The cloning and expression of the gene encoding organ-specific esterase S from the genome of Drosophila virilis

We have cloned the gene for the esterase S isozymes complex from the genome of Drosophila virilis in pBR322. Esterase S is an enzyme which is specifically synthesized in the ejaculatory bulbs of D. virilis adult males. The gene for the esterase S isozyme complex (estS) has been localized in band 2G5e of chromosome II. Poly(A)+ RNA prepared from ejaculatory bulbs actively hybridizes with this band. A cloned 15-kb fragment of D. virilis DNA (pVE9) also hybridizes with band 2G5e. The area encoding the poly(A)+ RNA is located in the middle part of the cloned fragment whose ends are not transcribed in vivo. Only one poly(A)+ RNA which is 1.9 kb long and complementary to pVE9 DNA can be revealed in the cytoplasm. The mRNA preselected by hybridization to pVE9 DNA was microinjected into the cytoplasm of Xenopus laevis oocytes. In other experiments, the pVE9 DNA itself was microinjected into oocyte nuclei. In both cases, esterase S is synthesized in the oocytes, and the major part of the protein is transported from the oocytes and accumulated in the incubation medium.     

Messenger-like RNA synthesis and DNA chromosomal puffs in the salivary glands of Rhynchosciara americana

RNA synthesis was studied mainly in the proximal sections of Rhynchosciara salivary glands in late fourth instar at two typical periods of development. These are characterized either by the absence or presence of the so-called “DNA puffs” in the salivary gland chromosomes. It was found that simultaneously with the appearance of the DNA puffs there is a great increase in the synthesis of all RNA species. The greatest increase was found to take place in the rate of synthesis of messenger-like RNA. Four main classes of messenger-like RNA were detected, having mobilities corresponding to 33, 23, 16, and 14 S RNA. There is a correlation between the abundance of the 16 S messenger-like RNA and the degree of opening of the B-2 DNA puff. This species might therefore be transcribed from this puff.     

The preparation and characterization of locust vitellogenin messenger RNA and the synthesis of its complementary DNA.

Poly(A)+ (polyadenylated) RNA was isolated from vitellogenic female-locus fat-body by LiCl/urea extraction and poly(U)-Sepharose 4B affinity chromatography. Agarose-gel electrophoresis of this poly(A)+ RNA under denaturing conditions shows the presence of a high-molecular-weight species (greater than 31 S, 7100 nucleotides) as the major species, which is absent from the RNA prepared from male-locust fat-body. Inclusion of this poly(A)+ RNA in a mRNA-dependent reticulocyte-lysate system directs the synthesis of polypeptides that could be immunoprecipitated with monospecific antibodies against locust egg vitellin. DNA complementary (cDNA) to the poly(A)+ RNA was synthesized, and back-hybridization of the cDNA to its template reveals a major abundant species comprising about 45% of the total poly(A)+ RNA hybridizing with R0t 1/2 of 2 x 10(-2) mol . litre-1 . s. Abundant cDNA isolated from the total cDNA hybridizes to poly(A)+ RNA with a R0t 1/2 of 9 x 10(-3) mol . litre-1 . s. There are 9.1 x 10(3) copies of vitellogenin mRNA per cell of vitellogenic female-locust fat-body, comprising 55% of the poly(A)+ RNA and equivalent to 0.7% of total cellular RNA.     

Circulating human blood platelets retain appreciable amounts of poly (A)+ RNA

Platelets lack a nucleus and are usually considered to be incapable of protein synthesis due to an apparent lack of messenger RNA, precluding the construction of platelet cDNA libraries and hindering the cloning of authentic platelet cDNA's. We reasoned that vestigial amounts of messenger RNA may remain in platelets when they first separate from the megakaryocyte and circulate in the peripheral blood. We isolated poly (A)+ RNA from platelets obtained by pheresis of individuals with elevated blood platelet counts due to a myeloproliferative syndrome termed essential thrombocythemia. Northern blots using probes for platelet glycoprotein Ib indicate that the poly (A)+ RNA obtained from the platelets of these donors is, in fact, derived from platelets. Cell free translation studies using the platelet poly (A)+ RNA indicate that the material is translationally active. We conclude that, contrary to prevailing information, circulating human blood platelets retain appreciable amounts of poly (A)+ RNA and that this RNA can be harvested by the described approach. The poly (A)+ RNA provides templates for the synthesis of cDNA's that code for platelet proteins.     

Regulation of RNA processing and transport by a nuclear guanine nucleotide release protein and members of the Ras superfamily.

The RCC1 gene of mammals encodes a guanine nucleotide release protein (GNRP). RCC1 and a homolog in Saccharomyces cerevisiae (MTR1/PRP20/SRM1) have previously been implicated in control of mRNA metabolism and export from the nucleus. We here demonstrate that a temperature-sensitive fission yeast mutant which has a mutation in a homologous gene, and two of three additional (mtr1/prp20/srm1) mutants accumulate nuclear poly(A)+ RNA at 37 degrees C. In S.cerevisiae, maturation of rRNA and tRNA is also inhibited at 37 degrees C. Nevertheless, studies with the corresponding BHK-21 cell mutant indicate that protein import into the nucleus continues. MTR1 homologs regulate RNA processing at a point which is distinct from their regulation of chromosome condensation since: (i) poly(A)+ RNA accumulation in the fission yeast mutant precedes chromosome condensation, and (ii) unlike chromosome condensation, accumulation of nuclear poly(A)+ RNA does not require p34cdc28 kinase activation or protein synthesis. Moreover, experiments involving inhibition of DNA synthesis indicate that the S.cerevisiae homolog does not govern cell cycle checkpoint control. Since RCC1p acts as GNRP for Ran, a small nuclear GTPase of the ras superfamily, we have identified two homologs of Ran in S.cerevisiae (CNR1 and CNR2). Only CNR1 is essential, but both code for proteins extremely similar to Ran and can suppress mtr1 mutations in allele-specific fashion. Thus, MTR1 and its homologs appear to act as GNRPs for a family of conserved GTPases in controlling RNA metabolism and transport. Their role in governing checkpoint control appears to be restricted to higher eukaryotes.     

Translational properties of a non-polyadenylated oligo(U)-containing RNA fraction from wheat embryos

A non-polyadenylated oligo(U)-containing RNA (poly(A)- . oligo(U)+ RNA) fraction was isolated from wheat embryo cytoplasm and its properties were compared with those of polyadenylated RNA (poly(A)+ RNA) from the same source. Both RNA preparations were highly heterogeneous and effectively stimulated [14C]leucine incorporation in a wheat germ cell-free translation system. Electrophoretic patterns of the translation products appearing in the non-polyadenylated RNA- and polyadenylated RNA-supplemented translation assays, respectively, differed from each other. The non-polyadenylated RNA-specific translation products included, in particular, a series of high molecular weight polypeptides. It is concluded that a specific class of non-polyadenylated oligo(U)-containing mRNA species (other than histone mRNAs) occurs in the wheat embryo cells.     

Processing and function of undermethylated chicken embryo fibroblast mRNA.

Cycloleucine (1-aminocyclopentane-1-carboxylic acid) is a potent inhibitor of RNA methylation in B77 sarcoma virus-infected chicken embryo fibroblasts. Under conditions where 40 mM cycloleucine is present, internal N-6-methyladenosine and 5'-terminal can 2'-O-ribose methylations of poly(A)+ RNA are inhibited greater than 90%. The methylation of the 5'-terminal 7-methylguanosine, however, does not appear to be significantly affected. The poly(A)+ RNA synthesized in cycloleucine-treated cells is transported from the nucleus to the cytoplasm and associates with polyribosomes at rates comparable to poly(A)+ RNA in untreated cells. On the other hand, the transport and utilization of newly synthesized ribosomal RNA in cycloleucine-treated cells is impaired, and the accumulation of mature 18 S and 28 S rRNA is reduced.     

In vitro synthesis of full-length influenza virus complementary RNA.

Influenza virus-specific RNA has been synthesized in vitro, using cytoplasmic or microsomal fractions of influenza virus-infected MDCK cells. The RNA polymerase activity was stimulated 5-30 times by priming with ApG. About 20-30% of the product was polyadenylated. Most of the in vitro product was of positive polarity, as shown by hybridization to strand specific probes and by T1 fingerprinting of the poly(A)+ and poly(A)- RNA segments encoding haemagglutinin and nucleoprotein. The size of poly(A)- RNA segments, determined on sequencing gels, was indistinguishable from that of virion RNA, whereas poly(A)+ RNA segments contain poly(A) tails approximately 50 nucleotides long. The size of in vitro synthesized RNA segments was also determined by gel electrophoresis of S1-treated double-stranded RNAs, obtained by hybridization of poly(A)+ or poly(A)- RNA fractions with excess of unlabelled virion RNA. The results of these experiments indicate that poly(A)- RNA contains full-length complementary RNA. This conclusion is further substantiated by the presence of additional oligonucleotides in the T1 fingerprints of in vitro synthesized poly(A)- haemagglutinin or nucleoprotein RNA, selected by hybridization to cloned DNA probes corresponding to the 3' termini of the genes.     

Characterization of a poly(A)+RNA-containing structural component directly associated with cytoplasmic membranes in dormant Artemia cysts

Poly(A)+RNA-containing material was extracted from the purified cytoplasmic membranes of dormant Artemia cysts by treatment with mild detergents. Sedimentation analysis of the extracts showed a predominant poly(A)-containing fraction at 40 S, associated with about 6% of the extracted proteins. Only limited amounts of poly(A)-containing material were found in the heavier fractions. Poly(A)+RNA extracted from the 40-S fraction sedimented around 14 S. The poly(A)-containing 40-S structures could be purified by treatment with non-ionic or zwitterionic detergents followed by resedimentation in sucrose gradients in the presence or absence of detergent. When the 40-S fraction was analyzed by isopycnic centrifugation in Cs2SO4 gradients, the main part of the poly(A)-containing material banded at a density of 1.27 g/ml. Electron-microscopic examination of this fraction revealed circular or slightly bullet-shaped profiles measuring 17-26 nm. When the 40-S fraction had been submitted to mild RNAase treatment prior to density gradient centrifugation, the material was displaced towards lower density and became less distinct. Purified 40-S particles showed a complex protein pattern not very similar to that of polyribosomal poly(A)+RNA-containing particles from developing embryos, but with components in common with unfractionated membranes. The particles also contained some lipids. The experiments indicate that a major part of the membrane-bound, latent poly(A)+RNA in dormant Artemia cysts occurs in the form of relatively uniform, detergent- and Cs2SO4-resistant structures, independent of ribosomes, but intimately associated with membrane components.     

Characterization and measurement of metallothionein messenger RNA of C57BL mouse liver

Liver poly(A)+RNA of Cd2+-treated C57BL mouse was characterized by cell-free translation, particularly intending to establish a procedure to measure the levels of messenger RNA coding for metallothioneins (MT-mRNA). Intact polysomes were obtained by Mg2+ precipitation from the liver cytoplasm of mice injected with 1 mg Cd2+/kg body wt. Poly(A)+RNA isolated from the polysomes was translated by a wheat germ cell-free system and the [35S]cysteine-labeled translation products were analyzed by sodium dodecyl sulfate (SDS)-15% polyacrylamide gel electrophoresis and fluorography. MTs were identified in the translation products directed by the RNA from the Cd2+-treated mice, but not in the translation products directed by the RNA from untreated mice. Relative incorporation of [35S]cysteine into MTs was determined by densitometrical quantification of the MT bands, and was found to be linear up to a RNA concentration of 150 micrograms/ml in the translation reaction mixture, showing that this system is suitable for the measurement of translatable MT-mRNA levels. Cd2+ stimulated the total levels of cell-free translation (1.4-fold at 20-60 micrograms/ml), not specifically to MT-mRNA. MT-mRNA sedimented at 9S in a sucrose gradient, and its size was comparable with rat and human MT-mRNAs.     

Expression of mRNA of beta 1- and beta 2-adrenergic receptors in Xenopus oocytes results from structurally distinct receptor mRNAs

Poly(A)+-selected RNA prepared from cells or tissues that express a homogeneous population of either beta 1- or beta 2-adrenergic receptors was isolated and then microinjected into Xenopus laevis oocytes. Following microinjection, the expression of beta-adrenergic receptors was assessed by equilibrium radioligand binding analysis using the antagonist ligand [3H]dihydroalprenolol. The pharmacology of the newly- expressed beta-adrenergic receptors in oocyte membranes was the same as that of the original tissue used as a source of RNA. Hybridization of nick-translated cDNA of hamster beta 2-adrenergic receptor to poly(A)+-selected RNA from tissues containing beta 2-adrenergic receptors was to a mRNA species of 2.2 kilobases. In contrast, hybridization of the cDNA probe to poly(A)+-selected RNA from tissues containing beta 1-adrenergic receptors was to a mRNA species of 2.0 kilobases. A single-stranded fragment of hamster beta 2-adrenergic receptor cDNA corresponding to nucleotides 730-886 was isolated and uniformly radiolabeled. This region of the gene is predicted to encode for the entire second exofacial loop (L4-5), the entire fifth transmembrane-spanning region, and the first 5 amino acid residues of the third cytoplasmic loop (L5-6) of the beta 2-adrenergic receptor. Hybridization at 48 and 56 degrees C of poly(A)+-selected RNA prepared from sources that express either beta 1 or beta 2-adrenergic receptors to the antisense orientation strand of this region of the beta 2-adrenergic receptor cDNA was followed by S1 endonuclease digestion of nonhybridized sequences. At 48 degrees C, S1-resistant hybrids from both sources of RNA protected the probe from S1 endonuclease digestion. At 56 degrees C, however, only the RNA prepared from the source of beta 2-adrenergic receptors protected the probe from S1 endonuclease digestion. These results demonstrate that the mRNAs encoding for the structurally homologous beta 1- and beta 2-adrenergic receptors are distinct in the pharmacological specificity of their translation products and in their size and structure.     

Mouse ubiquitous B2 repeat in polysomal and cytoplasmic poly(A)+RNAs: uniderectional orientation and 3''-end localization.

A cDNA library in pBR322 was prepared with cytoplasmic poly(A)+RNA from mouse liver cells. From 1 to 1.5% of clones hybridized to either B1 or B2 ubiquitous repetitive sequences. Several clones hybridizing to a B2 repeat were partially sequenced. The full-length B2 sequence was found at the 3'-end of abundant 20S poly(A)+RNA (designated as B2+mRNAx) within the non-coding part of it. B2+mRNAx is concentrated in mouse liver polysomes and absent from cytoplasm of Ehrlich carcinoma cells. The B2 sequence seems to be located at the 3'-end of some other mRNAs as well. To determine the orientation of the B2 sequence in different RNAs, its two strands were labeled, electrophoretically separated, and used for hybridization with Northern blotts containing nuclear, cytoplasmic and polysomal RNAs. In nuclear RNA, the B2 sequence is present in both orientations; in polysomal and cytoplasmic poly(A)+RNAs, only one ("canonical") strand of it can be detected. Low molecular weight poly(A)+B2+RNA [1] also contains the same strand of the B2 element. The conclusion has been drawn that only one its strand can survive the processing. This strand contains promoter-like sequences and AATAAA blocks. The latter can be used in some cases by the cell as mRNA polyadenylation signals.     

Transport of different RNA species from the nucleus to the cytoplasm in Xenopus laevis neurula cells

Isolated cells from Xenopus laevis neurulae were labeled, and the RNAs extracted from their nuclear and soluble cytoplasmic fractions were analyzed on polyacrylamide gels. In the soluble cytoplasm, 4S RNA emerged very rapidly, and this was immediately followed by the emergence of poly(A)-containing RNA and 18S ribosomal RNA. In contrast, the emergence of 28S ribosomal RNA was delayed by about 2 hr. The size distribution of cytoplasmic poly(A)-containing RNA was much smaller as compared to that of nuclear poly(A)-containing RNA. These results indicate that the newly synthesized RNAs in Xenopus neurula cells are transported from the nucleus to the cytoplasm in a characteristic sequence.     

Characterization of two SV40 early mRNAs and evidence for a nuclear "prespliced" RNA species.

Using in vitro translation of sucrose-gradient fractionated cytoplasmic mRNA from SV40-infected cells, we have shown that a deletion in the region mapping between 0.54--0.59 reduced the size of mRNA for small-t but not the size of mRNA for large-T. Mutants with a deletion in this region were shown to produce in vivo either shortened small-t or no small-t, and normal large-T. Similarly, in vitro translation of poly(A)+cytoplasmic RNA from cells infected with these mutants gave the same results. On the other hand in vitro translation of poly(A)+nuclear RNA from the mutants which made no small-t produced a small-t derivative possibly synthesized from a prespliced RNA species. We have also shown that poly(A)+nuclear RNA from mutant dl 2122 produced two small-t related proteins: one of these (MW: 11K) probably represents the product of a "prespliced" RNA, the other (MW: 17K) which is also found in the cytoplasm represents the product of the mutant specific small-t mRNA.     

Cytoplasmic RNA complementary to pre-albumin intron V

We have detected an RNA species, containing sequences complementary to pre-albumin intron V in poly(A)+ RNA from rat liver cytoplasm (but not in nuclear RNA). Its relative abundance roughly parallels that of mature albumin mRNA, when comparing control with acute phase preparations.