Endosymbiotic Bacteria in the Parasitic Ciliate Ichthyophthirius multifiliis

Endosymbiotic bacteria were identified in the parasitic ciliate Ichthyophthirius multifiliis, a common pathogen of freshwater fish. PCR amplification of DNA prepared from two isolates of I. multifiliis, using primers that bind conserved sequences in bacterial 16S rRNA genes, generated an ∼1,460-bp DNA product, which was cloned and sequenced. Sequence analysis demonstrated that 16S rRNA gene sequences from three classes of bacteria were present in the PCR product. These included Alphaproteobacteria (Rickettsiales), Sphingobacteria, and Flavobacterium columnare. DAPI (4′,6-diamidino-2-phenylindole) staining showed endosymbionts dispersed throughout the cytoplasm of trophonts and, in most, but not all theronts. Endosymbionts were observed by transmission electron microscopy in the cytoplasm, surrounded by a prominent, electron-translucent halo characteristic of Rickettsia. Fluorescence in situ hybridization demonstrated that bacteria from the Rickettsiales and Sphingobacteriales classes are endosymbionts of I. multifiliis, found in the cytoplasm, but not in the macronucleus or micronucleus. In contrast, F. columnare was not detected by fluorescence in situ hybridization. It likely adheres to I. multifiliis through association with cilia. The role that endosymbiotic bacteria play in the life history of I. multifiliis is not known.The ciliate Ichthyophthirius multifiliis is an obligate parasite of freshwater fish that infects epithelia of the skin and gills. The life cycle of I. multifiliis consists of three stages: an infective theront, a parasitic trophont, and a reproductive tomont. Infection is initiated by invasion of the skin and gills by free-swimming, 40-μm-long, pyriform-shaped theronts that burrow several cell layers deep into epithelial tissue of the skin and gills and rapidly differentiate into trophonts. Trophonts feed on epithelial cells and grow into 500- to 800-μm-diameter cells, causing extensive damage to skin and gills, which in severe infections results in mortality (10-12). After feeding for 5 to 7 days, trophonts leave the host, form encysted tomonts, and undergo up to 10 cell divisions over 18 to 24 h, producing as many as 10³ daughter cells, which exit the cyst as infective theronts to reinitiate the life cycle. I. multifiliis is ciliated at all stages (9).DNA sequencing of the I. multifiliis genome at the J. Craig Venter Institute unexpectedly revealed that bacterial DNA sequences, including sequences with homology to Rickettsia, were present in the DNA preparations (R. S. Coyne, 2009 [http://www.jcvi.org/cms/research/projects/ich/overview]). The origin of these sequences was unclear, but they represented evidence for either horizontal gene transfer into the I. multifiliis genome (17, 27) or the presence of intracellular bacteria. No previous evidence suggested the presence of intracellular bacteria in I. multifiliis, even though the fine structure of I. multifiliis theronts and trophonts has been examined by transmission electron microscopy (10-12). Intracellular or endosymbiotic bacteria, however, are commonly found in protists, and about 200 ciliate species are known to harbor intracellular bacteria (13, 15). Sonneborn and Preer in their classic studies on endosymbionts in Paramecium characterized a number of different endosymbionts, including “killers,” named for their ability to kill uninfected strains of Paramecium. Cytoplasmic endosymbionts in Paramecium now include Caedibacter taeniospiralis (Gammaproteobacteria), and Pseudocaedibacter conjugates, Tectibacter vulgaris, and Lyticum flagellatum (Alphaproteobacteria). Macronuclear endosymbionts include the Alphaproteobacteria, Holospora caryophila, and Caedibacter caryophila, which can also infect the cytoplasm (4, 16, 22, 26). The roles these endosymbionts play in protists are not well understood.The presence of sequences with homology to bacterial genomes prompted us to determine if I. multifiliis contained endosymbionts, or if these sequences represented evidence for horizontal gene transfer into the I. multifiliis genome. Our identification of the same two endosymbionts, in two different isolates of I. multifiliis, suggests that endosymbionts are common in I. multifiliis. However, the physiological relationships between I. multifiliis and its resident endosymbionts are unclear. It is not known if the endosymbionts contribute to the growth of I. multifiliis, if they contribute to the severity or pathogenicity of infection, or if they provide their host with any selective advantage, as occurs with Paramecium containing killer particles (4). It has not been determined if they influence the immune response of fish infected with I. multifiliis. It is possible that they may simply be parasites of this parasitic ciliate.     

Ultrastructural and Cytochemical Identification of Peroxisomes in the Ciliate Ichthyophthirius multifiliis

ABSTRACT. The peroxisomes of the parasitic ciliate Ichthyophthirius multifiliis were studied, using ultrastructural and cytochemical techniques. In this ciliate most peroxisomes possess a circular or oval section less than 0.6 μm in diameter. However, some dumbbell-shaped and elongated peroxisomes could also be observed. These organelles were frequently associated with the mitochondria and were more abundant in the cell cortex than in the center of the ciliate. Small vesicles and dense nucleoids were usually present in the ultrathin sections of these peroxisomes. Peroxisomal vesicles and tubular structures were selectively impregnated with osmium tetroxide. Catalase was detected by cytochemical techniques in I. multifiliis peroxisomes.     

Ultrastructural Aspects of the Somatic Cortex and Contractile Vacuole of the Ciliate,Ichthyophthirius multifiliis Fouquet1

The trophont stage in the life cycle of Ichthyophthirius multifiliis was studied in the electron microscope. Surface ridges contain up to 24 ridge microtubules, disposed as a ribbon. Kinetosomes show the classic morphology of 9 triplets of microtubules. Associated with each kinetosome is a kinetodesmal fibril, originating in proximity to triplets 5, 6, and 7, and having a 30 nm periodicity; 3 to 5 postciliary microtubules, originating between triplets 8 and 9; and up to 3 transverse microtubules, originating at triplet 4, as well as a parasomal sac. Each cell is partially enclosed by a system of 3 “unit” membranes: the outer limiting membrane, and the outer and inner alveolar membranes. The last two membranes define the alveolar sac. Mucocysts, each with a dense core, are present in large numbers. The contractile vacuole system includes the contractile vacuole, associated tubules and vesicles, injection canals, a discharge canal, and a pore. Microtubules abound in the walls of the contractile vacuole, injection and discharge canals, and in the region of the pores, where both ring and radial microtubular arrangements are noted. The ultrastructure suggests that I. multifiliis is more closely related to Tetrahymena pyriformis than to Paramecium aurelia.     

Enzyme Cytochemistry of the Alveolar Sacs and Golgian-Like Cisternae in the Ciliate Ichthyophthirius multifiliis

In the cell cortex of the parasitic ciliate Ichthyophthirius multifiliis different kinds of cisternae were observed: the alveolar sacs, thick membrane cisternae and the endoplasmic reticulum. The thick membrane cisternae possess coated dilated rims and sometimes could be observed close to the endoplasmic reticulum. Using cytochemical techniques acid phosphatase, thiamine pyrophosphatase and nucleoside diphosphatase activities were detected in the thick membrane cisternae and in the alveolar sacs of trosphozoites. In the endoplasmic reticulum acid phosphatase activity was not detected and only very small amounts of thiamine pyrophosphatase and nucleoside diphosphatase reaction product were observed. After exit from the host, a reduction in acid phosphatase activity was evident in the alveolar sacs. At theront stage acid phosphatase activity is absent from these structures. However, high thiamine pyrophosphatase and nucleoside diphosphatase activities remain in the alveolar sacs during the whole life cycle. On the other hand, acid phosphatase, thiamine pyrophosphatase and nucleoside diphosphatase activities were detected in thick membrane cisternae of theronts. Based on the morphological aspects and enzymatic content the thick membrane cisternae of the cell cortex are designated as golgian-like cisternae. The cytochemical results point out a relationship between the alveolar sacs and the Golgi complex.     

Approaches towards DNA Vaccination against a Skin Ciliate Parasite in Fish

Rainbow trout (Oncorhynchus mykiss) were immunized with plasmid DNA vaccine constructs encoding selected antigens from the parasite Ichthyophthirius multifiliis. Two immobilization antigens (I-ags) and one cysteine protease were tested as genetic vaccine antigen candidates. Antigenicity was evaluated by immunostaining of transfected fish cells using I-ag specific mono- and polyclonal antibodies. I. multifiliis specific antibody production, regulation of immune-relevant genes and/or protection in terms of parasite burden or mortality was measured to evaluate the induced immune response in vaccinated fish. Apart from intramuscular injection, needle free injection and gene gun delivery were tested as alternative administration techniques. For the I-ags the complement protein fragment C3d and the termini of the viral haemorrhagic septicaemia virus glyco(G)protein (VHSV G) were tested as opsonisation and cellular localisation mediators, respectively, while the full length viral G protein was tested as molecular adjuvant. Expression of I-ags in transfected fish cells was demonstrated for several constructs and by immunohistochemistry it was possible to detect expression of a secreted form of the Iag52B in the muscle cells of injected fish. Up-regulations of mRNA coding for IgM, MHC I, MHC II and TCR β, respectively, were observed in muscle tissue at the injection site in selected trials. In the spleen up-regulations were found for IFN-γ and IL-10. The highest up-regulations were seen following co-administration of I-ag and cysteine protease plasmid constructs. This correlated with a slight elevation of an I. multifiliis specific antibody response. However, in spite of detectable antigen expression and immune reactions, none of the tested vaccination strategies provided significant protection. This might suggest an insufficiency of DNA vaccination alone to trigger protective mechanisms against I. multifiliis or that other or additional parasite antigens are required for such a vaccine to be successful.     

Differential Protein Synthesis During the Life Cycle of the Protozoan Parasite Trypanosoma brucei1

Two-dimensional polyacrylamide gel electrophoresis has been used to analyze changes in protein content and protein synthesis in three stages of the life cycle of the protozoan parasite Trypanosoma brucei. The stages examined were slender and stumpy mammalian bloodstream forms and procyclic forms, which are analogous to the tsetse fly midgut stage. Two-dimensional gels of ³⁵S-methionine-labeled proteins were examined by autoradiography to analyze newly synthesized protein, and gels were stained with ammoniacal silver to analyze proteins present. Several stage-specific molecules were noted. The most obvious was the variant surface glycoprotein, which was only present in bloodstream forms. Some other proteins were also bloodstream form specific; they had molecular weights of 120,000 and 38,000. Proteins of 52,000, 46,000, 25–30,000, and 16,000 daltons were present both in stumpy forms and procyclics but not in slender-form trypanosomes. Several proteins (molecular weights of 50–70,000, 43,000, 40,000, 26–24,000, 20–25,000, and 15,000) were present only in one of the three stages. One protein, a molecule of about 18,000 daltons present in both slender and stumpy parasites, did not appear to be synthesized in the stumpy stage. In vitro translation products of mRNA purified from the three stages were also examined. The abundance of mRNA encoding a protein of about 40,000 daltons appeared to be greater in slender than in stumpy parasites although the stumpy forms contained more of the protein and synthesized it at a higher rate.     

Critical Periods in Development of Ichthyophthirius multifiliis (Ciliophora) Populations1

ABSTRACT. Three periods in development that strongly influence population dynamics of Ichthyophthirius multifiliis were identified in experimental infections of channel catfish. The first occurred upon establishment within the host, 0 to 10 min postexposure (PE), when the parasite population that gained entrance declined 50%. Survival from 10 to 45 min PE, however, was constant. The second period identified came after I. multifiliis left the host and the free-living tomont encysted. The third occurred during reproduction. Although survival of encysting tomonts approached 100% among individuals departing after three to five days residence in the host, theront production varied significantly with parasite size, culture temperature during development, and length of residence by the trophont in the host. Theront production per tomont increased daily and on days three, four, and five PE was significantly higher for parasites developing at 24°C than for those at 21°C. At five days PE, mean production was 562 theronts/tomont and 240 theronts/tomont, respectively, and production by tomonts of equal size was greater for parasites maintained at 24°C.     

Invasion and development strategies of Ichthyophthirius multifiliis, a parasitic ciliate of fish

Like many other parasites, Ichthyophthirius multifliis faces critical changes when moving between free-living and parasitic phases. This ciliate alternates between feeding in the epithelium of freshwater fishes and swimming and encysting in fresh water. Several organelles appear to play key roles in successful negotiation o f these changes. Margaret Ewing and Katherine Kocan discuss a variety of cellular components important in host invasion and development of the parasite, with particular attention given to mucocysts, extrusive organelles whose secretions appear to be essential to both life cycle phase changes.     

The Life Cycle of the Histophagous Ciliate Tetrahymena corlissi Thompson, 1955*

The life cycle of Tetrahymena corlissi Thompson, 1955, is described from organisms fed on tissue of the oligochaete Enchytraeus. The trophont stage usually divides twice either while free-swimming or encysted as a tomont. The tomont stage apparently occurs only when the trophont is removed from the “conditioned” tissue environment. The time to completion of division is constant and determined at the onset of exposure to tissue. The number of divisions is a function of the amount of tissue ingested. Tomites differentiate after the divisions as active theronts. This dispersal stage transforms to a trophont when tissue is ingested. If tissue is absent, the theronts become smaller, eventually settling on the substrate as immotile pyriform resting theronts, with a small proportion of the resting theronts encysting within a delicate cyst wall. When stimulated chemically or mechanically, the resting theronts transform to active theronts. If these active theronts ingest tissue, they transform to immature trophonts, initially incapable of division. Life cycle and morphologic dissimilarities among T. corlissi, T. bergeri, and T. rostrata are presently used to distinguish among these species.     

Ichthyophthirius multifiliis as a potential vector of Edwardsiella ictaluri in channel catfish

There is limited information on whether parasites act as vectors to transmit bacteria in fish. In this trial, we used Ichthyophthirius multifiliis and fluorescent Edwardsiella ictaluri as a model to study the interaction between parasite, bacterium, and fish. The percentage (23-39%) of theronts fluorescing after exposure to E.?ictaluri was significantly higher than control theronts (~?6%) using flow cytometry. Theronts exposed to E.?ictaluri at 4?×?10(7) CFU?mL(-1) showed a higher percentage (~?60%) of fluorescent theronts compared to those (42%) exposed to 4?×?10(3) CFU?mL(-1) at 4?h. All tomonts (100%) carried the bacterium after exposure to E.?ictaluri. Edwardsiella ictaluri survived and replicated during tomont division. Confocal microscopy demonstrated that E.?ictaluri was associated with the tomont surface. Among theronts released from tomonts exposed to E.?ictaluri, 31-66% were observed with attached E.?ictaluri. Sixty percent of fish exposed to theronts treated with 5?×?10(7) E.?ictaluri?mL(-1) were positive for E.?ictaluri at 4?h as determined by qPCR or fluorescent microscopy. Fluorescent E.?ictaluri were observed on trophonts in skin and gill wet mounts of dead fish. This study demonstrated that Ich could vector E.?ictaluri to channel catfish.     

Observations on the Caudal Cilium of the Tomite of Ichthyophthirius multifiliis Fouquet, 18761,2

Light microscopy of live or silver-impregnated specimens of the fish parasite Ichthyophthirius multifiliis show that the tomites are elongated and claviform with the anterior end broad. The cytostome, indicated by the presence of the organelle of Lieberkühn, is found in the lower part of the broadened anterior third of the tomite. The tapered posterior end bears a rigid, caudal cilium at its pole. Scanning electron microscopy reveals the caudal cilium and associated structures, including the depression from which the cilium protrudes, circumciliary ring, and raised struts on the ring. From these observations it is concluded that a previously reported “apical filament” found on the tomite is actually the posterior caudal cilium described by Canella & Rocchi-Canella in 1976.     

Ichthyophthirius multifiliis (Fouquet) in the mirror carp, Cyprinus carpio L.

Mirror carp were infected with Ichthyophthirius multifiliis (Fouquet) under standardized conditions. The size and number of parasites at selected sites on the body were recorded during the course of the infection. Initial exposure to 40 mature parasites resulted in a mild infection with 100% recovery after 18 days. Recovered fish did not appear to be carriers of the parasite. Exposure to 400 parasites resulted in 100% mortality between 22–25 days. The growth rate of the parasite was linear. Parasites were more numerous in the dorsal surface of the fish than in the lateral or ventral surface. The increase in parasite numbers during the disease was greater in the gills than in the skin.     

Enzyme cytochemistry of the alveolar sacs and golgian-like cisternae in the ciliate Ichthyophthirius multifiliis

In the cell cortex of the parasitic ciliate Ichthyophthirius multifiliis different kinds of cisternae were observed: the alveolar sacs, thick membrane cisternae and the endoplasmic reticulum. The thick membrane cisternae possess coated dilated rims and sometimes could be observed close to the endoplasmic reticulum. Using cytochemical techniques acid phosphatase, thiamine pyrophosphatase and nucleoside diphosphatase activities were detected in the thick membrane cisternae and in the alveolar sacs of trophozoites. In the endoplasmic reticulum acid phosphatase activity was not detected and only very small amounts of thiamine pyrophosphatase and nucleoside diphosphatase reaction product were observed. After exit from the host, a reduction in acid phosphatase activity was evident in the alveolar sacs. At theront stage acid phosphatase activity is absent from these structures. However, high thiamine pyrophosphatase and nucleoside diphosphatase activities remain in the alveolar sacs during the whole life cycle. On the other hand, acid phosphatase, thiamine pyrophosphatase and nucleoside diphosphatase activities were detected in thick membrane cisternae of theronts. Based on the morphological aspects and enzymatic content the thick membrane cisternae of the cell cortex are designated as golgian-like cisternae. The cytochemical results point out a relationship between the alveolar sacs and the Golgi complex.     

Nuclear Features of the Heterotrich Ciliate Blepharisma americanum: Genomic Amplification,Life Cycle,and Nuclear Inclusion

Blepharisma americanum, a member of the understudied ciliate class Heterotrichea, has a moniliform somatic macronucleus that resembles beads on a string. Blepharisma americanum is distinguishable by its pink coloration derived from the autofluorescent pigment blepharismin and tends to have a single somatic macronucleus with 3–6 nodes and multiple germline micronuclei. We used fluorescence confocal microscopy to explore the DNA content and amplification between the somatic and germline nuclei of B. americanum through its life cycle. We estimate that the DNA content of the macronucleus and micronucleus are 43 ± 8 Gbp and 83 ± 16 Mbp respectively. This correlates with an approximate DNA content difference of 500‐fold from micronucleus to macronucleus and a macronuclear ploidy of ~1,100 N as compared to the presumably diploid micronucleus. We also investigate a previously reported macronuclear inclusion, which is present sporadically across all life cycle stages; this inclusion looks as if it contains blepharismin based on its fluorescent properties, but its function remains unknown. We also provide additional detail to our understanding of life cycles changes in B. americanum by analyses of fluorescent images. Overall, the data analyzed here contribute to our understanding of the diversity of nuclear architecture in ciliates by providing details on the highly polyploid somatic macronucleus of B. americanum.     

Two year study on the infectivity of Ichthyophthirius multifiliis in channel catfish Ictalurus punctatus

Ichthyophthirius multifiliis Fouquet (Ich) is a fish parasite that causes serious economic loss for aquaculture. A major difficulty in the maintenance of single isolates of Ich for research purposes is the loss of infectivity. After an unknown number of passages or infection cycles the Ich isolate loses its infectivity. This study determined the infectivity of an Ich isolate during 105 infection cycles in channel catfish Ictalurus punctatus over a 2 yr period. The mean percentage of fish infected by Ich, the infection levels and the time to trophont emergence were each compared after 4 cyclic periods: 1-25, 26-60, 61-90 and 91-105 Ich cycles. Results of this study demonstrated that Ich was significantly more infective (p < 0.05) at 1-25 than 26-105 cycles. Channel catfish were infected at a ratio of 1 infected fish to 8 naive fish at 1-25 and 26-60 cycles. A higher infection ratio occurred at 61-90 and 91-105 cycles. Trophont emergence was noted to be significantly longer at 91-105 compared to 1-25 cycles, during 7 and 5 d respectively, at 23.4 +/- 1.1 degrees C. The results of the present study indicate that the infectivity of I. multifiliis started to decrease after 25 infection cycles and was predominant in the single Ich isolate at 61-90 and 91-105 cycles.     

Differential expression of cysteine proteases in developmental stages of the parasitic ciliate Ichthyophthirius multifiliis

An expressed sequence tag database of the freshwater fish parasite, Ichthyophthirius multifiliis (Ciliophora) was analyzed to seek for proteases potentially involved in the invasion and degradation of host tissues during infection. The translation of the database revealed two cathepsin L cysteine proteases (Icp1 and Icp2) of the C1A peptidase subfamily. The analysis of Icp1 and Icp2 sequences suggested that both proteases would be synthesized as preproproteins, with a mature domain of 27.9 and 22.8 kDa, respectively. Their expression level was determined in the trophont parasitic stage, in the tomont reproductive stage, and in the theront infective stage by real-time RT-PCR. ICP1 and ICP2 were significantly upregulated in trophont and theront stages in comparison with the tomont stage. Mature peptides of Icp1 and Icp2 were identified in crude extracts of I. multifiliis trophonts by LC-MS/MS. Zymograms showed three to seven activity bands at the optimum pH of cathepsin L cysteine proteases. Two bands displaying cysteine protease activity were identified by inhibition with E-64. They represented the major proteolytic activity of the trophont stage at pH 5-7, suggesting that cysteine proteases play an important role in the infection process.     

Euduboscquella costata n. sp. (Dinoflagellata,Syndinea), an Intracellular Parasite of the Ciliate Schmidingerella arcuata: Morphology,Molecular Phylogeny,Life Cycle,Prevalence, and Infection Intensity

The syndinean dinoflagellate Euduboscquella costata n. sp., an intracellular parasite of the tintinnid ciliate Schmidingerella arcuata, was discovered from Korean coastal water in November of 2013. Euduboscquella costata parasitized in about 62% of the host population, with infection intensity (= number of trophonts in a single host cell) ranging from 1 to 8. Based on morphology and nuclear 18S ribosomal RNA gene sequences, the parasite is new to science. Euduboscquella costata n. sp. had an infection cycle typical of the genus, but had morphological and developmental features that distinguished it from congeneric species. These features include: (1) episome of the trophont with 25–40 grooves converging toward the center of the shield; (2) a narrow, funnel‐shaped lamina pharyngea extending from the margin of the episomal shield to the nucleus; (3) persistence of grooves during extracellular development (sporogenesis); (4) a single food vacuole during sporogenesis; (5) separation of sporocytes early in sporogenesis, regardless of type of spore formed; and (6) dinospore size (ca. 14 μm in length) and shape (bulbous episome with narrower, tapering hyposome). After sporogenesis, E. costata produced four different types of spore that showed completely identical 18S rRNA gene sequences. The gene sequence was completely identical with a previously reported population, Euduboscquella sp. ex S. arcuata, from Assawoman Bay, USA, indicating that the two populations are likely conspecific. Favella ehrenbergii, a widely recorded tintinnid known to host Euduboscquella spp., co‐occurred with S. arcuata, but was not infected by E. costata in field samples or during short‐term, cross‐infection experiments.     

Occurrence of the Myxosporidan Parasite Myxidium minteri in Salmonid Fish1

SYNOPSIS. The myxosporidan Myxidium minteri was found in 3 recognized hosts, chinook and coho salmon and rainbow trout and 2 new hosts, cutthroat trout and mountain whitefish. Spores in all species examined were found primarily in the gall bladder. Fish infected with this parasite were obtained from both Oregon coastal rivers and Columbia River basin locations. In general the prevalence of infection was higher in the fish in coastal rivers.     

Photosynthetic Activity during the Life Cycle of Synchronous Skeletonema Cells

A culture of Skeletonema costatum grown at a light intensity of 3 klux and at 20°C was synchronized in diurnally intermittent illumination of 12 hour light and 12 hour dark. The culture was hardly fully synchronous as the cell division period lasted about 9 hours. The cell division started in the middle of the light period. The concentration of the pigments: chlorophyll a, chlorophyll 6 and fucoxanthin and the rate of light-saturated photosynthesis were followed every hour during the 24 hour period. Both the concentration of pigments and the photosynthetic activity showed a rhythmical variation. The concentration per cell of all three pigments examined increased during the development of the cells and decreased automatically during the period of cell division. An increase in the pigment concentration was found only in the light period. The rate of light-saturated photosynthesis calculated per unit of cell number increased during the cell development and decreased during the division period. The increase in the photosynthetic activity at light-saturation started about 4 hours after the end of cell division, which was 4 hours before the light was turned on while the increase in the concentration of chlorophyll a first started 1–2 hours after this moment. The variation in photosynthetic activity was compared with that found by other workers. The results found with Chlorella ellipsoidea by Japanese scientists (Nihci et al.) was explained as an inhibition phenomenon because the cells were not adapted to the experimental conditions.