The use of phosphorylated sugars to support protein synthesis with some mammalian cell extracts

Double-stranded RNA-dependent phosphorylation of protein P1 and eukaryotic initiation factor 2 alpha does not correlate with protein synthesis inhibition in a cell-free system from interferon-treated mouse L cells

The double-stranded RNAs (I)n X (C)n and (A)n X (dUfl)n (dUfl is 2'-fluoro-2'-deoxyuridylic acid) have been compared as inhibitors of translation in cell-free systems from interferon-treated mouse L cells and from rabbit reticulocytes. In the interferon-treated mouse L-cell system, both double-stranded RNAs stimulated kinase activity, leading to phosphorylation of protein P1 and eukaryotic initiation factor 2 alpha (eIF-2 alpha), but only (1)n X (C)n activated the (2'-5')-oligoadenylate synthetase. Moreover, in this system, (I)n X (C)n, but not (A)n X (dUfl)n, inhibited translation. Both (A)n X (dUfl)n and (I)n X (C)n also activated the rabbit reticulocyte kinase to phosphorylate protein P1 and eIF-2 alpha, but, in contrast to mouse L-cell systems, both (A)n X (dUfl)n and (I)n X (C)n were potent inhibitors of translation in reticulocyte lysates. These results indicate that protein P1 and eIF-2 alpha phosphorylation are not sufficient to cause inhibition of protein synthesis in interferon-treated mouse L-cell extracts. They further suggest that protein synthesis inhibition by (I)n X (C)n in extracts of interferon-treated L cells correlates better with activation of (2'-5')-oligoadenylate synthetase than with activation of the protein P1 and eIF-2 alpha kinase.

Interferon interactions with thyroid cells

Iodide uptake by functioning rat thyroid (FRTL) cells is increased by mouse interferon. The effect is detectable using purified interferon; it is not accompanied by an increase in intracellular cyclic AMP levels, is measurable within 20 min, and is prevented by cholera toxin, an agent which inhibits interferon's antiviral activity. The effect of interferon is biphasic with maximally increased iodide uptake (approximately 2-fold) evident at about 300 international mouse units per ml (U/ml) and lesser effects evident at higher concentrations (greater than 1000 U/ml). The effect of mouse interferon on iodide uptake is accompanied by an extremely sensitive antiviral response. Thus, significant antiviral protection is evident at 1 U/ml with FRTL cells, as opposed to 1000 U/ml for nonfunctioning rat thyroid (FRT) cells. Functioning FRTL thyroid cells are also more sensitive to mouse interferon (10-fold) with respect to 2',5'-polyadenylate (An) synthetase activity or to 125I-thyrotropin binding to membrane preparations than are nonfunctioning FRT cells. Antiviral protection in FRTL cells is evident as early as 1 h after exposure to mouse interferon, and is accompanied by a nearly 100-fold increase in the measurable titer of 2'5'-An synthetase activity. Actinomycin D blocks the antiviral effect of interferon, but not its effect on iodide uptake. The results are discussed with respect to the unusually sensitive response of heterologous (rat) cells to mouse interferon: a possible relationship between thyrotropin and interferon receptors; and, the difference in interferon sensitivity exhibited by differentiated (functioning) as opposed to undifferentiated (nonfunctioning) thyroid cells.

A mouse cell line, which is unprotected by interferon against lytic virus infection, lacks ribonuclease F activity

A mouse cell line, NIH 3T3, does not respond to some of the activities of interferon. Even after treatment with high concentrations of interferon the replication of lytic viruses, such as encephalomyocarditis virus (EMCV) and vesicular stomatitis virus (VSV) is not inhibited in these cells. In contrast, interferon treatment of these same cells results in the inhibition of Moloney murine leukemia virus (MMuLV) production. We have analyzed enzymatic pathways which are induced by interferon in these cells. After interferon treatment, the level of the (2'-5')oligoadenylate [(2'-5)An] synthetase activity and the phosphorylation of the 67000-dalton protein (P1) are enhanced in NIH 3T3 cells to approximately the same level as interferon-sensitive mouse L-cells. Moreover, NIH 3T3 and L-cells, contain approximately the same levels of enzymes which inactivate (2'-5')An. Both exogenously added (2'-5')A3 or double-stranded RNA (dsRNA) failed to inhibit protein synthesis in NIH 3T3 extracts even though they were potent inhibitors of L-cell extract-directed protein synthesis. Direct measurements of the (2'-5')An-dependent ribonuclease F (RNase F) failed to detect such activity in NIH 3T3 cells. Our results, therefore, suggest that the presence of RNase F activity is necessary for the interferon-induced antiviral activity against EMCV and against VSV. The induction of protein kinase activity by interferon treatment of NIH 3T3 cells appears to have no direct effect on EMCV and VSV replication.

Role of 2',5'-oligo(adenylic acid) polymerase in the degradation of ribonucleic acid linked to double-stranded ribonucleic acid by extracts of interferon-treated cells

RNA covalently linked to double-stranded RNA (dsRNA) is preferentially degraded in extracts of interferon-treated HeLa cells [Nilsen, T. W., & Baglioni, C. (1979) Proc. Natl. Acad. Sci. U.S.A. 76, 2600-2604]. The size of the dsRNA required for this preferential degradation has been determined by annealing poly(I) of known length to the poly(C) tract of encephalomyocarditis virus (EMCV) RNA or by annealing poly(U) to poly(A) of known length of vesicular stomatitis virus mRNA. The dsRNA must be longer than about 60 base pairs to observe the preferential degradation of RNA. Moreover, triple-stranded regions that do not activate synthesis of 2',5'-oligo(A) and ethidium bromide, which intercalates in dsRNA and blocks 2',5'-olido(A) polymerase activation, prevent this degradation. Ethidium also blocks the degradation of the replicative intermediate of EMCV by extracts of interferon-treated cells. These experiments indicate that synthesis of 2',5'-oligo(A) is required for the degradation of RNA linked to dsRNA. The 2',5'-oligo(A)-dependent endonuclease does not cleave single- or double-stranded DNA, nor does it cleave homopolyribonucleotides. The potential role of the 2',5'-oligo(A) polymerase/endonuclease system in the inhibition of viral RNA replication is discussed.

Induction of interferon in HeLa cells of a protein kinase activated by double-stranded RNA

Treatment of HeLa cells with human fibroblast interferon results in increased levels of latent protein kinase activity that can be activated by double-stranded RNA (dsRNA). The protein kinase activity in extracts of interferon-treated cells is assayed by two methods: (a) inhibition of protein synthesis in rabbit reticulocyte lysates and (b) phosphorylation of two polypeptides of Mr 72000 (P1) and 38000 (the eIF-2 alpha subunit of initiation factor 2). When extracts of interferon-treated cells are fractionated by centrifugation at 150000 x g, the protein kinase activity is found in the pellet fraction. The kinase is maximally activated by 0.1 micrograms/ml poly(I) . poly(C). An increase in protein kinase activity is detected after 8 h of treatment with 100 units interferon/ml or after a 17-h treatment with 12.5 units/ml or greater interferon concentrations. Therefore, the kinase activity increases as a function of both time of treatment and interferon concentration. Addition of actinomycin D to cells during interferon treatment prevents this increase. The protein kinase activity decreases gradually over three days when interferon-treated cells are subsequently grown in the absence of interferon.

Regulation of protein synthesis in mitotic HeLa cells

Mitotic HeLa cells (M cells) synthesize protein at about 25% of the rate of S phase cells. This decrease in protein synthesis is due to a reduction in the rate of initiation. However, extracts prepared from M cells are almost as active in protein synthesis as S cell extracts. Both cell extracts are quite active in in vitro initiation of protein synthesis. Moreover, two steps in initiation, binding of Met-tRNAf to 40S ribosomal subunits and binding of mRNA to ribosomes, show similar activity in both extracts. The difference in protein synthesizing activity observed in vivo is largely eliminated in the preparation of cell-free systems. The ribosomes of M cells contain small mol wt RNA, which inhibits protein synthesis in vitro. This RNA, which has possibly a nuclear origin, may be a cause of the reduction in the rate of protein synthesis in M cells.