Interaction between parasite and tick vector

Interaction of tick vectors with Borrelia species including B. burgdorferi, rickettsias and piroplasms has been demonstrated by describing selected phenomena. In particular, the various environments inside the tick vector have been considered, including the midgut lumen, gut epithelial cells, body cavities and tissues. Intracellular parasitism occurs in different compartments of the host cell: parasitophorous vacuoles (Anaplasma marginale), phagolysosomes (Coxiella spp.), cytoplasm (Rickettsia, spp. piroplasms) or nucleus (some rickettsiae).     

Growth pattern of Rickettsia tsutsugamushi in irradiated L cells.

Irradiated L cells infected with Rickettsia tsutsugamushi were studied under the electron microscope to define the morphological growth pattern of the organism. For 2 days after inoculation, no rickettsiae were found either extra- or intracellularly; after 2 days multiple rickettsiae appeared within the host cells without morphological evidence of their entry. These observations showed that the rickettsiae within the cell were assembled in situ by segregation of portions of the granular cytoplasm and subsequent internal differentiation and surface membrane assembly of the segregated bodies. The protoplasmic (P) bodies, which seemed to be formed by shedding infected-cell granular cytoplasm, consistently appeared on the surface and within the phagosomes of the host cells. Rickettsiae were occasionally seen entering host cells in the later phase of infection; these were apparently the ones assembled within the P bodies. This suggested that the P bodies, and not the rickettsiae, were the major infectious particles that transmitted the rickettsial genetic substance among the host cells. On the basis of the present morphological observations, viral-type multiplication for R. tsutsugamushi is proposed.     

Studies on rickettsia-like organism disease of the tropical marine pearl oyster I: the fine structure and morphogenesis of pinctada maxima pathogen rickettsia-like organism

The present paper reports for the first time the discovery of a rickettsia-like organism (RLO) in the cultured tropical marine pearl oyster Pinctada maxima with mass mortality in the Hainan Province of China. This organism parasitizes the cytoplasm of host cells and forms intracytoplasmic eosinophilic inclusions. These organisms are extremely pleiomorphic in shape and average 967 x 551 nm in size, as measured in cross sections of transmission electron micrographs. The organisms exhibit clearly recognizable ultrastructural characteristics of prokaryotic bacteria-like cells, including two trilaminar membranes, an increasing electron-dense periplasmic ribosome zone, and a thread-like DNA nucleoidal structure. In addition to the above prokaryotic characteristics, the following unique biological characteristics were confirmed by TEM: (i) These organisms are usually located in host cells in two ways, namely, free in the cell cytoplasm and involved within membrane-limited phagolysosomes; (ii) The organisms exist in two morphological cell types, namely a small cell variant (SCV) and a large cell variant (LCV). The most important morphological difference between two cell types is that the SCV is obviously ribosome-rich in the periphery of the body, which makes SCV more electron-dense in the cytoplasm and narrower in the central nucleoid area than the LCV; (iii) Two propagative modes of the organisms, transverse binary fission and budding, are observed in cytoplasm and phagolysosomes of host cells under TEM, in which the budding is more often seen in phagolysosomes. These characteristics indicate that the organism is a separate species in the family Rickettsiaceae and should be classified into the genus Rickettsia. On the basis of the existence of the two propagative modes and two cell types, and intracellular location, we propose a developmental cycle for this organism which includes a vegetative differentiation stage to develop LCV by transverse binary fisson and a budding differentiation stage to develop resistant SCV. Copyright 1999 Academic Press.     

Penetration of Rickettsia tsutsugamushi into cultured mouse fibroblasts (L cells): an electron microscopic observation

The mechanism of penetration of purified Rickettsia tsutsugamushi (Gilliam strain) into cultured mouse fibroblasts (L cells) was examined by electron microscopy. After 10-40 min of infection, rickettsiae in the process of being phagocytized were often seen on the cell surface. These were restricted to the rickettsiae which seemed to be intact in morphology, while heavy plasmolyzed ones were never phagocytized. Additionally, rickettsiae were taken up individually into a phagosome, and phagocytosis of several rickettsiae together was rarely observed, except in the case of heat-inactivated microorganisms. In the cells, phagosomes whose membranes enclosed rickettsiae either tightly or loosely were seen. Rickettsiae in the loose phagosomes often showed signs of plasmolysis and were rarely released into the cell cytoplasm. Partial disintegration of phagosomal membranes and the escape of rickettsiae from the phagosomes were seen only in tight phagosomes. Large phagosomes containing a clump of several rickettsiae were observed occasionally, in which case the microorganisms were deformed and seemed to be denatured. From the above observations and the frequency of appearance of these different penetration stages in the specimens 10, 20, and 40 min after infection, it was concluded that the rickettsiae enter initially into a tight phagosome by phagocytosis and are then released into the cell cytoplasm by disruption of the phagosomal membrane. No other mechanisms of penetration were found. On the other hand, rickettsiae inactivated by trypsin did not attach to host cells. Inactivation by heat or UV irradiation resulted in reduction of phagocytosis, and rickettsiae treated with rifamycin could penetrate into the host cell cytoplasm to the same extent as in the case of infection with intact rickettsiae.     

Electron microscopic study of the interaction of Yersinia pseudotuberculosis with macrophages and HeLa cells

The comparative electron-microscopic study of early stages of the interaction of Y. pseudotuberculosis virulent strain (No. 282) with "professional" (macrophages) and "nonprofessional" (HeLa cells) phagocytes has been carried out. The character of the intimate mechanism of this interaction has been found to be essentially different. The common feature for both systems is the adsorption of bacteria and their penetration into cells due to phagocytosis. But the subsequent fate of Y. pseudotuberculosis is different. In HeLa cells they are isolated from the cytoplasm by multilayer membrane structures, thus remaining morphologically intact. In macrophages the destruction of the microbe in phagolysosomes occurs.     

Acquisition of thymidylate by the obligate intracytoplasmic bacterium Rickettsia prowazekii.

The pathway for the acquisition of thymidylate in the obligate bacterial parasite Rickettsia prowazekii was determined. R. prowazekii growing in host cells with or without thymidine kinase failed to incorporate into its DNA the [3H]thymidine added to the culture. In the thymidine kinase-negative host cells, the label available to the rickettsiae in the host cell cytoplasm would have been thymidine, and in the thymidine kinase-positive host cells, it would have been both thymidine and TMP. Further support for the inability to utilize thymidine was the lack of thymidine kinase activity in extracts of R. prowazekii. However, [3H]uridine incorporation into the DNA of R. prowazekii was demonstrable (973 +/- 57 dpm/3 x 10(8) rickettsiae). This labeling of rickettsial DNA suggests the transport of uracil, uridine, uridine phosphates (UXP), or 2'-deoxyuridine phosphates, the conversion of the labeled precursor to thymidylate, and subsequent incorporation into DNA. This is supported by the demonstration of thymidylate synthase activity in extracts of R. prowazekii. The enzyme was determined to have a specific activity of 310 +/- 40 pmol/min/mg of protein and was inhibited greater than or equal to 70% by 5-fluoro-dUMP. The inability of R. prowazekii to utilize uracil was suggested by undetectable uracil phosphoribosyltransferase activity and by its inability to grow (less than 10% of control) in a uridine-starved mutant cell line (Urd-A) supplemented with 50 microM to 1 mM uracil. In contrast, the rickettsiae were able to grow in Urd-A cells that were uridine starved and supplemented with 20 microM uridine (117% of control). However, no measurable uridine kinase activity could be measured in extracts of R. prowazekii. Normal rickettsial growth (92% of control) was observed when the host cell was blocked with thymidine so that the host cell's dUXP pool was depressed to a level inadequate for growth and DNA synthesis in the host cell. Taken together, these data strongly suggest that rickettsiae transport UXP from the host cell's cytoplasm and that they synthesize TTP from UXP.     

Characteristics of rickettsial morphology during intracellular development

The normal anatomy of rickettsiae has been characterized with the use of R. prowazekii, R. conorii and R. akari in continuous cell cultures L-929, Al, FL and in primary chick embryo fibroblast culture. Rickettsiae are short rod-shaped cells with the dense cytoplasm and the regular structure of the cell wall--cytoplasmic membrane complex. The study has shown the absence of polymorphism in rickettsiae growing under permissive conditions, but at the same time these organisms easily develop into pathological forms. Pathological forms can be detected alongside normal rickettsiae in the same cells. The classification of the pathological forms of rickettsiae is presented. In this classification the compensating (reversible) and destructive (irreversible) forms of alterations, as well as hypertrophic and dystrophic processes on the level of the whole rickettsial cell or its organelles, are pointed out.     

Acquisition of polyamines by the obligate intracytoplasmic bacterium Rickettsia prowazekii.

Both the polyamine content and the route of acquisition of polyamines by Rickettsia prowazekii, an obligate intracellular parasitic bacterium, were determined. The rickettsiae grew normally in an ornithine decarboxylase mutant of the Chinese hamster ovary (C55.7) cell line whether or not putrescine, which this host cell required in order to grow, was present. The rickettsiae contained approximately 6 mM putrescine, 5 mM spermidine, and 3 mM spermine when cultured in the presence or absence of putrescine. Neither the transport of putrescine and spermidine by the rickettsiae nor a measurable rickettsial ornithine decarboxylase activity could be demonstrated. However, we demonstrated the de novo synthesis of polyamines from arginine by the rickettsiae. Arginine decarboxylase activity (29 pmol of 14CO2 released per h per 10(8) rickettsiae) was measured in the rickettsiae growing within their host cell. A markedly lower level of this enzymatic activity was observed in cell extracts of R. prowazekii and could be completely inhibited with 1 mM difluoromethylarginine, an irreversible inhibitor of the enzyme. R. prowazekii failed to grow in C55.7 cells that had been cultured in the presence of 1 mM difluoromethylarginine. After rickettsiae were grown in C55.7 in the presence of labeled arginine, the specific activities of arginine in the host cell cytoplasm and polyamines in the rickettsiae were measured; these measurements indicated that 100% of the total polyamine content of R. prowazekii was derived from arginine.     

Ultrastructural study on Japanese isolates of spotted fever group rickettsiae

Japanese isolates of spotted fever group rickettsiae were observed under a transmission electron microscope. In Vero cells persistently infected with Japanese isolates, small numbers of intracytoplasmic rickettsiae were seen. On the other hand, moderate numbers of rickettsiae were found in the cytoplasm of productively infected BHK cells. The electron-lucent, halo-like zone was found to surround organisms in the cytoplasm of their host cells, which is a prominent characteristic of spotted fever group rickettsiae. Fine structural features of the cell wall revealed thin outer and thick inner leaflets like those observed in other spotted fever group rickettsiae.     

Electron Microscopic Studies on Intracellular Multiplication of Rickettsia tsutsugamushi in L Cells

The mechanism and kinetics of intracellular growth of Rickettsia tsutsugamushi were investigated by electron microscopic observations, parallel with quantitative analysis by counting the rickettsiae seen in electron micrographs and by plaque assay for infectivity of the culture. The observations demonstrated the existence of electron-less dense and -dense types of rickettsiae in the early stage of infection, binary fission and the process of release of the microorganisms in the host cell cytoplasm and from the cell surface, formation of abnormally long rickettsiae, and the process of lysis of the host cell in the later stage of infection with vacuole formation between the inner and outer leaflets of the host cell nuclear membrane. Separate titrations of infectivity of the cells and the culture fluid showed a very slow increase in infectivity in the culture fluid compared with the intracellular titer, suggesting that the progeny rickettsiae stay in the cell or at the cell surface for a relatively long period. Doubling time of the rickettsia was found to be about 9 hr.     

The ultrastructure of the interaction of Rickettsia sibirica and R. slovaca with the cells of ixodid ticks

The ultrastructural aspects of the interaction of R. sibirica and R. slovaca with cells of mites of the species Dermacentor reticulatus, D. marginatus and Ixodes ricinus after their parenteral infection, as well as in the organs of D. marginatus infected naturally in the environment, have been studied. Both rickettsial species have similar morphology in different organs of the vector. These rickettsiae not only multiply, their populations are also partly destroyed in phagolysosomes. The natural mixed infection of R. sibirica and orbivirus in cells of D. reticulatus is described. As shown in this study, both associates pass through the complete ontogenetic cycle of development on the level of the host body and also on the level of an individual cell.     

Ultrastructure of a Japanese Rickettsial strain genetically identified as Rickettsia helvetica which was originally found in Europe

A rickettsial strain IO-1 has been isolated from a tick, Ixodes ovatus, in Japan and genetically identified as Rickettsia helvetica, a member of the spotted fever group rickettsiae. Ultrastructural observations were made on the microorganism. The ultrastructure of R. helvetica IO-1 appeared to be generally the same as that previously shown for other rickettsiae of the spotted fever and typhus groups. The rickettsiae were primarily found free in the cytoplasm of L929 cultured cells. Occasionally, the rickettsiae may also invade the host cell nucleus; however, the frequency of the nuclear localization was very low.     

On the nature of obligate intracellular symbiosis of rickettsiae — Rickettsia prowazekii cells import mitochondrial porin

Mitochondrial porin was identified in Rickettsia prowazekii by Western blot analysis of whole cells and membrane fractions with monoclonal antibody against porin VDAC 1 of animal mitochondria. Using the BLAST server, no protein sequences homologous to mitochondrial porin were found among the rickettsial genomes. Rickettsiae also do not contain their own porin. The protein imported by rickettsiae is weakly extracted by nonionic detergents and, like porin in mitochondria, is insensitive to proteinase K in whole cells. Immunocytochemical analysis showed that it localizes to the outer membrane of the bacterial cells. These data support an earlier suggestion about import by rickettsiae of indispensable proteins from cytoplasm of the host cell as a molecular basis of obligate intracellular parasitism. They are also consistent with the hypothesis invoking a transfer of genes specifying surface proteins from the last common ancestor of rickettsiae and mitochondria to the host genome, and preservation by rickettsiae of the primitive ability to import these proteins.     

Epitheliocystis disease in the striped bass Morone saxatilis from the Chesapeake Bay.

Epitheliocystis disease in the gills of the striped bass Morone saxatilis from Chesapeake Bay was studied using light and electron microscopy. The epitheliocystis infection appeared synchronous in that all capsules on a single host were at the same stage of development. The disease appeared to begin in a single cell on the gill lamella, which gradually enlarged to form a large cyst, encapsulated by a thick cellular capsule of epithelial origin. The epitheliocystis inclusion was filled with cells of the general morphology and size of rickettsiae; however, the infection was atypical for rickettsiae in that the cells had a dense central nucleoid region and they developed within an inclusion separated from the host cytoplasm.     

Characterization and growth of polymorphic Rickettsia felis in a tick cell line

Morphological differentiation in some arthropod-borne bacteria is correlated with increased bacterial virulence, transmission potential, and/or as a response to environmental stress. In the current study, we utilized an in vitro model to examine Rickettsia felis morphology and growth under various culture conditions and bacterial densities to identify potential factors that contribute to polymorphism in rickettsiae. We utilized microscopy (electron microscopy and immunofluorescence), genomic (PCR amplification and DNA sequencing of rickettsial genes), and proteomic (Western blotting and liquid chromatography-tandem mass spectrometry) techniques to identify and characterize morphologically distinct, long-form R. felis. Without exchange of host cell growth medium, polymorphic R. felis was detected at 12 days postinoculation when rickettsiae were seeded at a multiplicity of infection (MOI) of 5 and 50. Compared to short-form R. felis organisms, no change in membrane ultrastructure in long-form polymorphic rickettsiae was observed, and rickettsiae were up to six times the length of typical short-form rickettsiae. In vitro assays demonstrated that short-form R. felis entered into and replicated in host cells faster than long-form R. felis. However, when both short- and long-form R. felis organisms were maintained in cell-free medium for 12 days, the infectivity of short-form R. felis was decreased compared to long-form R. felis organisms, which were capable of entering host cells, suggesting that long-form R. felis is more stable outside the host cell. The relationship between rickettsial polymorphism and rickettsial survivorship should be examined further as the yet undetermined route of horizontal transmission of R. felis may utilize metabolically and morphologically distinct forms for successful transmission.     

S-adenosylmethionine transport in Rickettsia prowazekii

Rickettsia prowazekii, the causative agent of epidemic typhus, is an obligate, intracellular, parasitic bacterium that grows within the cytoplasm of eucaryotic host cells. Rickettsiae exploit this intracellular environment by using transport systems for the compounds available in the host cell's cytoplasm. Analysis of the R. prowazekii Madrid E genome sequence revealed the presence of a mutation in the rickettsial metK gene, the gene encoding the enzyme responsible for the synthesis of S-adenosylmethionine (AdoMet). Since AdoMet is required for rickettsial processes, the apparent inability of this strain to synthesize AdoMet suggested the presence of a rickettsial AdoMet transporter. We have confirmed the presence of an AdoMet transporter in the rickettsiae which, to our knowledge, is the first bacterial AdoMet transporter identified. The influx of AdoMet into rickettsiae was a saturable process with a K(T) of 2.3 micro M. Transport was inhibited by S-adenosylethionine and S-adenosylhomocysteine but not by sinfungin or methionine. Transport was also inhibited by 2,4-dinitrophenol, suggesting an energy-linked transport mechanism, and by N-ethylmaleimide. AdoMet transporters with similar properties were also identified in the Breinl strain of R. prowazekii and in Rickettsia typhi. By screening Escherichia coli clone banks for AdoMet transport, the R. prowazekii gene coding for a transporter, RP076 (sam), was identified. AdoMet transport in E. coli containing the R. prowazekii sam gene exhibited kinetics similar to that seen in rickettsiae. The existence of a rickettsial transporter for AdoMet raises intriguing questions concerning the evolutionary relationship between the synthesis and transport of this essential metabolite.     

Comparison of the ultrastructure of several rickettsiae, ornithosis virus, and Mycoplasma in tissue culture

Anderson, Douglas R. (National Cancer Institute, Bethesda, Md.), Hope E. Hopps, Michael F. Barile, and Barbara C. Bernheim. Comparison of the ultrastructure of several rickettsiae, ornithosis virus, and Mycoplasma in tissue culture. J. Bacteriol. 90:1387-1404. 1965.-In an effort to make a valid comparison of the ultrastructure of several intracellular parasites, selected agents were propagated under identical conditions in a single type of tissue culture cell; such infected preparations were processed for examination by electron microscopy by use of a standardized procedure for fixation and embedding. The organisms studied were: the Breinl and E strains of epidemic typhus, Rickettsia prowazeki; the Bitterroot strain of R. rickettsii; the Karp strain of R. tsutsugamushi (R. orientalis); R. sennetsu; the P-4 strain of ornithosis virus; and the HEp-2 strain of Mycoplasma hominis type I. Each of the rickettsial species examined had a cell wall and a plasma membrane, and contained ribosomes and deoxyribonucleic acid (DNA) in a ground substance. However, certain differences were noted. Both strains of R. prowazeki contained numerous intracytoplasmic electron-lucent spherical structures (4 to 10 mmu), not previously described. R. sennetsu, unlike the other rickettsiae, was not free in the host cytoplasm but was always enclosed in a vacuole. R. rickettsii was observed intranuclearly and in digestive organelles of the host cell as well as in the cytoplasm. Cells infected with ornithosis virus contained several forms representing the stages in its life cycle. The "initial bodies," made up of ribosomes and DNA strands, were morphologically similar to the rickettsiae. In cultures infected with M. hominis, most of the cells became large and multinucleate. Although the Mycoplasma organisms were readily cultivated from these cultures, only a few could be found in the electron microscope preparations. These organisms were extracellular and lacked a cell wall, being bound only by a unit membrane. Again, the internal components were ribosomes and DNA strands. Under the uniform preparative conditions employed here, the three groups of organisms were morphologically distinguishable from one another.     

Rickettsiae in gill epithelial cells of the hard clam, Mercenaria mercenaria

Rickettsiae are found in the gill epithelium of the hard clam, Mercenaria mercenaria. The procaryotes occur free in the cytoplasm of the epithelial cells at the tip of the filament and in the more proximal cells that support the lateral J cilia. The fine structure of the organisms, showing rippled cell walls, is typical of the rickettsiae. The increasing size of the inclusion representing late phase growth often culminates in lysis of the host cell. Masses (Gram-negative, Feulgen-positive) in ova, similar to those observed in the gill epithelium, suggest that transovarian transmission may occur.     

Electron microscopic studies on the interaction of rat Kupffer cells and Plasmodium berghei sporozoites

The interactions between Plasmodium berghei sporozoites and Kupffer cells in rat liver were studied by transmission electron microscopy. Between 10 and 45 min after inoculation, sporozoites were found in the process of entering Kupffer cells and inside phagolysosomes. The sporozoites entered the Kupffer cells by phagocytosis as determined by the presence of pseudopods and local accumulations of aggregated microfilaments and the resulting exclusion of other organelles in the phagocyte cytoplasm beneath the attached parasite. Sporozoites were taken up either with their anterior end first, or backwards. Scanning electron microscopy of in vitro sporozoite Kupffer cell interaction confirmed these observations. It was concluded that sporozoites are taken up in a normal phagocytic way by the Kupffer cells, regardless of their initial place of contact or position. Thirty min after inoculation sporozoites found in phagolysosomes were still morphologically intact but after 45 min we could encounter completely digested sporozoites.