Endosymbionts in paramecium

Paramecium species are extremely valuable organisms to enable experiments for the reestablishment of endosymbiosis. This is investigated in two different systems, the first with Paramecium caudatum and the endonuclear symbiotic bacterium Holospora species. Although most endosymbiotic bacteria cannot grow outside the host cell as a result of their reduced genome size, Holospora species can maintain their infectivity for a limited time. We found that an 89-kDa periplasmic protein has an important function for Holospora's invasion into the target nucleus, and that Holospora alters the host gene expression; the host thereby acquires resistance against various stresses. The second system is the symbiosis between P. bursaria and symbiotic Chlorella. Alga-free P. bursaria and the algae retain the ability to grow without a partner. Consequently, endosymbiosis between the aposymbiotic host cells and the symbiotic algae can be reestablished easily by mixing them. We now found four checkpoints for the reestablishment of the endosymbiosis between P. bursaria and the algae. The findings in the two systems provide excellent opportunities for us to elucidate not only infection processes but also to assess the associations leading to eukaryotic cell evolution. This paper summarizes recent progresses on reestablishment of the primary and the secondary endosymbiosis in Paramecium.     

Motor activity of paramecium

A systemic study of the mechanisms of motor activity of paramecium was carried out. The movements of paramecium responding to various influences were photographed. The analysis of the data revealed the time dependences of the rate of movement, rate of rotation, and the radius and the pitch of the helix trajectory. Mathematical models of the membrane and a unit that transforms the calcium signal to programs of regulating the effectors were constructed. A system of equations for constructing the trajectory of movement was proposed. It is concluded that the biomolecular system that involves calmodulin, calmodulin-dependent ionic channels, adenylate cyclase, guanylate cyclase, phosphodiesterases, Ca(2+)-calmodulin, cAMP, cGMP-dependent protein kinases, and phosphoprotein phosphatases is capable of regulating motor reactions necessary for complex maneuvering of paramecium under various conditions.     

Positional Information and Positional Signalling in Hydra

A model is proposed for regulation and regeneration of the headend of hydra in terms of positional information, which involvestwo gradients. One is a diffusible substance made at the headend, which may be regarded as a positional signal. The otheris a more stable cellular parameter which is the positionalvalue. The rule for head end formation is that the concentrationof the diffusible substance falls a threshold amount below thepositional value. This model, for which some computer simulationis provided, can account for head end formation in a wide varietyof grafts. Evidence for a diffusable signal is provided by experimentsin which the time/distance relationships for head inhibitionby a grafted head are determined. Changes in positional valueduring regulation have been assayed and are much slower awayfrom the boundary. Polarity is interpreted in terms of the interactionbetween the two gradients. The biochemical basis of the gradientsis not known, but an approach to the problem has been made bytreating hydra with a variety of chemical agents.     

Positional information and gonadal differentiation in the planarian Dugesia lugubris (Turbellaria)

The planarian Dugesia lugubris is a balanced hermaphrodite, meaning that male genetic factors are in equilibrium with female factors. Differentiation of the gonads is controlled by the region in which they develop. According to the classical theory of germ cell formation, these cells stem from neoblasts that are induced to differentiate by factors specific to the gonadal regions, factors presumably due to gradients formed by neurosecretory activity of the cephalic ganglia and longitudinal nerve cords. A more recently proposed theory holds that germ cells in regenerates originate not from neoblasts but from dedifferentiated cells and that characteristics of the gonadal regions are determined by direct interactions of cells here. Results of our experiments with homo- and autoplastic grafst support the classical theory. Prepharyngeal portions grafted onto posterior body portions retained their ability to maintain or induce development of ovaries. Postpharyngeal portions grafted onto anterior portions produced only testes even though the brain developed normally in these regenerates. Under these experimental conditions, gonad regeneration took longer than it does in normal regeneration (i.e., that in which body regions are not displaced).Translated, from the French, by Marianne Klauser and Seth Tyler.     

Molecular genetics of regulated secretion in paramecium

Paramecium is a unicell in which cellular processes are amenable to genetic dissection. Regulated secretion, which designates a secretory pathway where secretory products are first stored in intracellular granules and then released by exocytotic membrane fusion upon external trigger, is an important function in Paramecium, involved in defensive response through the release of organelles called trichocysts. In this review, we focus on recent advances in the molecular genetics of two major aspects of the regulated pathway in Paramecium, the biogenesis of the secretory organelles and their exocytosis.     

Ion regulation in potassium-sensitive mutants of paramecium tetraurelia

Two recessive mutations of Paramecium tetraurelia confer sensitivity to potassium: While wild-type cells survive when up to 30 mM KCI is added to their growth medium, mutants cease to grow and die when levels of added KCl reach 20–25 mM. Similar sensitivities are seen to Rb⁺ and Cs⁺, but not to Na⁺. Swimming behavior of mutants is indistinguishable from wild type when place in stimulating solutions containing Na⁺, K⁺, or Ba²⁺. Behavioral adaptation to low levels of K⁺ also is indistiguishable from wild type. Flame photometry reveals that one mutant is unable to keep out K⁺ when that ion is at high levels in the medium, while the other mutant readily leaks K⁺ and Na⁺ when those ions are at low levels in the medium. Both mutants have markedly lower internal Na⁺ than does wild type. Problem with K⁺ permeability account for the sensitivity of the one mutant to elevated external K⁺, but the basis of sensitivity in the other mutant is unclear. These mutants expand the range of ion regulation mutants in Paramecium and demonstrate that lesions in cellular ion regulation in this organism need not result in changes in swimming behavior.     

The Trichocysts of Chilomonas paramecium*

SYNOPSIS Axenic cultures of Chilomonas paramecium were grown in media lacking a C-source, resulting in breakdown in autophagosomal vesicles of large numbers of trichocysts. Return of the starved organisms to complete media was followed by a wave of trichocyst formation. Stages in the degeneration and subsequent reformation of trichocysts are described as well as attempted labeling of the developing organelles with ³H-thymidine. A modification of the method of Anderson et al. (2) was used for isolating quantities of exploded trichocysts from Chilomonas. Attempts at isolation of the trichocyst in its coiled state were unsuccessful. Isolated trichocysts mounted on electron microscope grids were subjected to various types of enzymatic digestions.     

Induced Resistance to Sulfonamides in Chilomonas paramecium

SUMMARY. Strains of Chilomonas paramecium differing in degree of resistance to sulfanilamide have been established through acclimatization to this sulfonamide at 50, 100 and 200 mg. %. Resistant strains differ from the normal stock in their enhanced sensitivity to p -aminobenzoic acid. In the normal stock, sulfanilamide inhibition is reversed at an SA/PABA ratio of 10,000 but not at 20,000; in the least resistant strain, at a ratio of 400,000 but not at 800,000. In resistant strains inhibition is reversed by folk acid, methionine, adenine, cytosine and thymine; in the normal stock, none of these metabolites produces reversal. In high concentrations of PABA (10–20 mg. %) growth of the normal stock is only retarded, whereas the strain least resistant to sulfanilamide fails to recover from exposure to 20 mg. % PABA. The strain most resistant to sulfanilamide is most susceptible to PABA in high concentrations. The data suggest that resistance to sulfanilamide in C. paramecium may depend mainly upon an accelerated synthesis of PABA.