Rescue of a positive stranded RNA virus from antigen negative neuroblastoma cells.

Single cell clones of latently infected mouse neuroblastoma cells were isolated from a culture chronically infected with mouse hepatitis virus in the presence of an antiviral antibody. These cell clones did not produce infections virus or exhibit viral cytopathic effects during cultivation at 32, 37, or 39°C. Infectious virus was isolated from single cell clones via fusion with permissive cells using polyethylene glycol, but not after fusion with inactivated Sendai virus or following treatment with metabolic inhibitors. One cell clone (S-3) from which virus was rescued was negative for viral antigen by immunofluorescence. The S-3 cell clone and no demonstrable virus antigen by complement-fixation tests using cytoplasmic extracts or virus-specified proteins detectable by polyacrylamide gel electrophoresis. The rescued viruses exhibited a temperature dependent growth defect at 32°C and have been classified as cold sensitive mutants. This study suggests that a complete genome of a positive stranded RNA virus can remain latent in infected cells without the expression of detectable virus antigen.     

Formation of Viral Ribonucleic Acid and Virus in Cells that are Permissive or Nonpermissive for Murine Encephalomyelitis Virus (GDVII)

GDVII virus growth in BHK-21 cells, a permissive host for the virus, resembled productive infections with other picornaviruses. Virus yields ranged from 100 to 600 plaque-forming units (PFU)/cell. Virus replication in HeLa cells, a nonpermissive host for GDVII virus, was characterized by virus yields of only 0.1 to 5 PFU/cell. Similar low yields of virus have been obtained from HeLa cells at all multiplicities of input up to 6,000 per cell. The progeny particles from HeLa cells were, like the infecting particles, restricted in the HeLa cell host. Despite the great difference in final yields of virus from BHK-21 and HeLa cells, the times when maximal yields were reached were similar. GDVII virus stock grown in BHK-21 cells was designated HeLa(-). A variant of GDVII virus which is capable of extensive growth in HeLa cells was obtained. This variant, designated HeLa(+) GDVII virus, was passaged serially in HeLa cells. Virus yields of 50 to 150 infective virus particles per cell were obtained from infection of HeLa cells with HeLa(+) GDVII virus. The major species of HeLa(+) virus-specific ribonucleic acid (RNA) produced was single stranded and sedimented with an S value of 35S. The rate of accumulation of HeLa(+) virus-specific RNA in HeLa cell cultures was about four times that of HeLa(-) RNA. The amount of virus-specific HeLa(+) RNA formed in HeLa cells was several-fold greater than that of HeLa(-) RNA. With HeLa(-) parent GDVII virus undergoing productive replication in BHK-21 cells or abortive replication in HeLa cells, the major species of virus-specific RNA produced was single stranded and sedimented with an approximate S value of 35S. The amount of HeLa(-) virus-specific RNA extracted from BHK-21 cells was several-fold greater than the amount obtained from HeLa cells.     

Development of novel single-stranded nucleic acid aptamers against the pro-angiogenic and metastatic enzyme heparanase (HPSE1)

Heparanase is an enzyme involved in extracellular matrix remodelling and heparan sulphate proteoglycan catabolism. It is secreted by metastatic tumour cells, allowing them to penetrate the endothelial cell layer and basement membrane to invade target organs. The release of growth factors at the site of cleaved heparan sulphate chains further enhance the potential of the tumour by encouraging the process of angiogenesis. This leads to increased survival and further proliferation of the tumour. Aptamers are single or double stranded oligonucleotides that recognise specific small molecules, peptides, proteins, or even cells or tissues and have shown great potential over the years as diagnostic and therapeutic agents in anticancer treatment. For the first time, single stranded DNA aptamers were successfully generated against the active heterodimer form of heparanase using a modified SELEX protocol, and eluted based on increasing affinity for the target. Sandwich ELISA assays showed recognition of heparanase by the aptamers at a site distinct from that of a polyclonal HPSE1 antibody. The binding affinities of aptamer to immobilised enzyme were high (7 × 10(7) to 8 × 10(7) M(-1)) as measured by fluorescence spectroscopy. Immunohistochemistry and immunofluorescence studies demonstrated that the aptamers were able to recognise heparanase with staining comparable or in some cases superior to that of the HPSE1 antibody control. Finally, matrigel assay demonstrated that aptamers were able to inhibit heparanase. This study provides clear proof of principle concept that nucleic acid aptamers can be generated against heparanase. These reagents may serve as useful tools to explore the functional role of the enzyme and in the future development of diagnostic assays or therapeutic reagents.     

DNA methylase: purification from ascites cells and the effect of various DNA substrates on its activity.

DNA methylase has been purified 405-fold from Krebs II ascites cells. The purified enzyme is homogeneous on SDS-poly acrylamide gel electrophoresis (molecular weight about 80,000) and the only product of the reaction with DNA is 5-methyl cytosine. Both native and denatured DNA are methylated by the enzyme; with calf thymus DNA the double stranded form is the better substrate but the enzyme preferentially methylates single stranded E.coli DNA even in "native" preparations. Our results do not support a mechanism whereby the enzyme methylates DNA by binding irreversibly and "walking" along it. By measuring maximum levels of methylation of DNAs from different sources we have estimated the proportion of unmethylated sites present in them. Homologous ascites DNA can be methylated, but only to about 5% of the level of the best substrate, undermethylated mouse L929 cell DNA. DNA isolated from growing cells or tissues is a better substrate than DNA from normal liver or pancreas, or from stationary cells.     

Inhibition of Leukaemia Virus Replication by Polyadenylic Acid

A PREVIOUS communication from this laboratory demonstrated that the DNA polymerase of the Rauscher leukaemia virus is strongly inhibited in vitro by unprimed, single stranded polyribonucleotides¹ as a result of competition between the polymers and the active template for the same enzyme binding site. This inhibition was apparently specific, since partially purified preparations of DNA polymerase from Escherichia coli and BALB/c mouse embryos were not inhibited in the same conditions. We attempted to determine therefore whether single stranded polyribonucleotides would have any effect on the activities of oncogenic RNA viruses in cultured cells.     

Molecular Aspects of Interferon Induction by Viruses

Virus-induced interferon formation depends on the presence within the cell of a viral ribonucleic acid. This RNA may either be double stranded or, in certain cases, single stranded. The double-stranded RNA can be derived from a virus, such as reovirus, which contains this type of RNA, or it may be synthesized within the cell using viral single-stranded RNA as a template. Single-stranded RNA must possess a stable configuration in solution to be active, and certain viral RNA molecules appear to be active for this reason. The presence of this RNA triggers a derepression event, which is probably nuclear, by an unknown mechanism, and this is followed by the production of an interferon messenger RNA and its translation. Little is known of the derepression event or the events that follow it.     

Dynamics and interactions of viroids

Viroids are single stranded circular RNA molecules of 120,000 daltons which are pathogens of certain higher plants and replicate autonomously in the host cell. Virusoids are similar to viroids in respect to size and circularity but do replicate only as a part of a larger plant virus. The structure and structural transitions have been investigated by thermodynamic, kinetic and hydrodynamic methods and have been compared to results from calculations of the most favorable native structures and the denaturation process. The algorithm of Zuker et al. was modified for the application to circular nucleic acids. For viroids the calculations confirm our earlier theoretical and experimental results about the extended native structure and the highly cooperative transition into a branched structure. Virusoids, although described in the literature as viroid-like, show less base pairing, branching in the native secondary structure, and only low cooperativity during denaturation. They resemble more closely the properties of random sequences with length, G:C content, and circularity as in viroids but sequences generated by a computer. The comparison of viroids, virusoids and circular RNA of random sequences underlines the uniqueness of viroid structure. The interactions of viroids with dye and oligonucleotide-ligands and with RNA-polymerase II from wheat germ, which enzyme replicates viroids in vitro, has been studied in order to correlate viroid structure and its ability for specific interactions. Specificity of the interactions may be interpreted on the basis of the neighbourhood of double stranded and single stranded regions. In the host cell viroids are localized in the cell nucleus; they may be detected as free nucleic acids and in high molecular weight complexes together with other RNA and proteins.     

Inhibition of influenza virus RNA (PB2 mRNA) expression by a modified DNA enzyme.

DNA enzymes are RNA-cleaving single stranded DNA molecules. The structure and the catalytic domain of a DNA enzyme were determined by Santro et al. in 1997. In this study, we have designed several types of DNA enzymes (PB2Dz) targeted to the PB2 mRNA translation initiation region of influenza A virus, and examined their cleavage kinetics, nuclease resistance, and a luciferase gene reporter assay. Using a synthetic substrate, these DNA enzymes were shown to have cleavage activity that is dependent on the length of the substrate recognition domain. To confer serum nuclease resistance to the DNA enzymes, we designed a new type of DNA enzyme that has the N3'-P5' phosphoramidate modification (PB2Dz-N) at each terminal. We examined the activity of this DNA enzyme in vivo. The DNA enzymes used in this study inhibited the expression of the PB2-luciferase gene in COS cells. These results suggest that DNA enzymes are potentially useful as gene inactivating agents of influenza A virus.     

The SUMOylation Pathway Restricts Gene Transduction by Adeno-Associated Viruses

Adeno-associated viruses are members of the genus dependoviruses of the parvoviridae family. AAV vectors are considered promising vectors for gene therapy and genetic vaccination as they can be easily produced, are highly stable and non-pathogenic. Nevertheless, transduction of cells in vitro and in vivo by AAV in the absence of a helper virus is comparatively inefficient requiring high multiplicity of infection. Several bottlenecks for AAV transduction have previously been described, including release from endosomes, nuclear transport and conversion of the single stranded DNA into a double stranded molecule. We hypothesized that the bottlenecks in AAV transduction are, in part, due to the presence of host cell restriction factors acting directly or indirectly on the AAV-mediated gene transduction. In order to identify such factors we performed a whole genome siRNA screen which identified a number of putative genes interfering with AAV gene transduction. A number of factors, yielding the highest scores, were identified as members of the SUMOylation pathway. We identified Ubc9, the E2 conjugating enzyme as well as Sae1 and Sae2, enzymes responsible for activating E1, as factors involved in restricting AAV. The restriction effect, mediated by these factors, was validated and reproduced independently. Our data indicate that SUMOylation targets entry of AAV capsids and not downstream processes of uncoating, including DNA single strand conversion or DNA damage signaling. We suggest that transiently targeting SUMOylation will enhance application of AAV in vitro and in vivo.     

Dynamics and Interactions of Viroids

Abstract

Viroids are single stranded circular RNA molecules of 120 000 dal tons which are pathogens of certain higher plants and replicate autonomously in the host cell. Virusoids are similar to viroids in respect to size and circularity but do replicate only as a part of a larger plant virus. The structure and structural transitions have been investigated by thermodynamic, kinetic and hydrodynamic methods and have been compared to results from calculations of the most favorable native structures and the denaturation process. The algorithm of Zuker et al. was modified for the application to circular nucleic acids.

For viroids the calculations confirm our earlier theoretical and experimental results about the extended native structure and the highly cooperative transition into a branched structure. Virusoids, although described in the literature as viroid-like, show less base pairing, branching in the native secondary structure, and only low cooperativity during denaturation. They resemble more closely the properties of random sequences with length, G:C content, and circularity as in viroids but sequences generated by a computer. The comparison of viroids, virusoids and circular RNA of random sequences underlines the uniqueness of viroid structure.

The interactions of viroids with dye and oligonucleotide-ligands and with RNA-polymerase II from wheat germ, which enzyme replicates viroids in vitro, has been studied in order to correlate viroid structure and its ability for specific interactions. Specificity of the interactions may be interpreted on the basis of the neighbourhood of double stranded and single stranded regions. In the host cell viroids are localized in the cell nucleus; they may be detected as free nucleic acids and in high molecular weight complexes together with other RNA and proteins.     

Isolation and characterization of polyoma virus mutants which grow in murine embryonal carcinoma and trophoblast cells.

Mouse trophoblast cell lines established from cultured midterm placenta and a cell line obtained from cultured blastocyst resemble trophectoderm cells. These cells are resistant to infection by wild-type polyoma virus. We have isolated six polyoma virus mutants capable of growing in trophoblast cell lines. Restriction enzyme analyses and marker rescue experiments revealed that the genetic changes necessary for the growth of these mutants ( PyTr mutants) in trophoblast cells were located in a regulatory region of the genome between the origin of viral DNA replication and the region encoding the viral structural proteins. PyTr mutants are, therefore, similar to PyEC mutants, described by others, which are able to grow in embryonal carcinoma cell lines such as F9 or PCC4. The nucleotide sequence of two independently obtained PyTr mutants has an identical 26-bp deletion from nucleotide 5131 to 5156. This deleted region is replaced by either the sequence GGGA or by viral DNA sequences that flank this deletion. PyECF9 mutants grow well in trophoblast and trophectoderm cells, but PyTr mutants do not grow in F9 or PCC4 cells.     

Nature of Ribonuclease-resistant Nucleic Acid of Chick Embryo Cells transformed by Schmidt–Ruppin Strain of Rous Sarcoma Virus

THE mode of replication of RNA or RNA-containing tumour viruses is not understood. The recent studies on Rous sarcoma and other RNA-containing oncogenic viruses suggest that the replicative cycle of the RNA of these viruses might not be associated with ribonuclease-resistant structures (double stranded RNAs), but might involve the synthesis of a DNA intermediate specific to viral RNA^1–3. Two groups of workers, however, presented evidence for the presence of a double stranded RNA in 78 Al cell line of rat embryo fibroblasts which had been transformed and chronically infected with the murine sarcoma-leukaemia virus complex (MSV-MLV)^4,5 and it was suggested that the mode of replication of oncogenic viral RNAs was the same as that of non-oncogenic viral RNAs⁴. This apparent discrepancy prompted me to look for ribonuclease-resistant RNA structures in the chick embryo cells transformed by Schmidt-Ruppin Rous sarcoma virus (SR-RSV).     

HIV-1 integrase inhibition by modified oligonucleotides: optimization of the inhibitor structure

Integration of human immunodeficiency virus type 1 DNA into the infected cell genome is one of the key steps of the viral replication cycle. Therefore viral enzyme integrase, which realizes the integration, is of interest as a target for new antiviral drugs. Conjugates of 11-mer single stranded oligonucleotides with hydrophobic molecules are shown to be efficient integrase inhibitors since they induce dissociation of the integrase-viral DNA complex. The effect of the oligonucleotide length and structure as well as the structure of hydrophobic molecules on the conjugate inhibitory activity has been studied. Conjugates with eosin and oleic acid are shown to be the most active. Conjugates of these molecules with 2'-O-methyl-oligonucleotide inhibit integrase at 50-100 nM and have no influence on a number of other DNA-binding enzymes.     

Cell fusion induced by herpes simplex is inhibited by hen egg-white lysozyme

The formation of syncytia in cell monolayers infected with a macroplaque strain (MP) of herpes simplex virus was found to be inhibited by hen egg-white lysozyme. Inhibition was roughly proportional to the enzyme concentration. The virus titres in supernatant fluids of lysozyme-treated cultures were also reduced compared with untreated cultures. Control experiments excluded the possibility that lysozyme altered the virus viability and infectivity or impaired cell growth. Since lysozyme is a cationic protein, further experiments were performed in order to discover whether its antisyncytiogenic effect depended on its enzymatic activity or on its positive charge. Inhibition of the MP-induced polycaryocytosis was found to be caused by heat-inactivated lysozyme and three chemically-modified lysozymes with a higher positive charge (one retaining and two lacking enzymatic activity).     

Use of a recombinant retrovirus to study post-implantation cell lineage in mouse embryos.

We show that a gene introduced into cells of mouse embryos by a retrovirus can serve as a heritable marker for the study of cell lineage in vivo. We constructed a defective recombinant retrovirus in which the Escherichia coli beta-galactosidase (lacZ) gene is inserted in the genome of a Muloney murine leukemia virus (M-MuLV). Expression of lacZ was detected with a histochemical stain that can be applied to cultured cells and embryonic tissue. Infection of cultured cells showed that lacZ has no detectable deleterious effects on cell viability or growth, that the enzyme is stably expressed in the progeny of infected cells for many generations in the absence of selective pressure, and that the virus can induce lacZ in a variety of cell types. Following injection of the virus into mid-gestation mouse embryos, clones of lacZ-positive cells were detected in skin, skull, meninges, brain, visceral yolk sac, and amnion. We identified the cell types comprising a series of lacZ-positive clones in the visceral yolk sac and skin to learn the lineage relationships of the labelled cells. In each tissue, we obtained evidence that several cell types have a pluripotential ancestor and that cell fate is progressively restricted as development proceeds.     

Comparison at the molecular level of uracil-DNA glycosylases from different origins

A nuclear and a cytoplasmic uracil-DNA glycosylase have been purified from epithelial cells derived from a rat hepatoma (H4 cells) cultured in vitro. They have different optimum pH, molecular weight, isoelectric points, activation energy, Km. Uracil acts as a non competitive inhibitor towards the nuclear enzyme while it is a competitive one for the cytoplasmic enzyme. Comparison of the properties of the two mammalian enzymes with those of the enzymes isolated from Escherichia coli and Micrococcus luteus shows that they all behave differently. The following criteria were studied: molecular weight, optimum pH, isoelectric point, inhibition by uracil analogs, modulation of their activity by polyamines or by intercalating drugs. The only common properties shared by these four enzymes are: an activity twice as high on single stranded DNA than on double stranded DNA and no requirement for divalent cation for maximal activity.     

Identification and genetic mapping of a herpes simplex virus capsid protein that binds DNA

Herpes simplex virus virion protein 19C (VP19C) is a constituent of both unenveloped (nuclear) and enveloped (cytoplasmic) capsids. In this paper we report that 32P-labeled DNA, either supercoiled or linear double stranded, efficiently bound to VP19C electrically transferred from denaturing polyacrylamide gels containing electrophoretically separated proteins from purified capsids. Analyses of the polypeptides specified by herpes simplex virus type 1 X herpes simplex type 2 recombinants with respect to electrophoretic mobility and binding of 32P-labeled DNA indicate that VP19C maps at the same location as infected cell polypeptide 32 and is derived from it.     

Homogeneous real-time detection and quantification of nucleic acid amplification using restriction enzyme digestion

A method for real-time fluorescent detection and quantification of nucleic acid amplification using a restriction endonuclease was developed. In this homogeneous system detection is mediated by a primer containing a reporter and quencher moiety at its 5' terminus separated by a short section of DNA encoding a restriction enzyme recognition sequence. In the single stranded form, the signal from the fluorescent reporter is quenched due to fluorescence resonance energy transfer. However, as the primer becomes incorporated into a double stranded amplicon, a restriction enzyme present in the reaction cleaves the DNA linking the reporter and quencher, allowing unrestricted fluorescence of the reporter. To test this system, a primer specific for the E6 gene of human papilloma virus (HPV) 16 was combined with the cleavable energy transfer label and used to amplify HPV16 positive DNA. In the presence of the thermally stable restriction enzyme BstNI, the reporter system was found to generate a fluorescent signal in proportion to the amount of template DNA. In addition to this direct format, the reporter primer was also used to monitor and quantify the amplification of other sequences. This was accomplished by using primers that contain a tag sequence complementary to the reporter oligonucleotide.