R-body-producing bacteria.

Until 10 years ago, R bodies were known only as diagnostic features by which endosymbionts of paramecia were identified as kappa particles. They were thought to be limited to the cytoplasm of two species in the Paramecium aurelia species complex. Now, R bodies have been found in free-living bacteria and other Paramecium species. The organisms now known to form R bodies include the cytoplasmic kappa endosymbionts of P. biaurelia and P. tetraurelia, the macronuclear kappa endosymbionts of P. caudatum, Pseudomonas avenae (a free-living plant pathogen), Pseudomonas taeniospiralis (a hydrogen-oxidizing soil microorganism), Rhodospirillum centenum (a photosynthetic bacterium), and a soil bacterium, EPS-5028, which is probably a pseudomonad. R bodies themselves fall into five distinct groups, distinguished by size, the morphology of the R-body ribbons, and the unrolling behavior of wound R bodies. In recent years, the inherent difficulties in studying the organization and assembly of R bodies by the obligate endosymbiont kappa, have been alleviated by cloning and expressing genetic determinants for these R bodies (type 51) in Escherichia coli. Type 51 R-body synthesis requires three low-molecular-mass polypeptides. One of these is modified posttranslationally, giving rise to 12 polypeptide species, which are the major structural subunits of the R body. R bodies are encoded in kappa species by extrachromosomal elements. Type 51 R bodies, produced in Caedibacter taeniospiralis, are encoded by a plasmid, whereas bacteriophage genomes probably control R-body synthesis in other kappa species. However, there is no evidence that either bacteriophages or plasmids are present in P. avenae or P. taeniospiralis. No sequence homology was detected between type 51 R-body-encoding DNA and DNA from any R-body-producing species, except C. varicaedens 1038. The evolutionary relatedness of different types of R bodies remains unknown.     

Tracing the role of R-bodies in the killer trait: Absence of toxicity of R-body producing recombinant E. coli on paramecia

R-bodies are coiled proteinaceous ribbons produced by Paramecium endosymbionts belonging to the genus Caedibacter. These intracellular bacteria confer upon their hosts a phenomenon called the killer trait. It is the ability to kill symbiont-free competitors called sensitives. The R-body is the crucial element of this process, but despite many efforts, the actual role of R-bodies in killing sensitive paramecia is still not satisfactory clarified. The open question is whether the R-body acts as transmitter for a yet unidentified toxin or whether it directly kills sensitive paramecia having intrinsic cytotoxic effects. In the present study, this problem is addressed by heterologous expression of Caedibacter taeniospiralis R-body in Escherichia coli followed by a detailed analysis of its potential intrinsic toxic effect on feeding sensitive Paramecium tetraurelia. Using this approach, we can exclude any eventual effects of additional, unidentified factors produced by C. taeniospiralis and thus observe the impact of the recombinant R-body itself. No cytotoxic effects of recombinant R-bodies were detected following this approach, strengthening the hypothesis that R-bodies act as releasing system for an unidentified C. taeniospiralis toxin.     

Characterization of genetic determinants for R body synthesis and assembly in Caedibacter taeniospiralis 47 and 116.

Caedibacter taeniospiralis, an obligate bacterial endosymbiont of Paramecium tetraurelia, confers a killing trait upon its host paramecium. Type 51 R bodies (refractile inclusion bodies) are synthesized by these endosymbionts and are required for expression of the killing trait. The nucleotide sequence of the genetic determinants for type 51 R body synthesis and assembly was determined for C. taeniospiralis 47 and 116. Three independently transcribed genes (rebA, rebB, and rebC) were characterized. To date these are the only genes from C. taeniospiralis to be sequenced and characterized. DNA regulatory regions are recognized by Escherichia coli, and codon usage appears similar to that in E. coli. A fourth open reading frame with appropriate regulatory sequences was found within the reb locus, but no evidence was obtained to suggest that this putative gene is expressed in E. coli. The R body-encoding sequences from both strains are identical. Two-dimensional gel electrophoresis of deletion derivatives shows that two polymerization events are involved in R body assembly. One polymerization event requires only RebB and RebC; the other requires all three proteins. Expression of RebC is necessary for the posttranslational modification of RebA and RebB into species with three and two different molecular weights, respectively. In the presence of RebC, each species of RebB with a different molecular weight has six different isoelectric points.     

Characterization of Caedibacter endonucleobionts from the macronucleus of Paramecium caudatum and the identification of a mutant with blocked R-body synthesis

Cytology, DNA and host-symbiont relationships of x-like endosymbionts from Paramecium caudatum are described. The symbionts (Caedibacter caryophila, sp. nov.) live in the macronuclei of their hosts. They confer the killer trait upon their hosts and appear well adapted to their endonucleobiotic way of life. R bodies (proteinaceous ribbons associated with killing) are produced, but differ significantly from any of the four R-body classes previously described. C. caryophila and their R bodies were isolated. DNA was extracted from purified symbionts and used to demonstrate that one P. caudatum line harbors a natural mutant which is deficient in R-body production. Melting studies indicate a GC content of 34.6%. No sequence homology between the C. caryophila DNA and the coding sequence for type 51 R-body production was observed. C. caryophila is parasitic, causing the death of its hosts in starving cultures.     

Comparative study of refractile (R) bodies and their genetic determinants: relationship of type 51 R bodies to R bodies produced by Pseudomonas taeniospiralis.

The relationship of type 51 refractile (R) bodies to R bodies produced by Pseudomonas taeniospiralis was investigated. Proteins associated with type 51 R bodies were not serologically cross-reactive with proteins associated with R bodies from P. taeniospiralis. The genetic determinants for type 51 R bodies did not exhibit close homology with DNA sequences from P. taeniospiralis.     

The genus Caedibacter comprises endosymbionts of Paramecium spp. related to the Rickettsiales (Alphaproteobacteria) and to Francisella tularensis (Gammaproteobacteria)

Obligate bacterial endosymbionts of paramecia able to form refractile inclusion bodies (R bodies), thereby conferring a killer trait upon their ciliate hosts, have traditionally been grouped into the genus CAEDIBACTER: Of the six species described to date, only the Paramecium caudatum symbiont Caedibacter caryophilus has been phylogenetically characterized by its 16S rRNA gene sequence, and it was found to be a member of the Alphaproteobacteria related to the RICKETTSIALES: In this study, the Caedibacter taeniospiralis type strain, an R-body-producing cytoplasmatic symbiont of Paramecium tetraurelia strain 51k, was investigated by comparative 16S rRNA sequence analysis and fluorescence in situ hybridization with specific oligonucleotide probes. C. taeniospiralis is not closely related to C. caryophilus (80% 16S rRNA sequence similarity) but forms a novel evolutionary lineage within the Gammaproteobacteria with the family Francisellaceae as a sister group (87% 16S rRNA sequence similarity). These findings demonstrate that the genus Caedibacter is polyphyletic and comprises at least two phylogenetically different bacterial species belonging to two different classes of the PROTEOBACTERIA: Comparative phylogenetic analysis of C. caryophilus, five closely related Acanthamoeba endosymbionts (including one previously uncharacterized amoebal symbiont identified in this study), and their hosts suggests that the progenitor of the alphaproteobacterial C. caryophilus lived within acanthamoebae prior to the infection of paramecia.     

R-Bodies in newly isolated free-living hydrogen-oxidizing bacteria

R-Bodies have been found in a recently isolated pseudomonas-like free-living hydrogen oxidizing bacterium. Their isolation, fine structure and chemical composition are described and compared with the R-bodies from the kappa particles (Caedobacter), obligate endosymbionts of Paramecium aurelia. The 2K 1 R-bodies exhibited essential characteristics of the kappa R-bodies; however, their size and some other structural aspects proved that they represent a new type of R-bodies. The presence of phage tail-like particles in cells induced with Mitomycin C is in favour of the hypothesis that the R-bodies might be coded by defective prophages, or by extrachromosomal elements.     

Phylogenetic relationships of bacterial endosymbionts of Paramecium aurelia: polynucleotide sequence relationships of 51 kappa and its mutants.

Hydroxyapatite chromatographic procedures were used to investigate the deoxyribonucleic acid (DNA) sequence relationships of kappa of Paramecium tetraurelia stock 51 and the organisms that have been designated as mutants of 51 kappa. Of the "mutants" studied, only 51m43 kappa possessed a high percentage (89%) of DNA sequences homologous to those of 51 kappa. All other "mutant" strains possessed less than 25% polynucleotide sequence homology to 51 kappa DNA. The three strains of pi endosymbionts (51m1 pi, 51m43 pi, and 139 pi) share greater than 75% DNA sequence homology with each other and approximately 50% DNA sequence homology with 138 mu, the mate-killer endosymbiont found in P. octaurelia. Only 23% of the 51 kappa DNA sequences were found to be homologous with those of 51m1 kappa. The data indicate that of the "mutants" studied, only 51m43 kappa could be a mutant of 51 kappa. The pi endosymbionts comprise a closely related group of organisms that are also related to 138 mu but not to any of the kappas tested. The group of organisms designated as kappa appears to be comprised of at least two distinct phylogenetic groups.     

Stereomicroscopy of isolated R-bodies from Psuedomonas Taeniospiralis and Caedibacter Taeniospiralis

Utilizing the facility of stereomicroscopy the R-body structures observed within various bacteria have been shown to be complex structures. They occasionally occur in intertwined pairs showing that a bacterium produces more than one R-body and that the growth of the two probably occurs at different times.     

Co-infection of the macronucleus of Paramecium caudatum by free-living bacteria together with the infectious Holospora obtusa

Infection experiments were performed incubating Paramecium caudatum with non-infectious free-living bacteria or weakly infectious intracellular bacteria together with the infectious Holospora obtusa. Two of four non-infectious free-living bacteria (Enterobacter aerogenes and Klebsiella pneumoniae) were found to get into the nuclei when added to Paramecium together with H. obtusa. The endonuclear bacterium Nonospora macronucleata that is weakly infectious by itself increases its infectivity when presented together with the infectious holosporas. The results provide evidence that H. obtusa may facilitate entry of other, non-infectious bacteria into the nuclei of Paramecium.     

The Toxic Symbiont Caedibacter caryophila in the Cytoplasm of Paramecium novaurelia

Endosymbiotic bacteria were observed to inhabit the cytoplasm of the freshwater ciliateParamecium novaurelia. Transmission electron microscopy and toxicity tests with sensitive paramecia showed that the endosymbionts belong to the genusCaedibacter. The bacteria conferred a killer trait to their host paramecia. The production of a proteinaceous inclusion body (“R-body”) in the bacterial cell makes them toxic to other paramecia after they become enclosed in food vacuoles. R-bodies ofCaedibacter sp were associated with phages, which are known in most otherCaedibacter species to code for the R-body proteins. The killer-effect ofP. novaurelia on sensitiveP. caudatum strains was of the “paralysis” type, which is a characteristic of the symbiont speciesCaedibacter caryophila. Until nowC. caryophila was known to inhabit the macronucleus ofParamecium caudatum only. Sequencing of the 16S rRNA-gene proved thatCaedibacter sp from the cytoplasm ofP. novaurelia belongs to the speciesC. caryophila as well. The rDNA-sequence of 1695 bp length differed in a total of only 1 bp from the corresponding gene inC. caryophila from the macronucleus ofP. caudatum. The results indicate that the infection of specific host cell compartments may depend on host genes, but not on different traits of the infecting symbiont species. The occurrence of killer and sensitive paramecia strains together in one pond is discussed with respect to the competitive advantage of the killer trait.     

Independent phylogenetic origins of methanotrophic and chemoautotrophic bacterial endosymbioses in marine bivalves.

The discovery of bacterium-bivalve symbioses capable of utilizing methane as a carbon and energy source indicates that the endosymbionts of hydrothermal vent and cold seep bivalves are not restricted to sulfur-oxidizing chemoautotrophic bacteria but also include methanotrophic bacteria. The phylogenetic origin of methanotrophic endosymbionts and their relationship to known symbiotic and free-living bacteria, however, have remained unexplored. In situ localization and phylogenetic analysis of a symbiont 16S rRNA gene cloned from the gills of a recently described deep-sea mussel species demonstrate that this symbiont represents a new taxon which is closely related to free-living, cultivable Type I methanotrophic bacteria. This symbiont is distinct from known chemoautotrophic symbionts. Thus, despite compelling similarities between the symbioses, chemoautotrophic and methanotrophic symbionts of marine bivalves have independent phylogenetic origins.     

Effects of various agents on the R bodies of certain bacteria

We have shown that urea and temperature affect the unrolling of the R bodies from the bacteria Caedibacter taeniospiralis, Pseudomonas taeniospiralis and Pseudomonas avenae. The R bodies of P. taeniospiralis are not, however, affected by pH changes nor by EDTA or EGTA unlike the other two types of R body. Antibodies prepared against the R bodies of C. taeniospiralis have been shown, following gold-labelling and electron microscopy, to be specific for the proteins of the homologous R body. Pre-treatment of R bodies with pronase or sodium periodate had no effect on these reactions.     

An experimental test of the symbiosis specificity between the ciliate Paramecium bursaria and strains of the unicellular green alga Chlorella

The ciliate Paramecium bursaria living in mutualistic relationship with the unicellular green alga Chlorella is known to be easily infected by various potential symbionts/parasites such as bacteria, yeasts and other algae. Permanent symbiosis, however, seems to be restricted to Chlorella taxa. To test the specificity of this association, we designed infection experiments with two aposymbiotic P. bursaria strains and Chlorella symbionts isolated from four Paramecium strains, seven other ciliate hosts and two Hydra strains, as well as three free-living Chlorella species. Paramecium bursaria established stable symbioses with all tested Chlorella symbionts of ciliates, but never with symbiotic Chlorella of Hydra viridissima or with free-living Chlorella. Furthermore, we tested the infection specificity of P. bursaria with a 1:1:1 mixture of three compatible Chlorella strains, including the native symbiont, and then identified the strain of the newly established symbiosis by sequencing the internal transcribed spacer region 1 of the 18S rRNA gene. The results indicated that P. bursaria established symbiosis with its native symbiont. We conclude that despite clear preferences for their native Chlorella, the host-symbiont relationship in P. bursaria is flexible.     

Towards an ecological understanding of the killer trait – A reproducible protocol for testing its impact on freshwater ciliates

Paramecium strains with the ability to kill other paramecia often harbour intracellular bacteria belonging to the genera Caedibacter or Caedimonas. Central structures of this killer trait are refractile bodies (R-bodies) produced by the endosymbionts. Once ingested by a sensitive Paramecium, R-bodies presumably act as delivery system for an unidentified toxin which causes the death of endosymbiont-free paramecia while those infected gain resistance from their symbionts. The killer trait is therefore considered as competitive advantage for the hosts of R-body producers. While its effectiveness against paramecia is well documented, the effects on other aquatic ciliates are much less studied.In order to address the broadness of the killer trait, a reproducible killer test assay considering the effects on predatory ciliates (Climacostomum virens and Dileptus jonesi) as well as potential bacterivorous Paramecium competitors (Dexiostoma campyla, Euplotes aediculatus, Euplotes woodruffi, and Spirostomum teres) as possibly susceptible species was established. All used organisms were molecularly characterized to increase traceability and reproducibility. The absence of any lethal effects in both predators and competitors after exposure to killer paramecia strongly suggests a narrow action range for the killer trait. Thus, R-body producing bacteria provide their host with a complex, costly strategy to outcompete symbiont-free congeners only.     

Symbionts and organelles in ancrobic protozoa and fungi

The discovery of methanogenic bacteria as endosymbionts of free-living anaerobic protozoa opened new fields of research in microbial ecology, cell physiology and molecular biology. Recent information from 16S rRNA sequence studies has shown in three cases that endosymbiotic methanogenic bacteria differ from free-living species. Frequently, endosymbiotic methanogens are localized in anaerobic protozoa near hydrogenosomes - organelles that produce H2, C02 and acetate, all of which are substrates for methanogenesis. Hydrogenosomes are also present in anaerobic fungi. The current view is that the organelles are endosymbllont-derived and were probably acquired on several distinct occasions during evolution.     

Extranuclear DNA and the Endosymbionts of <Emphasis Type="Italic">Paramecium aurelia</Emphasis>

THE basis of cytoplasmic inheritance in the killer system of Paramecium aurelia has been located to endosymbionts* in the cytoplasm. Breeding experiments have shown the maintenance and replication of some of the endosymbionts in their cellular environment to depend on nuclear genes of the Paramecium host cell¹. There are indications of a specific adaptation between the endosymbionts and certain strains or syngens (≡sibling species)².     

Alpha, an Infectious Macronuclear Symbiont of Paramecium aurelia

SYNOPSIS. A spiral, rod- or crescent-shaped symbiont here designated alpha, is present in the macronucleus of killer stock 562, syngen 2 of Paramecium aurelia. This stock has a cytoplasmic symbiont, kappa, as well as alpha. Lines were obtained which had only alpha, others which had only kappa, and some which had neither. It was possible to purify and separate both kinds of symbiont from homogenates of stock 562 using an ECTEOLA column. The killing action of this stock is due to kappa, not alpha. Observations on the structure of alpha with the electron microscope indicate that alpha, like the cytoplasmic symbionts in this species, is a bacterium. Alpha is never seen in the micronucleus, is rarely found in the cytoplasm, but abounds in the macronucleus. If paramecia are allowed to grow slowly after autogamy, alpha passes from the old macronuclear fragments, infects the new macronucleus, and all animals retain alpha. In exautogamous paramecia growing at maximum fission rate, however, alpha often does not infect the new macronucleus and is lost from many lines when the old macronuclear fragments disappear. In mixed cultures containing alpha-bearing and alphafree paramecia, it has been found that alpha readily invades the macronucleus of paramecia of susceptible stocks. Homogenates of alpha-bearing cultures are also infective. Infection is highly specific, occurring in only 6 of the 44 stocks of P. aurelia in which infection was attempted, and these 6 are all syngen 2. It is suggested that the short rod or crescent form of alpha is the reproductive form, while the elongated spiral form is probably the invasive motile form.