Intercellular information transfer in the process of immunogenesis. IX. The induction of the synthesis of antiphage antibodies in lymphosarcoma cells of rats as affected by different fractions of immune nuclear RNA

Various fractions of the immune nuclear RNA were isolated from spleens of phage T2 immunized rats. The fractions were compared for their ability to induce anti-phage T2 antibody synthesis in transplantable lymphosarcoma cells. The most active proved to be the nuclear sap RNA and its subfraction with sedimentation constant of 10 S. The 4S and 26S subfractions RNA were less stable and in some experiments failed to induce antibody synthesis.     

Intercellular information transfer in the immunogenesis process. VIII. Analytical separation on agar and polyacrylamide gel of RNA fractions from the spleens of immunized and intact rats

RNA isolated from the spleens of intact rats and from rats with immunized sheep red cells was fractionated through three steps: 1 - extraction from phenol nuclei at 50-55 degrees and 65-75 degrees C, 2 - calcium-phosphate chromatography, 3 - agar electrophoresis. Eight agar fractions were obtained of the spleens of immunized rats, an increased RNA content was manifested in at least three agar fractions: the first (4 S), the third (21 S) and the eighth (26 S) ones. The first and the eighth immune RNA fractions, as it was shown earlier, induce the synthesis of antibodies in the rat transplantable lymphosarcoma cell. The first agar fraction of nuclear RNA from the spleens of immunized and intact rats were additionally separated using PAAG electrophoresis. The 4 S agar RNA fraction appears to be rather heterogeneous. It contains 4 S, 4.5 S, 5 S, 5.8 S, U1, U2 and 8 SII fractions, which are low-molecular nuclear RNAs, the 4 S subfraction prevailing. It is suggested that the 4 S PAAG subfraction is most active in the synthesis of antibodies induced by the heterogeneous agar 4 S RNA.     

Synthesis of Saint Louis Encephalitis Virus Ribonucleic Acid in BHK-21/13 Cells

Infection of baby hamster kidney cells (BHK-21/13) with Saint Louis encephalitis (SLE) virus depressed the rate of protein and ribonucleic acid (RNA) synthesis until viral RNA synthesis began 6 hr postinfection (PI). Virus-directed RNA synthesis was subsequently inhibited until 12 hr PI when virion maturation began. The rate of protein synthesis reached a peak 6 hr PI and was subsequently depressed until just before the onset of virion maturation. Density gradient analysis of phenol-extracted RNA from actinomycin-treated infected cells indicated that, at 6 to 8 hr and again at 12 to 20 hr PI, three species of viral-specific RNA were synthesized. The most rapid sedimenting form (43S) was ribonuclease-sensitive and had a base composition similar to the RNA isolated from mature virions. The 20S RNA species was ribonuclease-resistant and had a sedimentation coefficient and base composition similar to the replicative form associated with other arbovirus infections. The 26S RNA was ribonuclease-resistant (0.2 mug/ml, 0.1 m NaCl, 25 C, 30 min) and had a nucleotide base composition closer to the 20S form than to the values for 43S RNA. Five-minute pulse labeling of infected cultures during the period viral RNA synthesis was maximal resulted in labeling of only the 20S to 22S RNA fractions. With pulse-labeling periods of 10 min, both the 20S and 26S RNA species were radioactive. Periods of radioactive labeling of as long as 15 min were required before the 43S form was radioactively labeled. These results suggest that the 20S and 26S RNA may be intermediate forms in the synthesis of 43S viral RNA.     

Cytoplasmic Fractions Associated with Semliki Forest Virus Ribonucleic Acid Replication

When actinomycin D-treated chick fibroblasts were labeled with (3)H-uridine for varying periods during the log phase of Semliki Forest virus infection, radioactivity was found associated with different cytoplasmic fractions. After a 1-min period of labeling, it appeared in a large cytoplasmic structure which was seen in electron micrographs of infected cells. Sediments of sucrose density gradients of cytoplasmic extracts of these cells also contained these structures. Three forms of viral ribonucleic acid (RNA) were associated with this cytoplasmic structure: a ribonuclease-sensitive 42S form identical to the RNA of the mature virus, a ribonuclease-sensitive 26S form, and a ribonuclease-resistant 20S form. After a 5- to 10-min labeling period, radioactivity was associated with a ribonuclease-sensitive 65S cytoplasmic fraction which contained only the 26S RNA form. Finally, after a 1-hr labeling period, a 140S ribonuclease-resistant particle was the most prominent radioactive structure in the cytoplasm. This particle contained only 42S viral RNA. Negative-contrast electron micrographs of the 140S particle and the virion demonstrated structural differences between them. The base compositions of the 42S and 26S viral RNA forms were not significantly different. The base composition of the 20S form differed significantly from that of the other two viral RNA forms, but the values obtained for the mole fractions of the bases present in the 20S form differed, and depended on the period during the virus growth cycle in which (32)P was present. These results suggested that viral RNA originated in the large cytoplasmic body. The 20S RNA appeared to be a structure engaged in viral RNA replication and the 140S particle appeared to be a virus precursor.     

Functional defects of RNA-negative temperature-sensitive mutants of Sindbis and Semliki Forest viruses.

Defects in RNA and protein synthesis of seven Sindbis virus and seven Semliki Forest virus RNA-negative, temperature-sensitive mutants were studied after shift to the restrictive temperature (39 degrees C) in the middle of the growth cycle. Only one of the mutants, Ts-6 of Sindbis virus, a representative of complementation group F, was clearly unable to continue RNA synthesis at 39 degrees C, apparently due to temperature-sensitive polymerase. The defect was reversible and affected the synthesis of both 42S and 26S RNA equally, suggesting that the same polymerase component(s) is required for the synthesis of both RNA species. One of the three Sindbis virus mutants of complementation group A, Ts-4, and one RNA +/- mutant of Semliki Forest virus, ts-10, showed a polymerase defect even at the permissive temperature. Seven of the 14 RNA-negative mutants showed a preferential reduction in 26S RNA synthesis. The 26S RNA-defective mutants of Sindbis virus were from two different complementation groups, A and G, indicating that functions of two viral nonstructural proteins ("A" and "G") are required in the regulation of the synthesis of 26S RNA. Since the synthesis of 42S RNA continued, these functions of proteins A and G are not needed for the polymerization of RNA late in infection. The RNA-negative phenotype of 26S RNA-deficient mutants implies that proteins regulating the synthesis of this subgenomic RNA must have another function vital for RNA synthesis early in infection or in the assembly of functional polymerase. Several of the mutants having a specific defect in the synthesis of 26S RNA showed an accumulation of a large nonstructural precursor protein with a molecular weight of about 200,000. One even larger protein was demonstrated in both Semliki Forest virus- and Sindbis virus-infected cells which probably represents the entire nonstructural polyprotein.     

In Vitro Replication of Cowpea Mosaic Virus RNA I. Isolation and Properties of the Membrane-Bound Replicase

A fraction which contained the membrane-bound cowpea mosaic virus RNA replicase was isolated from cowpea mosaic virus-infected cowpea leaves. The replicase activity appeared on day 1 after inoculation, then increased to reach a maximal on day 4. The increase in enzyme activity preceded the most-rapid virus multiplication. The membrane-bound replicase activity was almost completely insensitive to actinomycin D and DNase. The corresponding fraction from healthy leaves had no RNA-dependent RNA polymerase activity. The viral RNA synthesis in vitro proceeded linearly for 20 min and required all four ribonucleoside triphosphates and Mg(2+) ions. Mn(2+) was a poor substitute for Mg(2+). The reaction was optimal at pH 8.2. During the whole period of RNA synthesis the in vitro synthesized RNA was at least 70% resistant against RNase in 2 x SSC (0.15 M NaCl plus 0.015 M sodium citrate), but completely digestable by RNase in 0.1 x SSC. Analysis of the products by sucrose gradient centrifugation followed by treatment of separate fractions with RNase demonstrated that both single-and double-stranded RNA were present. Double-stranded RNA sedimented at about 20S, with a shoulder at 16S to 17S. A minor part of the double-stranded RNA sedimented below 10S. Single-stranded RNA sedimented with the same rate as the two viral RNAs, 26S and 34S.     

In vitro synthesis of RNA by Xenopus spermatogenic cells I. Evidence for polyadenylated and non-polyadenylated RNA synthesis in different cell populations.

Premeiotic and postmeiotic (haploid) gene expression during spermatogenesis in the anuran, Xenopus laevis, was studied by analyzing the accumulation of radioactively labelled cytoplasmic polyadenylated [poly (A +)] and non-polyadenylated [poly (A -)] RNAs. Dissociated spermatogenic cells were labelled and maintained in an in vitro system capable of supporting cell differentiation. Labelled cells were separated by density gradient centrifugation into subpopulations enriched for individual spermatogenic stages. RNA was extracted and purified from each cell fraction, and separated into poly (A +) and poly (A -) species. Comparison of poly (A +) to non-poly (A) radioactivity in cells labelled with tritiated uridine or adenosine demonstrated that (1) all cell fractions produced significant quantities of polyadenylated RNA relative to total RNA synthesis; and (2) that a cell fraction enriched for pachytene spermatocyte RNA contained up to 15% of total cytoplasmic and 35% of total polysomal RNA labelled as poly (A +) containing species. RNA was also characterized by sucrose density gradient centrifugation and polyacrylamide gel electrophoresis. All cell types showed typical poly (A -) peaks of 4S, 18S and 28S, corresponding to tRNA (4S) and rRNAs (18, 28S) respectively. Spermatids and spermatozoa had additional absorbance peaks at 13 and 21S which cosedimented with Xenopus oocyte mitochondrial rRNA. Patterns of incorporation of uridine and adenosine into poly (A +) RNA in all germ cell fractions tested were complex. In all cases, major areas of radioactivity were found in a broad band sedimenting between 6-17S. Spermatid fractions showed a prominent peak of incorporation at 6-8S, while pachytene cells also showed heavier poly (A +) peaks in the 17-25S region. A non-polyadenylated RNA species sedimenting at 6-8S with a relatively rapid rate of turnover was also observed in spermatids. From these results it is concluded that synthesis of transfer, ribosomal, and putative messenger RNA species continues in spermatogenic cells throughout all but the very last stages of spermatogenesis in Xenopus.     

Decreased RNA, and Increased RNA Oxidation, in Ribosomes from Early Alzheimer’s Disease

All cells rely on efficient protein synthesis in order to maintain cellular homeostasis. Recent studies from our laboratory indicate that declines in protein synthesis and ribosome function occur in the earliest stage of Alzheimer’s disease (AD). Additional studies indicate a potential role for ribosomal RNA oxidation as a potential mediator of decreased protein synthesis in AD. The ribosome is a complex of proteins and nucleic acids that mediates all protein synthesis. At present it is unclear if significant alterations in ribosomal RNA occurs within the ribosome complex during the progression of AD. In this study we examined the amount of ribosomal RNA in the different ribosomal fractions generated from control subjects, individuals with mild cognitive impairment (MCI), and individuals with AD. Studies were conducted in the inferior parietal lobule of each subject. Together, these data demonstrate that during the progression of AD there is a gross decline in the amount of ribosomal RNA within the ribosome complex. Additionally, these studies provide evidence for gross elevations in RNA oxidation within the ribosome complex of MCI and AD. Together, these data strongly suggest a role for RNA alterations within the ribosome as a mediator of decreased protein synthesis in both MCI and AD.     

Ribonucleic Acid Synthesis in Cells Infected with Herpes Simplex Virus: I. Patterns of Ribonucleic Acid Synthesis in Productively Infected Cells

HEp-2 cells were pulse-labeled at different times after infection with herpes simplex virus, and nuclear ribonucleic acid (RNA) and cytoplasmic RNA were examined. The data showed the following: (i) Analysis by acrylamide gel electrophoresis of cytoplasmic RNA of cells infected at high multiplicities [80 to 200 plaque-forming units (PFU)/cell] revealed that ribosomal RNA (rRNA) synthesis falls to less than 10% of control (uninfected cell) values by 5 hr after infection. The synthesis of 4S RNA also declined but not as rapidly, and at its lowest level it was still 20% of control values. At lower multiplicities (20 PFU), the rate of inhibition was slower than at high multiplicities. However, at all multiplicities the rates of inhibition of 18S and 28S rRNA remained identical and higher than that of 4S RNA. (ii) Analysis of nuclear RNA of cells infected at high multiplicities by sucrose density gradient centrifugation showed that the synthesis and methylation of 45S rRNA precursor continued at a reduced but significant rate (ca. 30% of control values) at times after infection when no radioactive uridine was incorporated or could be chased into 28S and 18S rRNA. This indicates that the inhibition of rRNA synthesis after herpesvirus infection is a result of two processes: a decrease in the rate of synthesis of 45S RNA and a decrease in the rate of processing of that 45S RNA that is synthesized. (iii) Hybridization of nuclear and cytoplasmic RNA of infected cells with herpesvirus DNA revealed that a significant proportion of the total viral RNA in the nucleus has a sedimentation coefficient of 50S or greater. The sedimentation coefficient of virus-specific RNA associated with cytoplasmic polyribosomes is smaller with a maximum at 16S to 20S, but there is some rapidly sedimenting RNA (> 28S) here too. (iv) Finally, there was leakage of low-molecular weight (4S) RNA from infected cells, the leakage being approximately three-fold that of uninfected cells by approximately 5 hr after infection.     

Characterization of ribonucleic acids from the venom glands of Crotalus durissus terrificus (Ophidia, Reptilia) after manual extraction of the venom. Studies on template activity and base composition

RNA synthesis in the venom glands of Crotalus durissus terrificus was stimulated by the manual extraction of the venom (milking). RNA was extracted from venom glands activated by milking and fractionated by centrifugation through sucrose density gradients. Template activity for protein synthesis and base composition of the RNA fractions were studied. RNA fractions that sediment between 18S and 4S had the highest template activity. The base composition analysis indicated that the 28S and 18S rRNA have a C+G content of 65.4 and 58% respectively. The ;melting' temperature (T(m)) of DNA in 0.15m-NaCl-0.015m-trisodium citrate, pH7.0, was 85 degrees C, corresponding to a C+G content of 38%. The base ratio of the RNA fractions that showed a high template activity was intermediate between that of rRNA and homologous DNA. The possible role of these fractions in the synthesis of the two main toxins (crotoxin and crotamine) of the South American rattlesnake's venom is discussed.     

Initiation sites for translation of sindbis virus 42S and 26S messenger RNAs.

Sindbis virus 26S RNA is the principal species of virus-specific RNA found in the infected cell; it is derived from a one third segment of virion 42S RNA. When translated in cell-free extracts from mouse ascites cells or rabbit reticulocytes, 26S RNA directed the synthesis primarily of the 33,000 dalton virus capsid protein, and the protein products were in the form of free peptides rather than peptidyl-tRNA. In contrast, the polypeptides synthesized in either extract in response to Sindbis virus 42S RNA were heterogeneous, ranging in molecular weight from 33,000 to 190,000, and were largely in the form of peptidyl-tRNA. The number of independent initiation sites on the 26S and 42S RNAs was determined by analyzing a tryptic digest of reaction products labeled with yeast N-formyl-35S-methionyl-tRNAFmet. The 26S RNA appeared to contain a single initiation site, and this site could also be found in varying amounts in different preparations of 42S RNA. However, a second initiation site, distinct from that of 26S RNA, was the major site in 42S virion RNA. These results suggest that 42S virion RNA contains two potential sites for initiation of protein synthesis. Only one of these may be active, however, and it is postulated that the second site functions primarily, if not exclusively, in the subgenomic 26S RNA species. In this regard, Sindbis virus 42S RNA may represent a novel form of a eucaryotic messenger RNA.     

In vitro DNA and RNA synthesis by human platelets.

In vitro incorporation of [Me-3H] thymidine and [5-3H] uridine into human platelets was demonstrated. Thymidine incorporation was inhibited by three specific inhibitors of DNA synthesis: hydroxyurea, cytosine arabinoside and daunomycin. The effect was dose-dependent. Uridine uptake by platelets was found to be inhibited by specific inhibitors of RNA synthesis such as actinomycin D, rifampicin and vincristine, the effect of actinomycin D being dose dependent. The drug also led to a time-dependent inhibition of protein synthesis when preincubated with platelets. The platelet RNA profile on polyacrylamide gel was demonstrated to be similar to that of embryonic mouse erythroblast RNA. Synthesis of all three fractions, 28 S, 18 S and 4 S, was inhibited by actinomycin D. These findings show that human platelets are capable of DNA and RNA synthesis, and that these activities play a role in controlling protein synthesis in these cells. Detectable amounts of DNA have been found in whole human platelets, and in isolated mitochondria derived from these cells. Isolated platelet mitochondria incorporated [3H] thymidine and [3H] uridine into their macromolecules. These activities were inhibited by daunomycin and by both rifampicin and actinomycin D, respectively. These results support the assumption that DNA and RNA synthesis found in intact cell preparations takes place most probably in platelet mitochondria.     

Viral Ribonucleic Acid Synthesis by Newcastle Disease Virus Mutants Isolated from Persistently Infected L Cells: Effect of Interferon

The synthesis of different viral ribonucleic acid (RNA) species was studied in chick embryo (CE) and mouse L-cell cultures infected with the Herts strain of Newcastle disease virus (NDV(o)) and a mutant isolated from persistently infected L cells (NDV(pi)). In CE cell cultures, both viruses synthesized significant amounts of 54, 36, and 18S RNA. However, in L cells, synthesis of 54S virion RNA was markedly reduced. From these results, it seems likely that the low yield of infective virus in L cells is due to a deficient synthesis of 54S RNA in this host. On this basis, however, it is apparent that the "covert" replication of NDV(o) in L cells is due to factors other than viral RNA synthesis. When low concentrations of interferon were used to pretreat CE cells, a differential effect on the synthesis of various RNA species was observed. The 18S RNA of NDV(o) was more sensitive to interferon action than the 36 and the 54S RNA species. In contrast, the 18S RNA of NDV(pi) was less sensitive than the 36S and the 54S RNA. The inhibition of 54S RNA synthesis correlated with the reduction of viral yield and explained the greater sensitivity of NDV(pi) to interferon.     

Evidence for the presence of mRNA in the post-ribosomal cytoplasm of sheep lymphocytes.

Several fractions of RNA prepared from the post-ribosomal cytosol of sheep lymphoid cells were found to include messenger-like RNA as defined by the following criteria: a, template activity, i.e. the ability to promote the incorporation of radioactive amino acids into protein in cell-free protein-synthesising systems derived from wheat embryos or ascites tumour cells; b, a low magnesium optimum (1-2.5 mM) for template activity which is characteristic of many natural mRNAs; c, sensitivity of the template response to aurintricarboxylic acid, a specific inhibitor of the initiation of protein synthesis. The lymphoid post-ribosomal RNA fractions, however, were translated less efficiently than were rabbit reticulocyte globin mRNA or tobacco mosaic viral (TMV) RNA; no explanation for this relatively poor template activity was found. The major fraction of messenger-like RNA had an average sedimentation coefficient of 12 S; this fraction directed the translation of several discrete polypeptides in the molecular weight range 10 000-25 000. On average the products of 12 S RNA-directed protein synthesis appeared lysine rich compared with TMV RNA-directed products. It is suggested that the apparent pool of uncommitted mRNA in resting lymphocytes may be utilised during the early stages of lymphocyte activation, and that the mRNAs could be stored in forms similar to those evident in other dormant tissues.     

Intercellular information transfer in the process of immunogenesis. VI. The induction of antiphage antibody synthesis in the cells of rat transplantable lymphosarcoma under the influence of splenic RNA from rats and mice immunized with phage T2]

It has been proved that nuclear and cytoplasmic RNAs, isolated from spleens of T2 phage immunized rats and mice, can induce T2 phage antibodies in cells of the transplantable rat lymphosarcoma. With the nuclear RNA from rat spleens, the effect is persisting in a number of subsequent cell generations. The data presented are principally in accord with results of the authors' previous studies in which lymphosarcoma cells were treated with RNA extracted from spleens of rat immunized with sheep red cells. These results well compare with the authors' earlier advanced hypothesis suggesting a possible involvement of RNA in deblockation of genes responsible for the synthesis of the antibodies in question.