Transfection of the Giardia lamblia double-stranded RNA virus into giardia lamblia by electroporation of a single-stranded RNA copy of the viral genome.

The development of a genetic vector for protozoan parasites is a major hurdle yet to be crossed in the study of the molecular and cellular biology of these parasites. We have identified and isolated a double-stranded RNA virus (G. lamblia virus [GLV]) from certain strains of the intestinal parasitic protozoan Giardia lamblia (A. L. Wang and C. C. Wang, Mol. Biochem. Parasitol. 21:269-276, 1986), which is capable of infecting other virus-free strains of G. lamblia (R. L. Miller, A. L. Wang, and C. C. Wang, Exp. Parasitol. 66:118-123, 1988). Here we demonstrate that G. lamblia can be infected with GLV by electroporating uninfected cells with purified single-stranded RNA (E. S. Furfine, T. C. White, A. L. Wang, and C. C. Wang, Nucleic Acids Res. 17:7453-7467, 1989) representing a full-length copy of one strand of the GLV double-stranded RNA genome. To the best of our knowledge, this is the first demonstration in vivo that a single-stranded RNA is a competent replicative intermediate for this class of double-stranded RNA virus. In addition, this result represents the first long-term transfection of a protozoan by a single species of RNA and will hopefully expedite the development of GLV as a genetic transfecting vector.     

Identification of Giardia lamblia isolates susceptible and resistant to infection by the double-stranded RNA virus

The presence or absence of the Giardia lamblia double-stranded RNA virus (GLV) was surveyed among 38 axenic isolates of G. lamblia derived from both humans and animals. Of the 28 isolates lacking the virus, 19 could readily be infected by the virus. The remaining 9 isolates proved to be resistant to GLV infection even when the ratio between virus to parasite reached as high as 10(6) to 1. Evidence is also presented indicating that there are at least two "Portland 1" strains being used by the current scientific community, one containing the virus and the other lacking the virus.     

RNA dependent RNA polymerase activity associated with the double-stranded RNA virus of Giardia lamblia.

Giardia lamblia, a parasitic protozoan, can contain a double-stranded RNA (dsRNA) virus, GLV (1). We have identified an RNA polymerase activity present specifically in cultures of GLV infected cells. This RNA polymerase activity is present in crude whole cell lysates as well as in lysates from GLV particles purified from the culture medium. The RNA polymerase has many characteristics common to other RNA polymerases (e.g. it requires divalent cations and all four ribonucleoside triphosphates), yet it is not inhibited by RNA polymerase inhibitors such as alpha-amanitin or rifampicin. The RNA polymerase activity synthesizes RNAs corresponding to one strand of the GLV genome, although under the present experimental conditions, the RNA products of the reaction are not full length viral RNAs. The in vitro products of the RNA polymerase reaction co-sediment through sucrose gradients with viral particles; and purified GLV viral particles have RNA polymerase activity. The RNA polymerase activities within and outside of infected cells closely parallel the amount of virus present during the course of viral infection. The similarities between the RNA polymerase of GLV and the polymerase associated with the dsRNA virus system of yeast are discussed.     

The course of giardiavirus infection in the Giardia lamblia trophozoites

The subcellular distribution of Giardia lamblia virus RNA in infected G. lamblia trophozoites was examined by in situ hybridization using biotinylated DNA probe and riboprobe. In G. lamblia Portland I strain, which is chronically infected by G. lamblia viruses, the viral RNA was detected in the cytoplasm as well as in the twin nuclei. When riboprobe was used to examine the course of virus infection in WB strain, accumulation of viral RNA was detected only in the cytoplasm prior to the first 72 hr of infection. Using DNA probe, further accumulation of viral RNA in increasing number of cells occurred after the 72nd hr of infection, with the RNA found in both the cytoplasm and nuclei. Eventually, the cell nuclei showed damaged morphology that deteriorated rapidly toward the final stage of infection. These observations indicate that early phase of viral RNA replication may take place in the cytoplasm of infected G. lamblia, but the nuclei are also involved during the late phase of viral replication.     

A single-stranded RNA copy of the Giardia lamblia virus double-stranded RNA genome is present in the infected Giardia lamblia.

An isolate of Giardia lamblia infected with the double-stranded RNA virus (GLV) has two major species of RNA that are not present in an uninfected isolate. One of these species is the previously characterized double-stranded RNA genome of GLV (1). The second species of RNA appears to be a full length copy of one strand of the double-stranded RNA genome. This full length single-stranded RNA is not present in viral particles isolated from the growth medium. The cellular concentration of the single-stranded RNA changes during exponential and stationary phases of cell growth in a fashion consistent with a viral replicative intermediate or mRNA. The single-stranded species does not appear to be polyadenylated.     

Replication of mengovirus. I. Effect on synthesis of macromolecules by host cell

Plagemann, Peter G. W. (Western Reserve University, Cleveland, Ohio), and H. Earle Swim. Replication of mengovirus. I. Effect on synthesis of macromolecules by host cell. J. Bacteriol. 91:2317-2326. 1966.-The replication of mengovirus was studied in two strains of Novikoff (rat) hepatoma cells propagated in vitro. The replicative cycle in both strains required 6.5 to 7 hr. Infection resulted in a marked depression of ribonucleic acid (RNA) and protein synthesis by strain N1S1-63. Inhibition of RNA synthesis was reflected by a decrease in the deoxyribonucleic acid (DNA)-dependent RNA polymerase activity of isolated nuclei. Mengovirus had no effect on either protein or RNA synthesis or on the DNA-dependent RNA polymerase activity of a second strain, N1S1-67. The time course of viral-induced synthesis of RNA by cells was studied in cells treated with actinomycin D. It was first detectable between 2.5 and 3 hr after infection and continued until 6.5 to 7 hr. The formation of mature virus was estimated biochemically by measuring the amount of RNA synthesized as a result of viral infection which was resistant to degradation by ribonuclease in the presence of deoxycholate. Approximately 70% of the deoxycholate-ribonuclease-resistant RNA was located in mature virus, and the remainder was double-stranded. The formation of mature virus began about 45 min after viral-directed (actinomycin-resistant) synthesis of RNA was detectable in the cell, and only about 18 to 20% of the total RNA synthesized was incorporated into virus. Release of virus from cells began about 1 hr after maturation was first detectable. Release of virus from cells was accompanied by a loss of a large proportion of their cytoplasmic RNA and protein.     

Maturation of giardiavirus capsid protein involves posttranslational proteolytic processing by a cysteine protease.

The double-stranded RNA genome of giardiavirus (GLV) has only two large open reading frame (ORFs). The 100-kDa capsid polypeptide (p100) is encoded by ORF1, whereas the only other viral polypeptide, the 190-kDa GLV RNA-dependent RNA polymerase (p190), is synthesized as an ORF1-ORF2 fusion protein by a (-1) ribosomal frameshifting. Edman degradation revealed that p100 was N-terminally blocked except for 2 to 5% of it that showed free N terminus starting from amino acid residue 33 of ORF1. Studies using antiserum targeted against amino acid residues 6 to 27 indicated that this region (NT) is absent from viral p100 and p190, while pulse-labelling experiments showed that NT is present in nascent p100 synthesized in GLV-infected Giardia lamblia but removed subsequently. In contrast, this region was retained in the two viral proteins synthesized in vitro, and it was not removed upon prolonged incubation or inclusion of microsomal fraction in the in vitro translation reaction mixtures. These results suggest that endoplasmic reticulum is not involved in the protein processing and that the precursors of p100 and p190 are incapable of cleaving themselves or each other. This specific cleavage was reproduced when lysates from GLV-infected G. lamblia were added, but not those from uninfected cells. The cleavage activity was relatively insensitive to phenylmethylsulfonyl fluoride, but it was inhibitable by leupeptin or E-64, two known specific inhibitors of cysteine protease. The possible origin of this processing activity is discussed.     

Spontaneous chromosome rearrangements in the protozoan Giardia lamblia: estimation of mutation rates.

Subcloned lines of the WB strain of Giardia lamblia contain polymorphic ribosomal RNA (rRNA) encoding chromosomes (Le Blancq et al., Nucl. Acids Res. 1991, 19, 4405-4412). We show that in a continuously propagated culture of G.lamblia trophozoites the proportion of trophozoites with rearranged rRNA encoding chromosomes gradually increases, consistent with the high mutation rate of about 1% per cell per division cycle. This conclusion is based on the finding in one experiment that after about 8 division cycles 20% of the population consisted of independent mutants, while after approximately 100 division cycles 87.5% of the population were independent mutants. In a second experiment, approximately 38% and 71.5% of the trophozoites were independent mutants after approximately 9 and approximately 100 division cycles, respectively. The data show that the genome of the WB strain of G.lamblia has a highly recombinogenic phenotype. Extensive karyotype heterogeneity has also been observed among recently isolated G.lamblia strains obtained from a defined geographic area (Korman et al., J. Clin. Invest. 1992, 89, 1725-1733) suggesting that a high mutation rate might also occur in vivo.     

A linear double-stranded RNA in Trichomonas vaginalis

A "double-stranded" RNA was identified in the anaerobic, parasitic protozoan Trichomonas vaginalis. Electron microscopic evidence indicated linear double-stranded structure 1.5 micron in length, with no apparent hairpins or loops. Boiling in 30% dimethyl sulfoxide denatured it into single strands of 1.5 micron and shorter fragments. It consists of 23.4% G, 23.4% C, 23.0% A, and 30.3% U and melts at a transition temperature of 81.7 degrees C in 75 mM NaCl and 7.5 mM sodium citrate, pH 7.0, with 7-15% hyperchromicity. The 32P-labeled double-stranded RNA hybridized specifically with T. vaginalis DNA fragments in a single DNA band from EcoRI digest and two DNA bands from HindIII digest. Of the 33 different strains or isolates of T. vaginalis examined, all contained this double-stranded RNA. However, the only two metronidazole-resistant T. vaginalis strains examined thus far (IR78 and 85) contained no detectable double-stranded RNA, although the corresponding DNA sequence was present. DNA fragments of Escherichia coli and Giardia lamblia did not hybridize with the double-stranded RNA. But DNA fragments of a metronidazole-sensitive Tritrichomonas foetus hybridized specifically with the double-stranded RNA, even though this organism does not contain the double-stranded RNA itself.     

Giardia lamblia: electrophysiology and ultrastructure of cytopathology in cultured epithelial cells

The pathogenicity of Giardia lamblia is a subject of debate. Some studies of human biopsy material have mentioned the presence of trophozoites inside the intestinal mucosa, while in others, flagellates have only been found attached to the epithelium. To study the possible cytopathic effects of G. lamblia cultured under axenic conditions, trophozoites of the human 1/Portland and WB strains were placed in contact with monolayers of Madin Derby Canine Kidney cells, a well characterized cell strain with morphological and functional properties similar to those of a transporting epithelium. After 24 and 48 hr of interaction, the effect of the parasite on epithelial cells was assessed by transmission, scanning, and freeze fracture electron microscopy. In addition, the possible action of living trophozoites and sonicates of G. lamblia on the transepithelial resistance of MDCK monolayers mounted in Ussing chambers was analyzed for periods varying up to 48 hr. The results demonstrate that G. lamblia trophozoites do not invade epithelial monolayers. Furthermore, the parasites fail to produce cytoplasmic changes on target cells and have no effect on transepithelial resistance as judged both electrophysiologically and by the failure to open the occluding junctions that bind together epithelial cells. Damage induced by the parasites to cultured cells was limited to focal distortion or depletion of microvilli at the site of adhesion, which may progress to leave circular areas devoid of microvilli, different from the adhesion marks reported by others for G. muris. Therefore, under the in vitro conditions described here, giardias showed no toxic or invasive effect.     

Excretory-secretory products of Giardia lamblia

The surface of Giardia lamblia strain WB was radioiodinated with either 1,3,4,6-tetrachloro-3 alpha, 6 alpha-diphenylglycoluril (IODOGEN) or lactoperoxidase, and the labeled membrane components as well as the released excretory-secretory (E-S) products were identified. The surface of G. lamblia was easily labeled, and G. lamblia excretory-secretory (E-S) products were identified in the medium. Over 70% of the label on the cell surface was released over 24 hr. The major E-S product released was polydisperse (m.w. 225 to 94,000), protease VI and periodate-sensitive, chloroform-methanol insoluble, and failed to adhere to a series of carbohydrate-binding lectins or to diethylaminoethyl (DEAE) cellulose. Hydrophobicity was suggested by adherence to phenyl-Sepharose. The major E-S product of another G. lamblia isolate, Portland-1 (P-1), was antigenically different. A previous study showed that strain P-1 lacked a major antigenic component of strain WB. In the present study, this material was identified as the major secretory product of WB by crossed immunoelectrophoresis.     

Viruses of parasitic protozoa

Recently, specific viruses have been identified among the parasitic protozoa Trichomonas vaginalis, Giardia lamblia, Leishmania braziliensis, the Eimeria spp and the Babesia spp. These viruses share many features: they are all RNA viruses and most, if not all, doublestranded (ds) RNA viruses with nonsegmented genomes ranging between 5 and 7 kilobases (kb); they are spherical or icosahedral with an average diameter of 30-40 nm. The giardiavirus is one of the best characterized and can infect virus free G. lamblia trophozoites in its freed, pure form. The replicative intermediate of the giardiavirus genome has been isolated from infected cells, and can be introduced into G. lamblia by electroporation to produce giardiavirus, thus raising the possibility of its being used as a specific genetic transfection vector for the parasite.     

Giardia lamblia: identification of different strains from man

Four axenically cultured human Giardia lamblia isolates from Jerusalem (KC-1, 2, 3 and 4) and one from Bethesda (WB) were compared. Three distinct groups were defined by agglutination response to rabbit anti-G. lamblia sera viz. WB; KC-3; and KC-1, 2 and 4. The same major groups were identified by isoenzyme analysis using thin-layer starch-gel electrophoresis, each group differing from the others in three or more of five enzymes studied. In addition, a single enzyme difference distinguished KC-2 from KC-1 and 4. These findings reveal significant heterogeneity in G. lamblia isolates both from widely separated areas and within a single region. Immunoassays for diagnosis of giardiasis should take into account the differences between strains. Heterogeneity among G. lamblia strains may explain the variable clinical manifestations, host response and treatment efficacy characteristic of human giardiasis.     

Mengovirus Replication in Novikoff Rat Hepatoma and Mouse L Cells: Effects on Synthesis of Host-Cell Macromolecules and Virus-specific Synthesis of Ribonucleic Acid

Novikoff cells (strain N1S1-67) and L-67 cells, a nutritional mutant of the common strain of mouse L cells which grows in the same medium as N1S1-67 cells, were infected with mengovirus under identical experimental conditions. The synthesis of host-cell ribonucleic acid (RNA) by either type of cell was not affected quantitatively or qualitatively until about 2 hr after infection, when viral RNA synthesis rapidly displaced the synthesis of cellular RNA. The rate of synthesis of protein by both types of cells continued at the same rate as in uninfected cells until about 3 hr after infection, and a disintegration of polyribosomes occurred only towards the end of the replicative cycle, between 5 and 6 hr. The time courses and extent of synthesis of single-stranded and double-stranded viral RNA and of the production of virus were very similar in both types of cells, in spite of the fact that the normal rate of RNA synthesis and the growth rate of uninfected N1S1-67 cells are about three times greater than those of L-67 cells. In both cells, the commencement of viral RNA synthesis coincided with the induction of viral RNA polymerase, as measured in cell-free extracts. Viral RNA polymerase activity disappeared from infected L-67 cells during the period of production of mature virus, but there was a secondary increase in activity in both types of cells coincidental with virus-induced disintegration of the host cells. Infected L-67 cells, however, disintegrated and released progeny virus much more slowly than N1S1-67 cells. The two strains of cells also differed in that replication of the same strain of mengovirus was markedly inhibited by treating N1S1-67 cells with actinomycin D prior to infection; the same treatment did not affect replication in L-67 cells.     

Inhibition of Host-Cell Protein and Ribonucleic Acid Synthesis by Newcastle Disease Virus

The mechanisms of Newcastle disease virus-(NDV) induced inhibition of cell protein and ribonucleic acid (RNA) synthesis were investigated. It was observed that the ability of NDV to inhibit cell RNA synthesis is dependent on the virus strain. The inhibitors, azauridine and cycloheximide, were added to cell cultures at different times after infection to study the roles of protein and RNA synthesis in the viral inhibition process. Viral inhibition of cell RNA synthesis and viral inhibition of cell protein synthesis become resistant to cycloheximide at a different time after infection than that in which they become resistant to azauridine. The results indicate that the inhibition of cell RNA synthesis by the Texas strain involves the synthesis of inhibitory proteins which are coded by the viral genome. The Texas and Beaudette strains of NDV appear to employ different mechanisms for the inhibition of host-cell protein synthesis. Viral inhibition of cell protein synthesis does not appear to cause, or be the result of, viral inhibition of cell RNA synthesis.     

The neurovirulent GDVII strain of Theiler's virus can replicate in glial cells.

The distribution, spread, neuropathology, tropism, and persistence of the neurovirulent GDVII strain of Theiler's virus in the central nervous system (CNS) was investigated in mice susceptible and resistant to chronic demyelinating infection with TO strains. Following intracerebral inoculation, the virus spread rapidly to specific areas of the CNS. There were, however, specific structures in which infection was consistently undetectable. Virus spread both between adjacent cell bodies and along neuronal pathways. The distribution of the infection was dependent on the site of inoculation. The majority of viral RNA-positive cells were neurons. Many astrocytes were also positive. Infection of both of these cell types was lytic. In contrast, viral RNA-positive oligodendrocytes were rare and were observed only in well-established areas of infection. The majority of oligodendrocytes in these areas were viral RNA negative and were often the major cell type remaining; however, occasional destruction of these cells was observed. No differences in any of the above parameters were observed between CBA and BALB/c mice, susceptible and resistant, respectively, to chronic CNS demyelinating infection with TO strains of Theiler's virus. By using Southern blot hybridization to detect reverse-transcribed PCR-amplified viral RNA sequences, no virus persistence could be detected in the CNS of immunized mice surviving infection with GDVII. In conclusion, the GDVII strain of Theiler's murine encephalomyelitis virus cannot persist in the CNS, but this is not consequent upon an inability to infect glial cells, including oligodendrocytes.