Molecular Weight of Poliovirus Ribonucleic Acid

Purified poliovirus single- and double-stranded ribonucleic acids (RNA) were examined by electron microscopy. The length of both molecules was found to be 2.37 mum. The uncorrected sedimentation coefficient for single-stranded RNA is 33S, as compared to 27S for the RNA of tobacco mosaic virus. It is calculated from these results that the molecular weight of the sodium form of poliovirus is 2.6 x 10(6) daltons.     

Infectivity and Sedimentation of Rhinovirus Ribonucleic Acid

Ribonucleic acid extracted from the virions of two human rhinoviruses is infective and is similar in size to poliovirus ribonucleic acid.     

Differential Effect of Phleomycin on the Infectivity of Poliovirus and Poliovirus-Induced Ribonucleic Acids

The infectivity of intact poliovirus was not affected by exposure to the antibiotic phleomycin at concentrations as high as 200 mug/ml, whereas that of the singlestranded poliovirus ribonucleic acid (RNA) was inactivated to 99% by pretreatment of the RNA with phleomycin at a concentration of 2 mug/ml. The infectivity of double and multistranded RNA was 10 times less sensitive than that of singlestranded RNA to the action of this antibiotic. Preincubation of HeLa cells for 30 min with 10 to 50 mug of phleomycin reduced the sensitivity of the cells to infection by viral RNA and intact virus, indicating that phleomycin interferes with cellular functions necessary for virus replication. When phleomycin was added to cells at different times after infection with single- or double-stranded RNA, the highest inactivation of infective centers was observed immediately after infection. With time of incubation at 37 C, the infective centers became more resistant to the action of phleomycin.     

Studies of Laryngotracheitis Virus in Avian Tissue Cultures: III. Enhancement of Infectivity by Diethylaminoethyl-Dextran

Diethylaminoethyl-dextran (DEAE-D) enhanced the infectivity of laryngotracheitis virus (LTV) for chicken kidney (CK) cells when cultures were treated before inoculation with virus and when DEAE-D was present in the inoculum. Infectivity was not increased when cultures were treated after virus had adsorbed to cells; since infection was not synchronized, most of the virus had probably already penetrated the plasma membrane by the time DEAE-D was added. Maximal enhancement occurred when DEAE-D was present in the inoculum. Enhancement of a lesser degree occurred when virus and DEAE-D were mixed, diluted, and inoculated onto cultures. Adsorption of LTV at 37 C as compared to that at 5 C usually yields about a threefold greater number of plaques after a 2-hr adsorption period. However, when DEAE-D was incorporated in the inoculum, greater enhancement occurred at 5 C than at 37 C, and the number of plaques produced at both adsorption temperatures was about equal. Results are compatible with the hypothesis that increased adsorption is a factor in enhancement of infectivity of LTV by DEAE-D.     

Isolation and Properties of Poliovirus Minus Strand Ribonucleic Acid

Poliovirus minus strands were purified from double-stranded polio ribonucleic acid. The minus strands have a base ratio complementary to that of the viral ribonucleic acid and are not infectious.     

In Vitro Synthesis of Poliovirus Ribonucleic Acid: Role of the Replicative Intermediate

Poliovirus ribonucleic acid (RNA) polymerase crude extracts could be stored frozen in liquid nitrogen without loss of activity or specificity. The major in vitro product of these extracts was viral single-stranded RNA. However, after short periods of incubation with radioactive nucleoside triphosphates, most of the incorporated label was found in replicative intermediate. When excess unlabeled nucleoside triphosphate was added, the label was displaced from the replicative intermediate and accumulated as viral RNA. It is concluded from this experiment that the replicative intermediate is the precursor to viral RNA. In addition, some of the label was chased into double-stranded RNA. The implications of this finding are discussed.     

Characterization of an Infectivity Assay for the Ribonucleic Acid of Bacteriophage MS2

An infectivity assay for MS2 ribonucleic acid (RNA), which uses bacterial spheroplasts of an F(-) strain of Escherichia coli, has an efficiency of 10(-5) infected spheroplasts per RNA molecule. The characteristics of this assay and the influence of several parameters are presented. Important variables include the duration of exposure of the cells to lysozyme-ethylenediaminetetraacetic acid, the duration of exposure of the spheroplast stock to the RNA solutions before dilution, the concentration of RNA, and the presence of competing RNA. The growth kinetics of the virus in the infected spheroplasts and the extent of lysis have also been studied.     

Influence of Polycations on the Interaction Between Poliovirus Multistranded Ribonucleic Acid and HeLa Cells

In contrast to single-stranded viral ribonucleic acid (RNA), poliovirus multistranded RNA (RI-RNA) is poorly adsorbed to suspended HeLa cells in the absence of polycations. In the presence of 20 mug of diethylaminoethyl (DEAE) dextran per ml and other polycations, 90% or more of the RI-RNA is adsorbed to HeLa cells within 2 min at 37 C. However, only 30% of the RI-RNA label penetrates into the cells independent of the concentration of DEAE dextran applied. DEAE dextran is adsorbed almost quantitatively to HeLa cells within 3 min at 37 C. Most of the DEAE dextran remains bound to the cell membrane and available for binding of RI-RNA for 15 min at 37 C.     

Synthesis of Ribonucleic Acid in Cells Infected with LSc Poliovirus at Elevated Temperatures

The synthesis of viral ribonucleic acid (RNA) was detected within 2 hr after infection with LSc poliovirus at 35 C. This RNA eluted as a single peak with 0.9 m NaCl on methylated albumin celite columns, was sensitive to ribonuclease, precipitated in the presence of 2 m LiCl, and had an S(20) value at 34 +/- 2 in linear sucrose gradients. When cells were infected at 39 to 40 C, there was also early synthesis of RNA. However, 2 hr after infection this synthesis was drastically inhibited. The absence of net RNA synthesis at 39 to 40 C during the late stages of infection was not caused by rapid degradation of newly formed RNA, since the RNA produced between 1 and 2 hr at 39 to 40 C was still present 3.5 hr after infection. There was a 3 log(10) inhibition in the production of infectious virus when p-fluorophenylalanine was present in the medium at a concentration of 25 mug/ml. This concentration of analogue had little effect upon the production of viral polymerase and viral RNA. Virus grown in the presence of analogue at a concentration of 10 mug/ml exhibited increased heat sensitivity compared to control virus. However, viral polymerase exhibited no change in sensitivity to heat or manganese when cells were exposed to 25 mug of p-fluorophenylalanine per ml during infection. p-Fluorophenylalanine had a relatively selective effect on viral capsid protein but did not reverse the inhibition of synthesis of viral RNA at 39 to 40 C.     

Infectivity of RNA from Inactivated Poliovirus

During inactivation of poliovirus type 1 (PV-1) by exposure to UV, hypochlorite, and heat (72°C), the infectivity of the virus was compared with that of its RNA. DEAE-dextran (1-mg/ml concentration in Dulbecco's modified Eagle medium buffered with 0.05 M Tris, pH 7.4) was used to facilitate transfecting PV-1 RNA into FRhK-4 host cells. After interaction of PV-1 RNA with cell monolayer at room temperature (21 to 22°C) for 20 min, the monolayers were washed with 5 ml of Hanks balanced salt solution. The remainder of the procedure was the same as that for the conventional plaque technique, which was also used for quantifying the PV-1 whole-particle infectivity. Plaque formation by extracted RNA was approximately 100,000-fold less efficient than that by whole virions. The slopes of best-fit regression lines of inactivation curves for virion infectivity and RNA infectivity were compared to determine the target of inactivation. For UV and hypochlorite inactivation the slopes of inactivation curves of virion infectivity and RNA infectivity were not statistically different. However, the difference of slopes of inactivation curves of virion infectivity and RNA infectivity was statistically significant for thermal inactivation. The results of these experiments indicate that viral RNA is a primary target of UV and hypochlorite inactivations but that the sole target of thermal inactivation is the viral capsid.     

Factors Influencing the Infectivity of a Trypanosoma brucei Stabilate for Mice

SYNOPSIS. Mice, segregated in groups according to sex and age from 5 to 21 weeks, and randomly presented, were inoculated in one continuous process with a trypanosome suspension prepared from a Trypanosoma brucei subgroup stabilate of such a dilution that about 50% of the mice might be expected to become infected. No statistically significant difference occurred between groups, either with regard to sex or to age.
Significant alterations in the proportions of mice infected did, however, occur in relation to inoculation order. The inoculation process occupied 12–197 minutes after removal of the stabilate from −79 C storage. Essentially, infectivity rose initially to a peak between 30 and 80 minutes, and then fell off, but was not abolished at the end of the experiment.     

Ribonucleic Acid Dependent Ribonucleic Acid Replicase in the Immune Response

An immune ribonucleic acid (iRNA) preparation was made using phenol extracts of spleens of mice previously immunized with Salmonella tennessee flagella. An enzyme, also prepared from the spleens of these mice, induced the incorporation of ³H-UTP into the acid-insoluble fraction in a cell-free system in the presence of this RNA. The enzyme activity could be demonstrated from the spleens of immunized mice but not from normal ones, and this activity was also inhibited by two derivatives of rifamycin. Treatment with ribonuclease or heating at alkaline pH resulted in a loss of activity in added RNA. The ³H-uridine-labeled product was found resistant to ribonuclease treatment but became sensitive when the product was subjected to heat treatment. However, actinomycin D, mitomycin C or bleomycin A₂ did not inactivate the enzyme activity. These results suggest that this enzyme induces the incorporation of UTP into the acid-insoluble fraction using iRNA as a template and the product may be a newly synthesized RNA which forms a hybrid with iRNA. This enzyme activity may play a role in the antibody formation process, and may account for the in vivo replication of iRNA by this enzyme, viz., probably an RNA-dependent RNA replicase.     

Ribonucleic Acid Polymerase Catalyzing Synthesis of Double-stranded Arbovirus Ribonucleic Acid

The large-particle fraction from the cytoplasm of chick embryo fibroblasts infected with Semliki Forest virus was found to catalyze the incorporation of the 5'-triphosphates of guanosine, adenine, cytidine, and uridine into an acid-insoluble alkali-labile product. The conditions affecting the preparation and assay of this enzyme were investigated. The ribonucleic acid (RNA) polymerase was not present in uninfected cells, and it appeared in infected cells at the time of rapid viral RNA synthesis. The polymerase was found to catalyze the synthesis of a species of RNA which was resistant to ribonuclease and which exhibited the sedimentation properties, buoyant density, and thermal transition temperature of the double-stranded RNA found in vivo in chick cells infected with Semliki forest virus. Attempts to demonstrate that the reaction product of this enzyme also included single-stranded viral RNA were not successful. Although other interpretations are possible, these results give some support to the suggestion that more than one enzyme may be involved in the replication of viral RNA.     

Enhancement of Agrobacterium tumefaciens Infectivity by Mitomycin C

The ability of Agrobacterium tumefaciens to induce pinto leaf tumors may be enhanced two- to threefold after treatment with mitomycin C. The enhancement may be obtained with either lethal or nonlethal concentrations. With 10-min treatments, an optimal response was obtained with 0.005 mug of mitomycin C per ml in the absence of any change in the number of viable cells. Both the tumor induction process and the tumors induced by treated cultures appear qualitatively the same as controls. To account for these results, the antibiotic must increase the proportion of viable cells that will subsequently initiate tumors. One, or at most a few, random lesions in the bacterial chromosome seem to be the necessary requirement for this promotion. At mitomycin concentrations of 1 and 5 mug/ml, the ability of A. tumefaciens to initiate tumors is rapidly lost, indicating that a fairly intact bacterial chromosome is one of the essentials for the tumor induction process.     

Ribonucleic Acid-Dependent Ribonucleic Acid Polymerase in the Immune Response

Ribonucleic acid (RNA)-dependent RNA polymerase activity was demonstrated in the microsomal and ribosomal fraction from the spleen cells of immunized mice. The enzyme activity was solubilized by Triton X-100 from the fraction and partially purified by Biogel A 1.5 M column chromatography. The RNA-dependent RNA polymerase activity was eluted in a single peak from the column. High activity was demonstrated with an RNA preparation (iRNA) as template made from the spleens of immunized mice but very low activity was found with an nRNA preparation made from the spleens of normal mice. Incorporation of ³H-UTP markedly decreased in the presence of RNase but not in the presence of DNase. DNA preparations made from the spleens of immunized mice were inactive as template for this enzyme. The iRNA preparation was fractionated by sucrose density gradient centrifugation. A fraction corresponding to 12–13 S was most active as a template. It was followed by a fraction corresponding to 6–7 S. Sucrose gradient analysis of the ³H-UTP-labeled product was attempted. Some properties of this enzyme are described.     

Some Factors Influencing the in vitro Infectivity and Replication of Encephalitozoon cuniculi*

SYNOPSIS. Rabbit Encephalitozoon cuniculi were propagated in vitro using rabbit choroid plexus (RCP) cells. The organisms reached maximum titer and numbers by 15 days. The source and in vitro passage level of RCP cells moderately influenced the sensitivity of the cells to infection. Cells less than 1 week old were significantly less sensitive than older cells. A moderate increase in infectivity for RCP cells was demonstrated with increasing organism passage level in vitro. Rabbit E. cuniculi were not affected by penicillin-streptomycin or gentamicin in the culture medium. The organism survived more than 9 days in buffer at 37 C and least 24 days at 4 and 20 C. Storage at -70 C or in liquid nitrogen was successful for at least 6 months. Encephalitozoon cuniculi survived 60 but not 120 min at 56 C. They were killed after 10 min of autoclaving and by 2% (v/v) Lysol, 10% (v/v) formalin and 70% (v/v) ethyl alcohol. The organisms survived at least 24 h at pH 9 or pH 4 and were not affected by sonication, freezing and thawing, or distilled water but lost significant infectivity after 24 h in CsCl or 40% (w/v) sucrose.     

Interaction of Poliovirus with Its Receptor Affords a High Level of Infectivity to the Virion in Poliovirus Infections Mediated by the Fc Receptor

Poliovirus infects susceptible cells through the poliovirus receptor (PVR), which functions to bind virus and to change its conformation. These two activities are thought to be necessary for efficient poliovirus infection. How binding and conformation conversion activities contribute to the establishment of poliovirus infection was investigated. Mouse L cells expressing mouse high-affinity Fcγ receptor molecules were established and used to study poliovirus infection mediated by mouse antipoliovirus monoclonal antibodies (MAbs) (immunoglobulin G2a [IgG2a] subtypes) or PVR-IgG2a, a chimeric molecule consisting of the extracellular moiety of PVR and the hinge and Fc portion of mouse IgG2a. The antibodies and PVR-IgG2a showed the same degree of affinity for poliovirus, but the infectivities mediated by these molecules were different. Among the molecules tested, PVR-IgG2a mediated the infection most efficiently, showing 50- to 100-fold-higher efficiency than that attained with the different MAbs. A conformational change of poliovirus was induced only by PVR-IgG2a. These results strongly suggested that some specific interaction(s) between poliovirus and the PVR is required for high-level infectivity of poliovirus in this system.     

Virus Interference by Cellular Double-Stranded Ribonucleic Acid

Ribonuclease-resistant ribonucleic acid (RNA) was isolated from uridine-labeled cultures of rabbit kidney, chicken embryo, and HeLa cells. This RNA, regardless of its source, was found to induce interference with virus growth in either rabbit kidney or chicken embryo cultures. Nuclease-treated cellular nucleic acids exhibited interference-inducing activity which eluted with a small fraction of RNA in the exclusion volume of a 6% agarose gel column. Besides resistance to ribonucleases, the interference inducer and RNA isolated from partially digested nucleic acids have in common two properties of double-stranded RNA: (i) similar sharp melting profiles were obtained for inducer and ribonuclease-resistant RNA, with T(m) dependent on NaCl concentration; (ii) ribonuclease-resistant inducer and RNA banded together in Cs(2)SO(4) density gradients at a density characteristic of known double-stranded RNA. After melting at low ionic strength, the labeled RNA shifted to a higher density and its capacity to inhibit virus replication was lost. Velocity sedimentation analysis of the cellular ribonuclease-resistant RNA indicated that the majority sedimented between 7 and 11S, but only RNA sedimenting at >==8 to 20S had a high specific activity of interference induction. Without prior ribonuclease treatment, the ribonuclease-resistant RNA can be precipitated with 2 m LiCl and thus appears to exist in purified cellular nucleic acids as part of molecular complexes with both single- and double-stranded regions of RNA. The biosynthesis of cellular double-stranded RNA is inhibited by actinomycin D.