron microscopy. The co-localization of ABP34 with actin in cells was also verified. ABP34 adopts a two-domain structure with an EF-hand-containing N-domain and an actin-binding C-domain, but has no reported overall structural homologues. The EF-hand is occupied by a calcium ion with a pentagonal bipyramidal coordination as in the canonical EF-hand. The C-domain structure resembles a three-helical bundle and superposes well onto the rod-shaped helical structures of some cytoskeletal proteins. Residues 216-244 in the C-domain form part of the strongest actin-binding sites (193-254) and exhibit a conserved sequence with the actin-binding region of α-actinin and ABP120. Furthermore, the second helical region of the C-domain is kinked by a proline break, offering a convex surface towards the solvent area which is implicated in actin binding. The F-actin-binding model suggests that ABP34 binds to the side of the actin filament and residues 216-244 fit into a pocket between actin subdomains -1 and -2 through hydrophobic interactions. These studies provide insights into the calcium coordination in the EF-hand and F-actin-binding site in the C-domain of ABP34, which are associated through interdomain interactions.

Article for the "Free-living amoebae special issue": Isolation and characterisation of various amoebophagous fungi and evaluation of their prey spectrum.

This article gives an overview on the isolation and characterisation of endoparasitic fungi invading free-living amoebae (FLA), including the ones forming thalli inside their hosts such as Cochlonema euryblastum and also the predatory fungi which capture amoebae by adhesive hyphae. Acaulopage spp. and Stylopage spp. trap, intrude, and exploit amoebal trophozoites. Previous phylogenetic studies proved Cochlonema to be a member of the Zoopagales. The genetic investigation of Acaulopage tetraceros demonstrated its close relationship to Cochlonema. Co-cultivation of A. tetraceros with a number of FLA revealed a great prey spectrum of this amoebophageous fungus. In addition it was shown that solitary amoebal stages of slime moulds such as Dictyostelium sp. and Physarum sp. are also suited as welcome prey amoebae.

Collection and cultivation of dictyostelids from the wild.

Dictyostelium discoideum is a commonly used model organism for the study of biological processes such as chemotaxis, cell communication, and development. While these studies primarily focus on a single clone, recent work has revealed a host of questions that can only be answered from studies of multiple genetically distinct clones. Understanding intraspecific clone conflict, kin recognition, differential adhesion, and other kinds of interactions likely to occur in the natural soil habitat can only come from studies of multiple clones. Studies of populations of wild isolates are also important for understanding the factors contributing to associations such as species co-occurrences and to observed inter- and intraspecific interactions such as those found between bacteria and D. discoideum. Natural isolates of Dictyostelium are easily found in soil and leaf litter in nearly all habitats. Here we describe a simple and successful method for isolating new wild clones from soil, then isolating single clonal strains, and storing them for future use.

Purification of pathogen vacuoles from Legionella-infected phagocytes.

The opportunistic pathogen Legionella pneumophila is an amoeba-resistant bacterium, which also replicates in alveolar macrophages thus causing the severe pneumonia "Legionnaires' disease"(1). In protozoan and mammalian phagocytes, L. pneumophila employs a conserved mechanism to form a specific, replication-permissive compartment, the "Legionella-containing vacuole" (LCV). LCV formation requires the bacterial Icm/Dot type IV secretion system (T4SS), which translocates as many as 275 "effector" proteins into host cells. The effectors manipulate host proteins as well as lipids and communicate with secretory, endosomal and mitochondrial organelles(2-4). The formation of LCVs represents a complex, robust and redundant process, which is difficult to grasp in a reductionist manner. An integrative approach is required to comprehensively understand LCV formation, including a global analysis of pathogen-host factor interactions and their temporal and spatial dynamics. As a first step towards this goal, intact LCVs are purified and analyzed by proteomics and lipidomics. The composition and formation of pathogen-containing vacuoles has been investigated by proteomic analysis using liquid chromatography or 2-D gel electrophoresis coupled to mass-spectrometry. Vacuoles isolated from either the social soil amoeba Dictyostelium discoideum or mammalian phagocytes harboured Leishmania(5), Listeria(6), Mycobacterium(7), Rhodococcus(8), Salmonella(9) or Legionella spp.(10). However, the purification protocols employed in these studies are time-consuming and tedious, as they require e.g. electron microscopy to analyse LCV morphology, integrity and purity. Additionally, these protocols do not exploit specific features of the pathogen vacuole for enrichment. The method presented here overcomes these limitations by employing D. discoideum producing a fluorescent LCV marker and by targeting the bacterial effector protein SidC, which selectively anchors to the LCV membrane by binding to phosphatidylinositol 4-phosphate (PtdIns(4)P)(3,11) . LCVs are enriched in a first step by immuno-magnetic separation using an affinity-purified primary antibody against SidC and a secondary antibody coupled to magnetic beads, followed in a second step by a classical Histodenz density gradient centrifugation(12,13) (Fig. 1). A proteome study of isolated LCVs from D. discoideum revealed more than 560 host cell proteins, including proteins associated with phagocytic vesicles, mitochondria, ER and Golgi, as well as several GTPases, which have not been implicated in LCV formation before(13). LCVs enriched and purified with the protocol outlined here can be further analyzed by microscopy (immunofluorescence, electron microscopy), biochemical methods (Western blot) and proteomic or lipidomic approaches.

Automated segmentation of electron tomograms for a quantitative description of actin filament networks.

Cryo-electron tomography allows to visualize individual actin filaments and to describe the three-dimensional organization of actin networks in the context of unperturbed cellular environments. For a quantitative characterization of actin filament networks, the tomograms must be segmented in a reproducible manner. Here, we describe an automated procedure for the segmentation of actin filaments, which combines template matching with a new tracing algorithm. The result is a set of lines, each one representing the central line of a filament. As demonstrated with cryo-tomograms of cellular actin networks, these line sets can be used to characterize filament networks in terms of filament length, orientation, density, stiffness (persistence length), or the occurrence of branching points.

New species of dictyostelids from Patagonia and Tierra del Fuego, Argentina.

In late Jan and early Feb 2005 samples for isolation of dictyostelid cellular slime molds (dictyostelids) were collected in five different provinces and from six national parks (all located 39-55°S) in Patagonia and Tierra del Fuego, Argentina. Southern beech (Nothofagus) forests represented the primary vegetation type investigated, but some samples were obtained from Patagonian steppe, alpine meadows, Valdivian temperate rainforests and coniferous forests dominated by Araucaria, Austrocedrus and Fitzroya. Among the dictyostelids isolated from the samples we collected were seven species new to science. These species (Dictyostelium austroandinum, D. chordatum, D. fasciculoideum, D. gargantuum, D. leptosomopsis, D. valdivianum and Polysphondylium patagonicum) are described herein on the basis of both morphology and molecular (SSU rDNA) data. One of the new species, D. gargantuum, is one of the largest representatives of the group reported to date. Another unusual species, D. chordatum, produces long interwoven sorocarps that do not appear to respond to a spacing gas similar to the condition first noted in D. implicatum.

New species and new records of dictyostelids from Ukraine.

Three species of dictyostelid cellular slime molds were isolated from forest soil, meadow soil and leaf litter collected from Yalta, Crimea, Ukraine. Dictyostelium globisporum is new to science; D. crassicaule and D. sphaerocephalum are new records from Ukraine. Descriptions and illustrations are given based on the Ukraine specimens.

Dictyostelid cellular slime molds associated with grasslands of the central and western United States.

Dictyostelid cellular slime molds (dictyostelids) associated with grassland ecosystems of the central and western United States were investigated at nine sites that included examples of the three major ecological types of grasslands (tall grass, mixed grass and short grass) generally recognized for the region. Samples of soil/humus collected from each site were examined with the Cavender method of isolating dictyostelids. For each of those six sites with well developed gallery forests present, an additional set of forest soil/humus samples was collected. A more intensive sampling effort was carried out at one site (Konza LTER) to assess the possible effects of burning and grazing on dictyostelid diversity and density. Twelve species of dictyostelids were recovered from grassland sites, whereas gallery forest sites yielded only nine species. Four cosmopolitan species (Dictyostelium giganteum, D. mucoroides, D. sphaerocephalum and Polysphondylium pallidum) were represented by the greatest densities of clones, with D. sphaerocephalum particularly common. The general pattern across all sites was that both species richness and density of dictyostelids decreased with decreasing precipitation. Samples collected from ungrazed grassland plots yielded higher numbers of both species and clones as compared to grazed plots, and the general pattern was for both values to increase as the interval between fires increased. For numbers of clones this correlation was statistically significant.

Genetic heterogeneity in wild isolates of cellular slime mold social groups.

This study addresses the issues of spatial distribution, dispersal, and genetic heterogeneity in social groups of the cellular slime molds (CSMs). The CSMs are soil amoebae with an unusual life cycle that consists of alternating solitary and social phases. Because the social phase involves division of labor with what appears to be an extreme form of "altruism", the CSMs raise interesting evolutionary questions regarding the origin and maintenance of sociality. Knowledge of the genetic structure of social groups in the wild is necessary for answering these questions. We confirm that CSMs are widespread in undisturbed forest soil from South India. They are dispersed over long distances via the dung of a variety of large mammals. Consistent with this mode of dispersal, most social groups in the two species examined for detailed study, Dictyostelium giganteum and Dictyostelium purpureum, are multi-clonal.

Expression, identification and purification of Dictyostelium acetoacetyl-coa thiolase expressed in Escherichia coli.

Acetoacetyl-CoA thiolase (AT) is an enzyme that catalyses the CoA-dependent thiolytic cleavage of acetoacetyl-CoA to yield 2 molecules of acetyl-CoA, or the reverse condensation reaction. A full-length cDNA clone pBSGT-3, which has homology to known thiolases, was isolated from Dictyostelium cDNA library. Expression of the protein encoded in pBSGT-3 in Escherichia coli, its thiolase enzyme activity, and the amino acid sequence homology search revealed that pBSGT-3 encodes an AT. The recombinant AT (r-thiolase) was expressed in an active form in an E. coli expression system, and purified to homogeneity by selective ammonium sulfate fractionation and two steps of column chromatography. The purified enzyme exhibited a specific activity of 4.70 mU/mg protein. Its N-terminal sequence was (NH2)-Arg-Met-Tyr-Thr-Thr-Ala-Lys-Asn-Leu-Glu-, which corresponds to the sequence from positions 15 to 24 of the amino acid sequence deduced from pBSGT-3 clone. The r-thiolase in the inclusion body expressed highly in E. coli was the precursor form, which is slightly larger than the purified r-thiolase. When incubated with the cell-free extract of Dictyostelium cells, the precursor was converted to the same size to the purified r-thiolase, suggesting that the presequence at the N-terminus is removed by a Dictyostelium processing peptidase.

Desalted deep sea water increases transformation and homologous recombination efficiencies in Dictyostelium discoideum.

The life cycle of Dictyostelium discoideum consists of many cellular and developmental aspects. By virtue of its relatively high transformation efficiency and a small haploid genome, this organism has proven to be advantageous for characterizing gene functions. However, a much higher transformation efficiency is required as one of the prerequisites for unraveling gene function on a genome-wide scale. In this study, we describe the positive effect of desalted deep sea water, when used as a solvent medium, on the transformation and homologous recombination efficiencies in Dictyostelium. A standard Dictyostelium medium HL5 containing desalted deep sea water, HL5dsw, distinctly increased both the transformation and homologous recombination efficiencies by approximately 2- to 3-fold. Furthermore, we observed that the growth of cells in HL5dsw both before and after electroporation contributed to the increase in transformation efficiency. These results indicate that a simple modification of the solvent medium remarkably enhanced the isolation of transformants and gene-targeted clones, which had previously been difficult to isolate.

The Genome of Dictyostelium discoideum.

The Dictyostelium discoideum genome has been sequenced, assembled and annotated to a high degree of reliability. The parts-list of proteins and RNA encoded by the six chromosomes can now be accessed and analyzed. One of the initial surprises was the remarkably large number of genes that are shared with plants, animals, and fungi that must have been present in their common progenitor over a billion years ago. The genome encodes a total of about 10,300 proteins including protein families involved in cytoskeletal control, posttranslational protein modification, detoxification, secondary metabolism, cell adhesion, and signal transduction. The genome has a higher proportion of homopolymeric tracts and simple sequence repeats, such as [CAA]n, than most other genomes. Triplet repeats in translated regions produce the highest known proportion of polyglutamine tracts in any known proteome. Phylogenetic analyses based on complete proteomes confirm that the amoebozoa are a sister group to the animals and fungi, distinct from plants and early diverging species such as Leishmania, Plasmodium, or Giardia. The completed Dictyostelium sequence opens the door to large-scale functional exploration of its genome.

Purification techniques of subcellular compartments for analytical and preparative purposes.

In the following protocols, broken cells are the starting material of all downstream purifications of functional organelles or intact subcellular membranes. The choice of the breakage method has direct and deep repercussions on the quality of subsequent steps. Breaking vegetative amoebae by shear stress with a steel ball cell cracker preserves the integrity of subcellular organelles and in particular that of lysosomes, the rupture of which is very deleterious to further purifications. In this chapter, we propose purification schemes for plasma membrane, nuclei, mitochondria, and endocytic compartments. Plasma membranes are purified without any cell coating by partition between aqueous polymer phases. Nuclei and mitochondria are purified by differential centrifugations in adequate buffer conditions. Endosomes are magnetically isolated after feeding the cells with colloidal iron dextran and phagosomes by flotation on a sucrose gradient after feeding amoebae with latex beads. As analytical approaches, we propose procedures to label the plasma membrane and the endo-lysosomal compartments by biotinylation and to separate early and late compartments on a Percoll gradient.

The Dictyostelium genome.

The 34 Mb genome of Dictyostelium discoideum is carried on 6 chromosomes and has been fully sequenced by an international consortium. The sequence was assembled on the classical and physical maps that had been built up over the years and refined by HAPPY mapping. Annotation of the sequence predicted about 12,000 genes for proteins of at least 50 amino acids in length. The total number of amino acids encoded (the proteome) is more than double that in yeast and rivals that of metazoans. The genome sequence shows all the proteins available to Dictyostelium as well as definitively showing which domains have been lost since Dictyostelium diverged from the line leading to metazoans. Genomics opens the door to determining the expression patterns of all the genes during growth and development using microarrays. This approach has already uncovered a wealth of new markers for the stages of development and the various cell types. Transcription factors and their cis-regulatory sites that account for the surprising complexity of Dictyostelium development can be analyzed much more easily now that we have the complete sequence.

[Dictyostelids (Eumycetozoa) from soils of Punta Lara, Province of Buenos Aires, Argentina]. / Dictiostélidos (Eumycetozoa) de suelos de Punta Lara, Provincia de Buenos Aires, Argentina.

Five taxa of dictyostelid cellular slime molds were isolated from soil and litter samples of the relictual gallery forest of Punta Lara (34 degrees 47' S, 58 degrees 1' W), Province of Buenos Aires, Argentina. Dictyostelium lavandulum, D. polycephalum, D. purpureum and Polysphondylium violaceum were identified from most samples studied, whereas D. macrocephalum was isolated only once. Strains were lyophilized and kept in the BAFC Ceparium. Two additional isolated strains were related to D. sphaerocephalum, and to D. mucoroides var. stoloniferum. These species were likewise found, among others, in soils of the Iguazú National Park (Misiones, Argentina) in 1995.

Dictiostélidos (Eumycetozoa) de suelos de Punta Lara, Provincia de Buenos Aires, Argentina / Dictyostelids (Eumycetozoa) from soils of Punta Lara, Province of Buenos Aires, Argentina

Five taxa of dictyostelid cellular slime molds were isolated from soil and litter samples of the relictual gallery forest of Punta Lara (34 degrees 47 S, 58 degrees 1 W), Province of Buenos Aires, Argentina. Dictyostelium lavandulum, D. polycephalum, D. purpureum and Polysphondylium violaceum were identified from most samples studied, whereas D. macrocephalum was isolated only once. Strains were lyophilized and kept in the BAFC Ceparium. Two additional isolated strains were related to D. sphaerocephalum, and to D. mucoroides var. stoloniferum. These species were likewise found, among others, in soils of the Iguazú National Park (Misiones, Argentina) in 1995.(AU)

Clonagem e caracterização da serina/treonina fosfatase tipo 1(PP1) de Dictyostelium discoideum / Cloning and characterization of the serine/threonine phosphatase type 1(PP1) of Dictyostelium discoideum

A serina/treonina fosfatase tipo 1 (PP1) é uma enzima importante para diversos processos celulares nos eucariotos. Apesar disso, a atividade enzimática da PP1 nunca foi detectada em extratos celulares de Dictyostelium discoideum, ao contrário da atividade da enzima PP2A, que é outra proteína fosfatase de ocorrência geral nos eucariotos. Nesse estudo repostamos a clonagem e o sequenciamento de um cDNA codificador para a subunidade catalílitica da PP1 de D. discoideum. Verificamos que esse cDNA tem origem a partir de um gene em cópia única, que expressa uma proteína ao longo de todo o ciclo de vida desse organismo. A dedução da seqüência da proteína a partir do cDNA revela uma identidade de 80 por cento em média com as seqüências de outras PP1, sendo a principal diferença observada a substituição da cisteína 269 por uma fenilalanina...

Isolation of glycosylation mutants in Dictyostelium discoideum using flow cytometry.

Fluorescence-activated cell sorting was used to isolate five spores of the soil amoeba Dictyostelium discoideum that carried new glycosylation mutations, which were produced by restriction enzyme-mediated integration (REMI)-induced gene disruption and which occurred at frequencies of around 10(-5). These mutations were identified by the loss of an O-glycosylation epitope found on surface proteins of wild type D. discoideum spores that is recognised by the monoclonal antibody MUD62. A secondary antibody conjugated to the fluorochrome fluorescein isothiocyanate identified MUD62 bound to spores. Spores lacking this epitope did not fluoresce, allowing this population to be separated. Samples were found to contain around 0.1% of viable spores that were wild type but lacked the MUD62 epitope at the time of sorting. To remove these spores from the unlabelled population, samples were labelled with monoclonal antibody MUD50, which recognises surface proteins on immature spores and proteins exposed from an inner coat layer. Double labelling with MUD50 and MUD62 reduced the unlabelled viable population to less than 0.002%, allowing the glycosylation-defective spores to be isolated. This is the first use of a selective approach to isolate nonmorphological REMI-induced mutants in D. discoideum. This study also characterises the surface properties of spore types found in mature fruiting bodies of D. discoideum.