Rac1B, a small GTP-binding protein in Dictyostelium discoideum, is involved in regulation of the actin cytoskeleton. Scanning electron microscopy revealed distinctive phenotypes for the wild-type, constitutively active, constitutively inactive and overexpressing cell lines. Immunofluorescence showed constitutively active Rac1B localized to lamellipodia and sites of cell-to-cell contact. In contrast, constitutively inactive Rac1B was homogeneously distributed throughout the cell. Phalloidin staining demonstrated that active Rac1B co-localizes with F-actin. Amoebae expressing mutant Rac1B exhibited defects in endocytosis, cytokinesis and multicellular development. Overexpression of wild-type Rac1B positively affected fluid-phase endocytosis, whereas expression of either constitutively active or inactive forms of Rac1B inhibited endocytic rates. The greatest defects in cytokinesis were observed in amoebae producing constitutively active Rac1B or overexpressing wild-type Rac1B. These cells were severely multinucleated and divided by traction-mediated cytofission when placed onto a solid surface. Cells expressing mutant Rac1B were unable to form viable fruiting bodies. Elucidating the role of Rac1B in filamentous actin dynamics will lead to a better understanding of cell adhesion, development and cell motility.
Stemonitis flavogenita, an acellular slime mold displays protist, fungal and animal attributes. These properties make classifying organisms such as Stemonitis difficult. The spores germinate, and give rise to either haploid flagellated swarm cells, or haploid myxamoebae. The myxamoebae resemble protists. When the environment changes, the swarm cells may resorb their flagella and become myxamoebae. These cells will fuse to make a new diploid plasmodium, which will move around assimilating nutrients in moist places such as leaf litter or on decaying logs [1]. These single celled, multinucleated plasmodia can be very large, reaching diameters of one to two feet, if conditions permit. The large plasmodium pumps protoplasm back and forth through the cell in specialized channels to transport nutrients and oxygen throughout the organism (Fig. 1). This appearance of vessels pumping protoplasm resembles a rudimentary vascular system, and initially lead to potential classification as an animal. However it is the formation of spores that ultimately leads to the classification as fungi.The plasmodium is initially referred to as a microplasmodium because of its size, and then when visible to the eye without the aid of a microscope it is a plasmodium. In Stemonitis, the cell grows and becomes an assimilative aphanoplasmodium, which contains a thin network of anastomosed veins [2]. The movement of the cytoplasm in these veins may be directly dependent on the cytoskeleton. Staining of kinesin shows localization to veins in the aphanoplasmodium, and high concentrations within membrane ruffles (Fig. 2).When conditions become dry, the plasmodium will change to the coralloid stage, condensing and moving away from the moist substrate prior to forming sporangia. The sporangia form by pumping protoplasm upward and forming a stalk (Fig. 3). Protoplasm is then pumped upward on top of the stalk and will cleave to form spores. The process of moving the protoplasm up the stalk involves numerous cytoskeletal elements. Figure 4 shows localization of the motor protein kinesin in a developing sporangium, indicating the movement of cellular components on microtubules. Spores produced allow the organism to survive unfavorable conditions, because the spores are very resistant to desiccation, even for long periods of time [1].The use of environmental scanning electron microscopy is useful for analysis of many microorganisms [3], including the stages of the myxomycete life cycle, as is evident by the examination of cross sections of freshly formed sporangia (Figs. 5 & 6). The uncoated samples show the spacing and distribution of spores and capletial threads inside the sporangium. The outer covering (peridium) is visible at the bottom of Figure 5. This is especially useful in looking for calcium deposition that is common in many myxomycetes after the formation of sporangia. REFERENCES 1. Alexopoulos, C. J., and Mims, C. W. Class Myxomycetes. Introductory Mycology, 3rd ed.; Wiley & Sons: New York, 1979; pp 61-98. 2. Collins, S. P. Cytoplasmic Elements...
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