Differences in the motility of Amoeba proteus isolated fragments are determined by F-actin arrangement and cell nucleus presence

Isolated fragments produced by bisection of Amoeba proteus differ by their position in the original cell and by the presence or absence of the cell nucleus. Immediately after the operation, both types of anterior fragments preserve the former motory polarity, and do not interrupt locomotion. In the same time, all posterior fragments stop, round up and fail to react stimuli. In the second phase of experiment, these anterior fragments, which had no nucleus ceased to move, whereas the nucleated posterior ones resumed locomotion. It was demonstrated, that the behaviour of a fragment is primarily determined by the peripheral F-actin distribution, which is different depending on the origin of the fragment either from the anterior or from the posterior cell region. Later, the "inherited" F-actin distribution may be stabilized or reorganized in the presence of the nucleus, or desorganized in its absence.     

Phosphorylation of Amoeba G-actin and its effect on actin polymerization

Mass culture of Amoeba proteus enabled us to do biochemical studies on this organism. Actin and profilin were purified from Amoeba to examine actin phosphorylation and polymerization. The apparent molecular weight of Amoeba actin was 44,000, and its isoelectric point was 5.8. The apparent molecular weight of Amoeba profilin was 12,000, and its isoelectric point was 4.9. It reduced the rate of actin polymerization as reported in the cases of profilins from other organisms. A protein of Mr = 44,000 (44 K protein) was phosphorylated in a Ca2+-dependent manner in cell homogenate of Amoeba without being inhibited by calmodulin antagonists. Using the homogenate as a kinase, purified Amoeba G-actin could be phosphorylated in proportion to the amount of actin. However, neither Amoeba F-actin nor rabbit skeletal muscle G-actin was phosphorylated. The phosphorylation of Amoeba actin with a kinase partially purified from A. proteus increased with dilution of the actin concentration. When Amoeba profilin was added, more than 80% of the actin was phosphorylated. By viscometry, electron microscopy, and ultracentrifugation analysis it was demonstrated that Amoeba G-actin phosphorylated in the presence of profilin and kinase did not polymerize in this solution. High-performance liquid chromatography analysis showed that phosphorylated Amoeba actin remained in a monomeric state even under conditions favorable for actin polymerization.     

Scanning electron microscope observations of Amoeba proteus during phagocytosis.

Phagocytosing Amoeba proteus at different stages of forming foodcups have been observed by scanning electron microscopy. A nonphagocytosing ameba is characterized by dorsal and lateral ridges running longitudinally over the posterior half of the cell and its attachment to the substrate over small areas. When stimulated by prey organisms, the ameba loses polarity and ridges, and adheres to the substrate more firmly over a wider area of contact. Then it forms broad pseudopods to surround its prey and this results in the formation of foodcups. The surface of all ameba is covered with small projections, and membranous blebs are often seen on the surface of phagocytosing organisms.     

Dynamics of the cytoskeleton in Amoeba proteus

Fluorescein-labeled muscle actin was microinjected into Amoeba proteus and followed during intracellular redistribution by means of the image-intensification technique. The fully polymerization-competent protein becomes part of the endogenous actomyosin system undergoing dynamic changes over time periods of several hours. Single-frame analysis of long-term sequences enabled the direct demonstration of both the contractile activities and morphological transformations of microfilaments in normally locomoting, immobilized and phagocytozing specimens. In normally locomoting cells the filament layer undergoes continuous changes in spatial distribution depending on the actual pattern of cytoplasmic streaming and cell shape. The highest degree of differentiation is always maintained in the intermediate region between the front and the uroid, thus indicating this segment of the cortex to be the most important site in generating motive force for pseudopodium formation and ameboid movement. In immobilized cells contracted by the application of ruthenium red or relaxed by different anesthetics, the filament layer forms a continuous thick sheath beneath the cell surface or becomes completely disintegrated. In phagocytozing cells the local polymerization of actin at the tip of pseudopodia forming the food-cup and around the nascent phagosome points to a significant participation of the actomyosin system in the process of capturing and constricting prey organisms. Although our results provide clear evidence for the overall importance of motive force generation according to the hydraulic pressure theory, some motile phenomena exist in Amoeba proteus that cannot exclusively be explained by this mechanism.     

MINIPODIA AND ROSETTE CONTACTS ARE ADHESIVE ORGANELLES PRESENT IN FREE-LIVING AMOEBAE

Using scanning electron microscopy, Amoeba proteus cells migrating on the glass have been shown to develop dense coats of minipodia, which are discrete microprotrusions up to 8 microm long and approximately 0.5 microm across. They cover the middle-anterior area of the ventral cell surface, i.e. the region previously determined as the zone of most efficient adhesion of an amoeba to its substratum. Minipodia are sparse underneath the frontal zone and lacking from the tail region. In amoebae that adhere to the glass without moving, have just started moving, or show unstable motor polarity, minipodia are grouped in rosette contacts, cauliflower-like papillae composed of supporting platforms with crowns of minipodia emerging from them. Both structures abound with cytoskeletal F-actin, as shown by staining with fluorescein-conjugated phalloidin. Amoebae experimentally prevented from adhering to the substratum neither develop discrete minipodia nor rosette contacts.     

Photophobic and phototactic responses of Amoeba proteus in KCN and SHAM solutions

The effects of the metabolic inhibitors KCN and SHAM on phototaxis and photophobic response in Amoeba proteus have been studied. Both drugs neither change amoebae photophobic response nor the phototactic reaction. The results indicate clearly that the negative phototactic orientation is not impaired by impediment of respiration thus it is not directly coupled to the differences in energy production in different parts of A. proteus body.     

Polarity of Acetabularia mediterranea: Stability in the Anucleate State

Concomitant with the outgrowth of the cap in cells of Acetabulariamediterranea Lamouroux, the stalk acquires a pale green appearance(‘Aufhellung’) and the chlorophyll and protein contentdecreases due to the translocation of part of the cytoplasmfrom the stalk into the cap. This process also occurs in anucleatecells or apical fragments during cap formation and in inversegrafts constructed either from two anucleate cells or apicalfragments or from two basal fragments containing the rhizoids.The cytoplasm's translocation does not depend on the presenceof the nucleus. It is suggested that the unidirectional flowof the cytoplasm during cap formation is generated by the electricalcharge across the cell and that this electrical charge is maintainedafter removal of the nucleus. Acetabularia, polarity, anucleate cells, grafts     

Defense function of pigment granules in the ciliate Blepharisma japonicum against two predatory protists, Amoeba proteus (Rhizopodea) and Climacostomum virens (Ciliata)

The defense function of pigment granules in the red ciliate Blepharisma japonicum against two predatory protists, Amoeba proteus and Climacostomum virens, was investigated by (1) comparing normally-pigmented and albino mutant cells of B. japonicum as the prey of these predators and (2) comparing resistance of the predators to blepharismin, the toxic pigment contained in the pigment granules of B. japonicum. Normally pigmented cells which contained more blepharismin than albino cells were less vulnerable to A. proteus than albino cells, but not to C. virens. C. virens was more resistant than A. proteus to the lethal effect of blepharismin. The results indicate that pigment granules of B. japonicum function as defense organelles against A. proteus but not against C. virens and suggest that successful defense against a predator depends on the susceptibility of the predator to blepharismin.     

Osmotic homeostasis in the freshwater ameba

Structural and physiological osmotic adaptations of freshwater protozoa are reviewed using Amoeba proteus as an example. A particular emphasis is given to the contractile vacuole. Recent results on the effects of exogenous ATP and vasopressin on the contractile vacuole are also presented.     

CYTOPLASMIC DNA SYNTHESIS IN AMOEBA PROTEUS : II. On the Behavior and Possible Nature of the DNA-Containing Elements

Nucleic acid-containing particles in the cytoplasm of Amoeba proteus (cf. reference 1) were counted after acridine orange staining. The number of particles per ameba was found to be correlated with cell age and size. Fresh daughters had a mean particle number of 5400, whereas predivision amebae contained around 11,000 particles. Amebae from two other strains contained similar particles. The particles were found to be clustered in fasted cells and redispersed after feeding. A marked increase in the particle population was noted in anucleate fragments. These results, together with those previously presented, suggest that the particles multiply intracellularly. Their nature and their relationship to previous work on nucleic acid labeling in Amoeba are discussed.     

Is actin involved in the nuclear division in Amoeba proteus?

During semi-open mitosis of Amoeba proteus the nuclear envelope is not dispersed and nucleus divides by fission. The presence of actin layer close to nuclear envelope was demonstrated in interphase and telophase nuclei of that amoeba stained with rhodamine labelled phalloidin. In telophase, an accumulation of actin arises in the space between the future daughter nuclei. It appears to be comparable with the contractile ring of dividing cells. This suggests that actin associated with the nuclear envelope of Amoeba proteus may be involved in final separation of the daughter nuclei, forming a constriction ring at the middle of dividing nucleus.     

Electrophoretic forms of glucose-6-phosphate dehydrogenase, acid phosphatase and esterase in Amoeba species amoebas

Glucose-6-phosphate dehydrogenase (G6PD), acid phosphatase and esterases in free-living amoebae of 7 Amoeba species were investigated with the use of disc-electrophoresis in polyacrylamide gel. The evidence provided is suggestive that the electrophoretic isoenzyme patterns of acid phosphatase and esterases (and G6PD in some cases), in addition to a few morphological characters, can serve as a taxonomic criterion for species identification within this genus, as well as for revealing erroneously classified species and strains. It is suggested that A. indica is an independent species whose preliminary diagnosis has been given in this paper. It is concluded that A. discoides and A. lescherae are strains of A. proteus, rather than two independent species. A and As-102 amoebian strains, kept in the collection of protozoan strains and species of the Institute of Cytology RAS and referred to as strains of A. proteus, belong in reality to another Amoeba species and even to another genus within the family Amoebidae. This conclusion has been documented by results of our analysis of electrophoretic patterns of acid phosphatase and esterases in these strains.     

Studies on changes in the nuclear helices of Amoeba proteus during the cell cycle.

The fine structure of the nuclei of synchronously growing cell population of Amoeba proteus was studied at I-h intervals during the interphase. This study showed that the nuclear helices undergo increases in their number at certain stages during interphase. These changes were found to correlate with ultrastructural changes occurring in the nucleoli.     

Ca2+-binding modulator protein in protozoa and myxomycete.

Ca2+-binding protein with the properties of brain modulator protein of 3,5-cyclic nucleotide phosphodiesterase was identified in Physarum polycephalum plasmodia and in Euglena gracilis and Amoeba proteus cells by urea polyacrylamide gel electrophoresis and activation of cyclic nucleotide phosphodiesterase and of myosin light chain kinase.     

Selective effects of enucleation and transfer of heterologous nuclei on cytoplasmic organelles in Amoeba proteus.

The ultrastructural changes in the cytoplasm of lethal hybrids obtained by nuclear transplantation between different strains of Amoeba proteus were compared with those of enucleated amebae. It was found that, whereas the Golgi complex and glycocalyx degenerated first in enucleated cells, mitochondria and endosymbiotes became abnormal first in the hybrids. The selective effects are attributed to the presence of nucleic acids in the mitochondria and endosymbiotes and hence to the different interactions they would have with the nuclear genome.     

Isolation and partial characterization of two plasmid deoxyribonucleic acids from endosymbiotic bacteria of Amoeba proteus.

Obligatory endosymbiotic bacteria in a strain of Amoeba proteus were found to harbor two distinct species of plasmid, pHJ11 and pHJ12. Their molecular weights were 39 x 10(6) and 14 x 10(6), respectively.     

Adhesion to the substratum improves the motility ofAmoeba proteus in the absence of a cell nucleus

Summary Anucleated fragments ofAmoeba proteus obtained by dissection and kept on an untreated glass surface fail to adhere to this substratum, lose motor polarity, and stop moving, at least for several hours. If they are transferred after the operation to a highly adhesive surface (polylysine-coated glass), they adhere to the substratum, although locomotion is not spontaneously restored. However, after exposure to a light-shade difference along their body they start moving towards the shaded area and continue locomotion as long as the photic stimulus is acting. Disorganisation of the F-actin cytoskeleton of anucleated fragments was observed on the untreated glass but reorganization on the polylysine-coated surface. The anucleated fragments can show transient recovery of slight spontaneous motor activity and react promptly to external stimuli after up to several days on untreated glass. These intermittent activity periods are enabled by reconstruction of F-actin cytoskeleton in the anucleated fragments during their temporary adhesion to the glass. It is concluded that the injurious effect of cell nucleus removal on the locomotor capacity of amoebae can be compensated by the simultaneous enhancement of cell adhesion and application of a stimulus restoring the motor polarity of the cell. The compensation is achieved by cytoskeletal reorganization.     

Bacterial endosymbiosis in amoebae

The large, free-living amoebae are inherently phagocytic. They capture, ingest and digest microbes within their phagolysosomes, including those that survive in other cells. One exception is an unidentified strain of Gram-negative, rod-shaped bacteria that spontaneously infected the D strain of Amoeba proteus and came to survive inside them. These bacteria established a stable symbiotic relationship with amoebae that has resulted in phenotypic modulation of the host and mutual dependence for survival.     

Cytoplasmic control of nuclear maturation in mouse oocytes

Oocytes with germinal vesicles were cut into anucleate and nucleate fragments. At the time of germinal vesicle breakdown (GVBD) in nucleate fragments (after 2–3 h of culture) sister anucleate fragments were fused with the help of inactivated Sendai virus with interphase blastomeres from 2-cell embryos. The hybrid cells were examined after h and 20 h. The anucleate fragments induced chromosome condensation in the nuclei of interphase blastomeres immediately after fusion. On this basis it may be concluded that GVBD and nuclear maturation in mouse oocytes is induced by a cytoplasmic factor which is produced or unmasked independently of the nucleus.     

The Isolation, Characterization, and Identification of the Crystalline Inclusions of the Large Free-Living Amebae

Amoeba proteus, Amoeba dubia, and Chaos chaos all contain similar plate-like and bipyramidal cytoplasmic crystals. Isolated crystals, purified by recrystallization from water, yield plate-like crystals which have been shown to be identical with synthesized carbonyl diurea (triuret) with regard to physicochemical properties, elemental analysis, x-ray diffraction patterns, infrared spectra, and optical properties. The birefringent plates found in the cytoplasm are carbonyl diurea. While the exact composition of the isotropic plates and of the bipyramids is not clear at present, the major constituent of these crystal types is also carbonyl diurea. It is suggested that carbonyl diurea is a nitrogen excretion product, not previously found in living organisms, and probably represents an end product of purine metabolism in amebae.