Ichthyophthirius multifiliis (Ciliophora) Development in Gill Epithelium1

ABSTRACT. The development of Ichthyophthirius multifiliis trophonts in gill epithelium of channel catfish was studied on the first five days post-exposure (PE) by light and electron microscopy. Trophonts increased in average diameter from 48 μm at one day PE to 248 μm at five days PE. Although theronts invaded any part of the gill epithelium, at three days PE most parasites were found adjacent to major blood vessels, particularly the afferent vessel. From one to three days PE, 70–90% of trophonts were immediately adjacent to gill epithelium, but at four and five days PE only 50% of trophonts were closely apposed by host epithelial cells. Notable ultrastructural changes in the trophonts over the five-day period occurred in the mucocysts and lipid inclusions, both of which increased markedly in number. The few crystalline mucocysts present at one day PE were near the cell periphery but rarely attached to the plasma membrane. At three days PE, crystalline mucocysts were significantly more abundant, and at five days PE, they occurred in large numbers throughout the cytoplasm as well as at the periphery. At three days PE, secretory mucocysts were first observed. Contractile vacuoles were more prominent at five days PE than earlier in development. Development of mucocysts and lipid reserves is probably essential to survival and reproduction of the ciliate after it leaves the host.     

Ichthyophthirius multifiliis (Ciliophora) Invasion of Gill Epithelium1

The sequence of morphologic events associated with Ichthyophthirius rnultifliis invasion of gill epithelium began in the theront with differentiation of secretory mucocysts and the perforatorium. After escaping from the cyst the theront, which stained intensely with Mallory' stain, sought a host. As it approached the host epithelium, the contents of the mucocysts were discharged, enveloping the ciliate in sticky material, which made initial contact with the host epithelium. Rapid penetration by the theront caused disruption of one or more host cells and resulted in a focal necrosis associated with the anterior margin of the ciliate. Within five minutes postexposure, the parasite completed its invasion of the epithelial layer and stained less intensely. The remnants of host cells disrupted during its entry surrounded the trophont until they were ingested by the parasite. Within 40 min postexposure, synthetic activity of the parasite appeared to increase as evidenced by an abundance of organelles, particularly ribosomes and crystalline mucocysts. At this point, the overlying host epithelium appeared normal.     

Ichthyophthirius multifiliis (Ciliophora) Exit from Gill Epithelium1

The first change in the sequence of morphological events occurring as fully developed Ichthyophthirius multifiliis trophonts spontaneously left gill epithelium or as younger trophonts departed, following experimentally induced death of the fish, was the separation of parasites from overlying host cells. Discharge of contractile vacuoles may have played a role in this process. Spaces then appeared between host cells, and individual epithelial cells became vacuolated. Finally, the epithelium ruptured and the parasites swam free. In induced exit after three days residence in the host, departure of the trophont was evident only after autolysis of epithelium had occurred. Induced departure of trophonts after four days residence was more rapid, suggesting an active role for the parasite in exit. Changes in parasite and epithelium observed in induced exit were similar to those in spontaneous departure after five days residence.     

Ichthyophthirius multifiliis (Ciliophora) exit from gill epithelium

The first change in the sequence of morphological events occurring as fully developed Ichthyophthirius multifiliis trophonts spontaneously left gill epithelium or as younger trophonts departed, following experimentally induced death of the fish, was the separation of parasites from overlying host cells. Discharge of contractile vacuoles may have played a role in this process. Spaces then appeared between host cells, and individual epithelial cells became vacuolated. Finally, the epithelium ruptured and the parasites swam free. In induced exit after three days residence in the host, departure of the trophont was evident only after autolysis of epithelium had occurred. Induced departure of trophonts after four days residence was more rapid, suggesting an active role for the parasite in exit. Changes in parasite and epithelium observed in induced exit were similar to those in spontaneous departure after five days residence.     

Chemoattraction of Ichthyophthirius multifiliis (Ciliophora) theronts to host molecules

Mechanisms in the host-finding process of Ichthyophthirius multifiliis were studied in vitro by a novel bioassay using 24-well multidishes supplied with bottom layers of agar with chemoattractants. It was shown that low molecular weight molecules (carbohydrates, amino acids, fatty acids, urea) did not attract theronts. In contrast, sera and mucus from a range of teleosts (including marine fish) were effective attractants. Fractionation by gel filtration of fish serum allowed determination of the molecular size of the attracting proteins. Further biochemical studies suggested the chemoattractants to be present in fractions with host immunoglobulin and some still undetermined proteins. No clear association between enzyme activity and chemotactic potential was seen. The high chemoattractive effect of serum from various unrelated teleosts corresponds to the low host specificity of I. multifiliis and suggests that serum factors in mucus could be involved in host finding of the parasite. Society for Parasitology Inc.     

Efficacy of selected oral chemotherapeutants against Ichthyophthirius multifiliis (Ciliophora: Ophyroglenidae) infecting rainbow trout Oncorhynchus mykiss

The chemotherapeutic efficacy of 6 in-feed compounds against Ichthyophthirius multifiliis Fouquet, 1876 was assessed using experimental infections of rainbow trout Oncorhynchus mykiss (Walbaum) fingerlings. Trial doses of 104 ppm amprolium hydrochloride or 65 ppm clopidol fed to fish for 10 d prior to infection significantly reduced the number of trophonts establishing in trout fingerlings by 62.0 and 35.2% respectively. In-feed treatments of infected trout with either 63 or 75 ppm amprolium hydrochloride, 92 ppm clopidol, or 38, 43 or 47 ppm salinomycin sodium for 10 d also significantly reduced the number of surviving trophonts by 77.6 and 32.2% for amprolium, 20.1% for clopidol and 80.2, 71.9 and 93.3% respectively for salinomycin sodium.     

Influence of Anguillicola crassus (Nematoda) and Ichthyophthirius multifiliis (Ciliophora) on swimming activity of European eel Anguilla anguilla

We investigated the swimming activity of 70 European eels Anguilla anguilla in relation to natural infection with 2 parasite species: the eel-specific swimbladder nematode Anguillicola crassus and the non-specific skin and gill protozoan Ichthyophthirius multifiliis. We measured how long individual eels exposed to a water current in a swimming channel with a steady-stream profile could withstand the water current. The parasites affected the swimming behaviour of eels in different ways. The maximum period of time the fish were able to swim against the current was not correlated with infection by A. crassus. In contrast, infection with I. multifiliis reduced the swimming time. The protozoan has a higher pathogenicity than the swimbladder nematode, at least in closed systems, where I. multifiliis is able to spread within a few days. Reduction in swimming capacity after infection with the ciliate averaged 47 % compared to capacity prior to infection. Thus, our results do not support the previously suggested strong negative relation between swimming activity of eels and intensity of A. crassus infection, at least in the short-term. However, there are indications in the literature that the pathological effects of A. crassus on the eel swimmbladder may involve a higher energy demand, possibly manifested in a prolonged spawning migration. As a result, eels heavily infected with this parasite may arrive too late at the spawning site to participate in mating. This could ensure a selection of 'good genes'.     

Reproduction of Ichthyophthirius multifiliis (Ciliata, Ophryoglenidae)

A case of reproduction of Ichthyophthirius multifiliis in the superficial tissues of larvae and fry of Amur wild carp is described. At a temperature of water from 28 to 29 degrees trophonts of Ichthyophthirius encysted on fishes. Inside cysts repeated cell division occurred but this process did not result in swarm spores formation. Later on with the increase of temperature to 29.5--31.5 degrees cysts degenerated.     

Ichthyophthirius (Ciliophora): Population Studies Suggest Reproduction in Host Epithelium1

Evidence that Ichthyophthirius multifiliis trophonts may reproduce within the epithelium of the host was obtained from experimental infections of channel catfish. Mean number of parasites spontaneously leaving the fish increased from 0 on day 3 postexposure (PE) to 66.5 per fish on day 7 PE. Mean population density in fin, however, increased five-fold from day 3 to day 5 PE in the absence of opportunity for reinfection. At day 3 PE, 100% of parasite loci in fin and gill arches contained solitary trophonts. At day 4 PE, 10% of loci in fin contained clusters of two trophonts; at day 7 PE, 69% contained clusters of two or more trophonts. The first clusters of four trophonts in fin were observed day 5 PE and of eight trophonts, day 8 PE. Trophonts in clusters were flattened against one another.     

Extracellular Calcium Concentration Affects Infectivity of Ichthyophthirius (Ciliophora) Theronts

Tomonts and their theront offspring of the hymenostomatid fish parasite Ichthyophthirius multifiliis were exposed to calcium levels from 0 to 0.8 mM Ca^2+. The survival and reproductive rates of tomonts in the absence of extracellular calcium were not significantly different from rates of tomonts provided calcium. Theronts that developed in the absence of calcium, however, were not infective for Ictalurus punctatus even when the extracellular magnesium concentration was doubled. Theronts that developed in 0.10 mM Ca²⁺ were infective (0.77 trophonts/mm² of pectoral fin) to essentially the same extent as theronts provided 0.33 mM Ca^2+. Infectivity of those provided 0.8 mM Ca²⁺ was 1.79 trophonts/mm² of fin, similar to that of theront controls. Theronts deprived of extracellular calcium as they developed contained significantly fewer secretory mucocysts than did theronts provided 0.1 to 0.8 mM Ca²⁺ although no significant differences among groups occurred with respect to abundance of crystalline or differentiating mucocysts. Theronts deprived of extracellular calcium also had swollen or enlarged mitochondria and abnormal crystalline mucocysts.     

Ichthyophthirius (Ciliophora): population studies suggest reproduction in host epithelium

Evidence that Ichthyophthirius multifiliis trophonts may reproduce within the epithelium of the host was obtained from experimental infections of channel catfish. Mean number of parasites spontaneously leaving the fish increased from 0 on day 3 postexposure (PE) to 66.5 per fish on day 7 PE. Mean population density in fin, however, increased five-fold from day 3 to day 5 PE in the absence of opportunity for reinfection. At day 3 PE, 100% of parasite loci in fin and gill arches contained solitary trophonts. At day 4 PE, 10% of loci in fin contained clusters of two trophonts; at day 7 PE, 69% contained clusters of two or more trophonts. The first clusters of four trophonts in fin were observed day 5 PE and of eight trophonts, day 8 PE. Trophonts in clusters were flattened against one another.     

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.     

Experimental infection of striped marshfrog tadpoles (Limnodynastes peronii) by Ichthyophthirius multifiliis.

Ichthyophthirius multifiliis, or white spot, is a well known and widely distributed parasite of freshwater fish. However, it is not know whether it can infect other aquatic vertebrates such as amphibians. This study uses a series of laboratory-based experiments to demonstrate that I. multifiliis can infect the tadpole stage of an amphibian, the striped marshfrog (Limnodynastes peronii) of Eastern Australia. The tadpoles did not appear to develop ichthyophthiriasis at low parasite levels (200 parasites per tadpole), but at high parasite levels (2,000 parasites per tadpole) 100% of the tadpoles developed ichthyophthiriasis. This is the first time that it has been demonstrated that I. multifiliis can infect a nonpiscine vertebrate host.     

Differences in virulence between two serotypes of Ichthyophthirius multifiliis

Naive channel catfish Ictalurus punctatus were infected by 2 isolates of the parasitic ciliate Ichthyophthirius multifiliis that differed in virulence. The isolates, NY1 and G5, Serotypes A and D, respectively, express different surface immobilization-antigens. The virulence of the 2 isolates was compared using tail-fin infections to quantitate parasite numbers and by analysis of the survival of infected fish. Although NY1 infected fish at a lower level than G5, all NY1-infected fish died, but 51% of G5-infected fish survived. The greater virulence of NY1 is apparently a consequence of its shorter life cycle, which results in overwhelming reinfection of fish before they can develop a protective immune response. This report represents the first experimental evidence for differences in virulence between serotypes of I. multifiliis.     

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.     

The I-antigens of Ichthyophthirius multifiliis are GPI-Anchored Proteins

The parasitic ciliate Ichthyophthirius multifiliis has abundant surface membrane proteins (i-antigens) that when clustered, trigger rapid, premature exit from the host. Similar antigens are present in free-living ciliates and are GPI-anchored in both Paramecium and Tetrahymena. Although transmembrane signalling through GPI-anchored proteins has been well-documented in metazoan cells, comparable phenomena have yet to be described in protists. Since premature exit of Ichthyophthirius is likely to involve a transmembrane signalling event, we sought to determine whether i-antigens are GPI-anchored in these cells as well. Based on their solubility properties in Triton X-114, the i-antigens of Ichthyophthirius are amphiphilic in nature and partition with the detergent phase. Nevertheless, following treatment of detergent lysates with phospholipase C, the same proteins become hydrophilic. Concomitantly, they are recognized by antibodies against a cross-reacting determinant exposed on virtually all GPI-anchored proteins following cleavage with phospholipase C. Finally, when expressed in recombinant form in Tetrahymena thermophila, full-length i-antigens are restricted to the membrane, while those lacking hydrophobic C-termini are secreted from the cell. Taken together, these observations argue strongly that the i-antigens of Ichthyophthirius multifiliis are, in fact, GPI-anchored proteins.     

蛇(鱼句)感染多子小瓜虫病一例

2003年6月18日从长江重庆木洞段购回十几条活泼蛇(鱼句)Saurogobio dabryi Bleeker.均由罾网捕捞,健康无损伤.放在室外水泥池饲养.室外水温白天26℃左右 ,夜晚24℃左右, 6月26日在常规检查时又发现蛇(鱼句)身上出现小白点,病鱼体色发黑、消瘦、反应迟钝、体表粘液增多、浮头、体表和鳃遍布小白点;感染后期表皮有脱落现象.取病鱼体表一个白点镜检,可见虫体全身密布短而均匀的纤毛;大核呈马蹄形,确定为多子小瓜虫Ichthyophthirius multifiliis Fouquet.感染小瓜虫病的蛇(鱼句)7月6日死亡.蛇(鱼句)是否能大面积发病还有待进一步研究.     

Inflammatory response of rainbow trout Oncorhynchus mykiss (Walbaum, 1792) larvae against Ichthyophthirius multifiliis

At hatching, the immune system of the rainbow trout larva is not fully developed. The larva emerges from the egg and is exposed to the aquatic freshwater environment containing pathogenic organisms. At this early stage, protection from disease causing organisms is thought to depend on innate immune mechanisms. Here, we studied the ability of young post-hatch rainbow trout larvae to respond immunologically to an infection with Ichthyophthirius multifiliis and also report on the localization of 5 different immune relevant molecules in the tissue of infected and uninfected larvae. Quantitative RT-PCR (qPCR) was used to analyze the genetic regulation of IL-1β, IL-8, IL-6, TNF-α, iNOS, SAA, cathelicidin-2, hepcidin, IL-10, IL-22, IgM and IgT. Also, a panel of 5 monoclonal antibodies was used to investigate the presence and localization of the proteins CD8, SAA, MHCII, IgM and IgT. At 10 days (84 degree days) post-hatching, larvae were infected with I. multifiliis and sampled for qPCR at 3, 6, 12, 24, 48 and 72 h post-infection (p.i.). At 72 h p.i. samples were taken for antibody staining. The first of the examined genes to be up-regulated was IL-1β. Subsequently, IL-8 and cathelicidin-2 were up-regulated and later TNF-α, hepcidin, IL-6, iNOS and SAA. Immunohistochemical staining showed presence of CD8 and MHCII in the thymus of both infected and non-infected larvae. Staining of MHCII and SAA was seen at sites of parasite localization and weak staining of SAA was seen in the liver of infected larvae. Staining of IgT was seen at site of infection in the gills which may be one of the earliest adaptive factors seen. No positive staining was seen for IgM. The study illustrates that rainbow trout larvae as young as 10 days (84 degree days) post-hatch are able to regulate important immune relevant cytokines, chemokines and acute phase proteins in response to infection with a skin parasitizing protozoan parasite.