New inducers revealed by the promoter sequence analysis of two interferon-activated human genes

In order to investigate the molecular basis of the regulation of interferon-inducible genes, we isolated the promoter region of two such genes coding for the (2'-5')oligo(adenylate) synthetase and a 56-kDa protein (IFI-56K). The regions surrounding the cap site were sequenced and compared with the sequences of vertebrate and viral DNA present in the Genbank data bank. Small DNA segments were found in both genes which are homologous to part of the promoter region of other genes, such as those of interferon-beta, tumor necrosis factor beta, interleukin-2 and its receptor. Since these homologies were found located in functionally important regions of these genes, we tested whether their inducers also enhance the (2'-5')oligo(adenylate) synthetase and IFI-56K gene expression. We found that poly(rI).poly(rC) and interleukin-1, activators of the interferon-beta gene and of T lymphocytes respectively, are both able to enhance IFI-56K mRNA accumulation in all cell lines tested. Cycloheximide even superinduces this gene when added together with poly(rI).poly(rC) and interleukin-1 (but not when added with interferon). We showed that these inductions are direct and not mediated by interferon produced by cells in response to poly(rI).poly(rC) or interleukin-1. The promoter sequence analyses have thus led to the discovery of unexpected inducers, i.e. an interferon inducer such as poly(rI).poly(rC) is also able to directly induce a gene that is under the control of interferon.     

Intratracheal double-stranded RNA plus interferon-gamma: a model for analysis of the acute phase response to respiratory viral infections

Double-stranded (ds)RNA is made as a by-product of viral replication. Synthetic dsRNA induces virtually all of the same systemic symptoms as acute viral infections, such as fever and malaise. In order to develop a model of respiratory viral infections (such as influenza) suitable for use in gene knockout mice (where the deleted gene may affect viral replication), we examined C57BL/6 mouse body temperature and locomotor activity responses to the synthetic dsRNA polyriboinosinic.polyribocytidylic acid (poly[rI.rC]) introduced via the intratracheal (IT) route. We compared the IT poly[rI.rC] responses to the well-characterized intraperitoneal (IP) poly[rI.rC] responses. IT poly[rI.rC] failed to induce an acute phase response (APR) in mice, in contrast to IP poly[rI.rC]. However, addition of interferon (IFN)gamma to the IT poly[rI.rC] inoculum induced sustained hypothermia and suppressed locomotor activity responses with similar kinetics to those responses seen in acute mouse influenza. We further examined cytokine, antiviral, muscarinic M2 receptor and inducible nitric oxide synthase gene expression at 5 hr in the lungs of IT challenged mice. These studies suggested that priming the lung with IFNgamma could enhance proinflammatory (IL1beta, IL6, TNFalpha) cytokine gene expression and suppress interferon gene expression compared to IT poly[rI.rC] alone. No differences were detected for the other genes examined. While further molecular characterization of the model is required, we demonstrate that IT challenge with combined poly[rI.rC] and IFNgamma closely simulates the APR to an acute respiratory virus, and may serve as a suitable model for analyzing the molecular basis of the viral APR in gene knockout mice.     

Antibody targeted liposomes containing poly(rI).poly(rC) exert a specific antiviral and toxic effect on cells primed with interferons alpha/beta or gamma

Double-stranded RNA can stimulate interferon production and mediate an antiproliferative effect on certain cell types. We evaluated the possibility of specifically targeting to cells in vitro the RNA duplex poly(rI).poly(rC) in pharmacologically active form after its encapsulation in small, unilamellar liposomes, to which was covalently coupled protein A. These liposomes became bound to and were endocytosed by murine L929 cells in the presence of protein A-binding monoclonal antibodies specific for an expressed cell surface protein, the H-2K molecule. When L929 cells were preincubated in the presence of low doses of interferon alpha/beta or gamma, they could be activated to produce interferon following exposure to either free poly(rI).poly(rC), or specifically bound liposomes poly(rI).poly(rC), but not the same liposomes in the presence of non-cell binding control antibodies. Specifically bound liposome-encapsulated poly(rI).poly(rC) was toxic to L929 cells at dose levels at least three logs lower than free poly(rI).poly(rC). This toxicity was also dependent on pre-treatment with interferon. These results indicate that liposome-encapsulated poly(rI).poly(rC) can survive endocytosis and can be released in active form to specific cell populations, at concentrations much lower than that required for pharmacologic effects of the same molecule in free form. They suggest that introduction into cells of other nucleic acids might benefit from the antibody-targeted liposome technology described here.     

Differential induction by cadmium of a low-complexity ribonucleic acid class in cadmium-resistant and cadmium-sensitive mammalian cells

The Chinese hamster ovary (CHO) cell line and the subline Cdr20F4 have been used to compare cadmium-induced ribonucleic acid (RNA) synthesis in cadmium-sensitive and cadmium-resistant cells, respectively. Gel electrophoresis of the cell-free translation products directed by polyadenylated [poly(A+)] messenger RNA (mRNA) from cadmium-induced Cdr20F4 cells revealed four low molecular weight species (Mr 7000-21 000), including metallothionein, whose synthesis was not detected after translation of either cadmium-induced or uninduced CHO cell poly(A+) mRNA. At least two of these species were also detected after translation of an abundant 400-nucleotide (NT) RNA class purified from the cadmium-induced Cdr20F4 cell RNA. Molecular hybridization of complementary deoxyribonucleic acid (cDNA) complementary to this abundant, cadmium-induced 400-NT RNA fraction indicates that the cadmium-induced RNA class possesses a total kinetic complexity of about 2000 NT's. At least half of these inducible sequences are also represented constitutively in less abundant RNA classes of both uninduced CHO and Cdr20F4 cells. Induction of Cdr20F4 cells with cadmium increases the cellular concentration of the 2000-NT-complexity RNA class to a level at least 2 x 10(3)-fold greater than its constitutive level in uninduced Cdr20F4 cells. Induction of CHO cells with cadmium increases the cellular concentration of a subset of the sequences in the 2000-NT-complexity class, but only to a level 100-fold over the constitutive level in uninduced CHO cells. The remainder of these sequences belongs to the least abundant CHO cell poly(A+) RNA class.     

Comparison of polysomal polyadenylated RNA from embryonal carcinoma and committed myogenic and erythropoietic cell lines

Using the technique of mRNA-cDNA hybridization, we have examined the polysomal poly(A)⁺ mRNA base-sequence complexity in three different mouse cell lines: mouse embryonal carcinoma cells, myoblast cells and Friend erythroleukemic cells. These cells express 7700, 13,200 and 6200 mRNA sequences, respectively, distributed in three frequency classes. Reciprocal heterologous hybridization experiments revealed that there is a large degree of homology, a subset of 6000 common sequences being present on the polysomes of all three cell types. Myoblast mRNA is capable of hybridizing all reactive embryonal carcinoma cell cDNA, with kinetics close to the homologous embryonal carcinoma cell curve, thus indicating that all embryonal carcinoma cell sequences are present on myoblast polysomes, the majority at similar abundance. Conversely, embryonal carcinoma cell mRNA fails to hybridize 12% of myoblast cDNA, apparently arising primarily from the complex frequency class. This was confirmed by using myoblast fractions partially enriched in abundant and rare sequences. As a proportion of the rare class, this 12% fraction represents about 4500 sequences close to the difference in base-sequence complexity between myoblast and embryonal carcinoma cells.Homologous and heterologous hybridization with total and fractionated Friend cell cDNA probes revealed that all Friend cell polysomal poly(A)⁺ RNA sequences are common to embryonal carcinoma cell polysomes—apart from a small group of sequences drawn from the abundant class, corresponding to about 10% of Friend cell cDNA. This represents about 12 sequences from the abundant class. In addition, certain common sequences in the abundant Friend cell frequency class are present at lower frequency in embryonal carcinoma cell polysomes. Friend cell polysomal poly(A)⁺ RNA fails to hybridize 7–10% embryonal carcinoma cell cDNA apparently derived from the rare frequency class. As a fraction of the rare class, this corresponds approximately to the difference (about 1500 sequences) in complexity between the Friend and embryonal carcinoma cell lines.     

A possible role of autogenous IFN-beta for cytokine productions in human fibroblasts

It has been already known that human diploid fibroblasts are able to produce not only high levels of IFN-beta but also various kinds of cytokines by poly rI: poly rC, and some inflammatory cytokines are induced by IFN-beta gene activation. We also obtained similar results. However, in our system, cytokine productions were extremely enhanced by treating the cells with a low dose of type 1 IFN and the priming effects on cytokine productions were blocked by cycloheximide similar to those on IFN-beta productions. Most of cytokines were produced later than IFN-beta and synthesis patterns of their mRNA showed the same phenomena. We made clear that cytokine productions by poly rI: poly rC are mediated by secreted IFN-beta at a protein level using a monoclonal antibody against human IFN-beta. Further, it was shown that intra-cellular IFN-beta which is not secreted might also participate in cytokine productions. Meanwhile, IL-1beta induced various kinds of cytokines in human fibroblasts and production time courses of these cytokines were similar to those of poly rI: poly rC induced cytokines. Although secreted IFN-beta was not detected in IL-1beta stimulated culture, expression of IFN-beta mRNA was augmented. These results showed that priming effects of type 1 IFN on cytokine productions by poly rI: poly rC might not be the direct action, but successive IFN-beta production might be essential in the production processes of other cytokines. Further, it was suggested that inducible IFN-beta might also take part in IL-1beta-induced cytokine productions.     

Cloning of mouse carbonic anhydrase mRNA and its induction in mouse erythroleukemic cells

Mouse carbonic anhydrase mRNA was detected in poly(A+) RNA of anemic spleens sedimenting as a RNA species at 14 S. Subsequently, poly(A+) RNA (12-16 S) was used as a template for the synthesis of double-stranded cDNA, which was inserted into the PstI site of pBR322 by oligo-dG:dC tailing. A recombinant plasmid containing carbonic anhydrase cDNA was identified by a positive hybridization selection assay and by partial DNA sequencing. Predicted amino acid sequences showed homology with the known sequences of rabbit and human carbonic anhydrase I and II. The clone contained sequences for most of the coding region and 600-700 base pairs at the 3' noncoding region of the mRNA. Hybridization analysis of poly(A+) RNA from uninduced and induced mouse erythroleukemic cells labeled for short and long time periods indicated that induction results in an increase of carbonic anhydrase mRNA in newly synthesized RNA.     

Intracellular location of human fibroblast interferon messenger RNA

Human diploid fibroblast (FS-4) cells were induced to produce interferon mRNA by exposure to poly(rI)·poly(rC) plus cycloheximide. The intracellular location of interferon mRNA was investigated by differential centrifugation of the cytoplasm into a membrane (pellet) and a free (supernatant) fraction, followed by injection of mRNA isolated from either fraction into $\text{X}\text{.}\text{laevis}$ oocytes. When translation in FS-4 cells was prevented, most (85–90%) of the interferon mRNA activity was found in the free fraction. However, when translation was permitted, most (80–95%) of the interferon mRNA activity was found in the membrane fraction. These results are consistent with the predictions of the “signal hypothesis” (Blobel and Dobberstein, J. Cell Biol. 1975, $\text{67}$:835) for secretory proteins.     

Two closely linked transcription units within the 63B heat shock puff locus of D. melanogaster display strikingly different regulation

We report the isolation and characterization of a cloned DNA of D. melanogaster, Dm4L, that is derived from the major heat shock puff site at 63B. This segment contains two closely linked genes that are each present once per Drosophila haploid genome. One of these, the hsp 83 gene, encodes an abundant heat shock mRNA that, unlike other major heat shock mRNAs, is also abundant in uninduced (23 degrees) kco cells. Although only a slight increase in the level of total hsp 83 RNA can be detected after heat shock in Kco cells, the level of hsp 83 poly(A)+ mRNA increases more than 6-fold and the level of pulse-labeled hsp 83 RNA in total cellular RNA increases 11-fold relative to uninduced cells. In contrast, the levels of total, poly(A)+, and pulse-labeled RNA homologous to the second gene, 63B-T2, are approximately the same in both induced and uninduced cells. Hence, even though these genes are separated by only one thousand base pairs, and, from in situ hybridization to polytene chromosomes, both lie within the heat shock puff, they display strikingly different regulatory properties, These results demonstrate that close linkage of a gene to a heat shock puff is not sufficient to render its expression heat inducible.     

Polyadenylate-deficient analogues of poly(A)-containing mRNA sequences in cultured AKR mouse embryo cells

Five to six percent (by mass) of AKR-2B mouse embryo cell polysomal RNA consists of messenger RNA sequences which may exist in polyadenylated form. In the steady state, however, only 30–40% of these molecules are retained by extensive passage over oligo(dT)-cellulose, the remainder being present in the form of poly(A)-deficient analogues. Within experimental limits, these poly(A)-deficient analogues contain representatives of all poly(A)-containing mRNA sequences in these cells. An analysis of the kinetics of hybridization of cDNA probes enriched for either abundant or rare poly(A)-containing mRNA sequences suggests that the frequency distributions of poly(A)-containing and poly(A)-deficient analogues are dissimilar, and that a relationship exists between the intracellular frequency of a given mRNA sequence and the number of poly(A)-deficient analogues of that sequence. High frequency sequences appear to be enriched in the poly(A)-containing fraction, while low frequency sequences are predominately associated with the poly(A)-deficient fraction, thus, poly(A) may play a role in the regulation of mRNA frequency in the cytoplasm.     

Frequency distribution of mRNA and pre-mRNA in growing and differentiated Friend cells.

The frequency distribution of poly(A)+-mRNA in growing and in differentiated Friend cells has been measured by mRNA-cDNA hybridization and their differences established by heterologous hybridization of mRNA of one type and cDNA of the other. It was shown that induction of Friend cells involves an increase in abundance of a small number of mRNAs, while no specific pattern of messenger disappearance could be detected. The frequency distribution of pre-mRNA was determined by hybridizing nuclear RNA with the cDNA probes complementary to mRNA. In uninduced Friend cells, it was shown that most precursor messenger sequences are present at a single frequency of about 3 molecules per nucleus, independently of their final frequency in polysomal mRNA. In induced Friend cells, the frequency distribution of pre-mRNA is more heterogeneous and correlated to some extent with the corresponding mRNA frequency distribution.     

The binding of poly(rI) - poly(rC) to human fibroblasts and the induction of interferon.

Human embryonic fibroblasts produce interferon when incubated at 37 degrees C after being treated at 4 degrees C with poly(rI) - poly(rC), either by addition of the double-stranded duplex or by sequential addition of the constitutent single-stranded polynucleotides. Cells which have been incubated with double-stranded poly(rI) - poly(rC) can be prevented from forming interferon by washing the cells with high concentrations of salt, immediately after adsorption of polynucleotides, or by incubation of the cells with single-stranded polynucleotides. The inhibition is probably due to displacement of the inducing molecule from the cell surface. Interferon production by cells treated sequentially with poly(rI) and poly(rC) is not inhibited by either of these treatments and the polynucleotides are not easily displaced from the cell surface.     

HeLa cell cytoplasmic mRNA contains three classes of sequences: predominantly poly(A)-free, predominantly poly(A)-containing and bimorphic

The mRNA species which exist in the HeLa cell polyribisomes in a form devoid of A sequences longer than 8 nucleotides constitute the poly(A)-free class of mRNA. The rapidly labelled component of this mRNA class shares no measurable sequence homology with poly(A)-containing RNA. If poly(A)-free mRNA larger than 12 S labelled for 2 h in vivo is hybridized with total cellular DNA, it hybridizes primarily with single-copy DNA. When a large excess of steady poly(A)-containing RNA is added before hybridization of labelled poly(A)-free RNA, no inhibition of hybridization occurs. This indicates the existence of a class of poly(A)-free mRNA with no poly(A)-containing counterpart. Some mRNA species can exist solely as poly(A)-containing mRNAs. These mRNAs in HeLa cells are found almost exclusively in the mRNA species present only a few times per cell (scarce sequences). Some mRNA species can exist in two forms, poly(A)containing and lacking, as evidenced by the translation data in vitro of Kaufmann et al. [Proc. Natl Acad. Sci. U.S.A. 74, 4801--4805 (1977)]. In addition, if cDNA to total poly(A)-containing mRNA is fractionated into abundant and scarce classes, 47% of the scarce class cDNA can be readily hybridized with poly(A)-free mRNA. 10% of the abundant cDNA to poly(A)-containing mRNA will hybridize with poly(A)-free sequences very rapidly while the other 90% hybridize 160 times more slowly, indicating two very different frequency distributions. The cytoplasmic metabolism of these three distinct mRNA classes is discussed.     

Complex population of nonpolyadenylated messenger RNA in mouse brain

The complexity of nonadenylated mRNA [poly(A)-mRNA] has been determined by hybridization with single-copy DNA (scDNA) and cDNA. Our results show that poly(A)- and poly(A)+ mRNA are essentially nonoverlapping (nonhomologous) sequence populations of similar complexity. The sum of the complexities of poly(A)+ mRNA and poly(A)- mRNA is equal to that of total polysomal RNA or total mRNA, or the equivalent of approximately 1.7 x 10(5) different sequences 1.5 kb in length. Poly(A)- mRNA, isolated from polysomal RNA by benzoylated cellulose chromatography, hybridized with 3.6% of the scDNA, corresponding to a complexity of 7.8 x 10(4) different 1.5 kb sequences. The equivalent of only one adenosine tract of approximately 20 nucleotides per 100 poly(A)- mRNA molecules 1.5 kb in size was observed by hybridization with poly(U). cDNA was transcribed from poly(A)- mRNA using random oligonucleotides as primers. Only 1-2% of the single-copy fraction of this cDNA was hybridized using poly(A)+ mRNA as a driver. These results show that poly(A)- mRNA shares few sequences with poly(A)+ mRNA and thus constitutes a separate, complex class of messenger RNA. These measurements preclude the presence of a complex class of bimorphic mRNAs [that is, species present in both poly(A)+ and poly(A)- forms] in brain polysomes.     

Amplification and molecular cloning of murine adenosine deaminase gene sequences

A previously isolated mouse Cl-1D derived cell line (B-1/25) overproduces adenosine deaminase (EC 3.5.4.4) by 3200-fold. The present studies were undertaken to determine the molecular basis of this phenomenon. Rabbit reticulocyte lysate and Xenopus oocyte translation studies indicated that the B-1/25 cells also overproduced adenosine deaminase mRNA. Total poly(A+) RNA derived from B-1/25 was used to construct a cDNA library. After prehybridization with excess parental Cl-1D RNA to selectively prehybridize nonamplified sequences, 32P-labeled cDNA probe synthesized from B-1/25 total poly(A+) RNA was used to identify recombinant colonies containing amplified mRNA sequences. Positive clones containing adenosine deaminase gene sequences were identified by blot hybridization analysis and hybridization-selected translation in both rabbit reticulocyte lysate and Xenopus oocyte translation systems. Adenosine deaminase cDNA clones hybridized with three poly(A+) RNA species of 1.5, 1.7, and 5.2 kilobases in length, all of which were overproduced in the B-1/25 cell line. Dot blot hybridization analysis using an adenosine deaminase cDNA clone showed that the elevated adenosine deaminase level in the B-1/25 cells was fully accounted for by an increase in adenosine deaminase gene copy number. The adenosine deaminase cDNA probes and the cell lines with amplified adenosine deaminase genes should prove extremely useful in studying the structure and regulation of the adenosine deaminase gene.