Isolation of messenger RNA from polysomes by chromatography on oligo(dT)-cellulose.

A method for the isolation of messenger RNA (mRNA) from polysomes is described. Polysomes are dissolved in a solution containing 0.5 m NaCl and Na dodecyl sulphate and applied to an oligo(dT)-cellulose column. RNA species containing poly(A) sequences are retained by the column, whereas ribosomal proteins and other RNA species are washed off. The column is then eluted with a buffer not containing NaCl. mRNA from HeLa cells and from duck reticulocytes has been fractionated in this way. When fractionated on sucrose gradients, 10 s globin mRNA is obtained in addition to a 20 s component, which can be translated in a cell free system into duck globin. This 20 s RNA is an aggregate of mRNA, which can be disaggregated. Experiments with HeLa cells have shown that the only mRNA species which is not retained by oligo(dT)-cellulose is histone mRNA; this mRNA does not contain a poly(A) sequence.     

Control of synthesis of functional mRNA coding for phenylalanine ammonia-lyase from Rhodosporidium toruloides

The regulation of functional mRNA coding for phenylalanine ammonia-lyase (PAL) from Rhodosporidium toruloides was investigated. Polyadenylic acid [poly(A)]-containing RNA was an efficient template for in vitro translation in rabbit reticulocyte lysate. Non-poly(A)-containing RNA did not stimulate in vitro protein synthesis. Several lines of experimental evidence indicate that mRNA from R. toruloides directs PAL synthesis in reticulocyte lysate: (i) the major radioactive product in immunoprecipitates when lysates, incubated with yeast poly(A)-containing RNA, were reacted with PAL-antiserum had the same molecular weight as native PAL (75,000); (ii) this major radioactive product competes with authentic PAL for binding to PAL-antiserum; and (iii) partial proteolytic peptide maps of the in vitro translation product were very similar to those of native PAL. The levels of functional mRNA coding for PAL, when R. toruloides was grown in different physiological conditions, were determined by quantitation of PAL synthesized in vitro when RNA was added to reticulocyte lysate. Functional PAL mRNA was six times higher in yeast grown on phenylalanine compared with glucose-phenylalanine minimal medium. No functional PAL mRNA was detected in yeast grown on glucose-ammonia minimal medium in the presence or absence of phenylalanine. These observed changes in functional PAL mRNA were similar to levels of PAL catalytic and antigenic activity. The kinetics of functional PAL mRNA synthesis and degradation were studied. Maximum levels of functional PAL mRNA were observed within 60 min of transfer to PAL-inducing growth conditions. Poly(A)-containing RNA and functional PAL mRNA were rapidly degraded when cells were transferred from phenylalanine to glucose-ammonia minimal medium, with half-lives of 25 and 10 min, respectively. Thus, it is suggested that the alterations in the amount of PAL in cells of R. toruloides grown in different physiological conditions primarily result from alteration in the amount of functional mRNA coding for the enzyme.     

Quantitative measurements of fibroin messenger RNA synthesis in the posterior silk gland of normal and mutant Bombyx mori

The amount of newly synthesized and accumulated fibroin messenger RNA has been measured quantitatively at various stages of posterior silk gland development in Bombyx mori. The two-step method involves fractionation on a Bio-Gel column which excludes the large mRNA, followed by RNAase T₁ digestion, and fractionation of the oligonucleotides on DEAE-Sephadex. Larvae in the feeding stages of the third and fourth instar synthesize and accumulate fibroin mRNA to about 2% of cellular RNA; this corresponds to 0.2 and 2 μg per pair of posterior glands in the third and fourth instars, respectively. More than 70% of this mRNA is degraded in vivo during the third and fourth moulting stages. Fibroin mRNA synthesis resumes again within the first 24 hours of the fifth instar; the mRNA accumulates and predominates over other DNA-like RNAs as the stage proceeds until finally it comprises about 3.5% of cellular RNA in a mature larva (170 μg per pair of posterior glands). These results indicate that more than 99% of the fibroin mRNA detected in the fifth instar is synthesized during this stage.Four spontaneous mutants of B. mori which synthesize very low levels of fibroin have been analyzed for their RNA content in the middle fifth instar. The total cellular RNA of the posterior gland is reduced to 4 to 7% of normal. Fibroin mRNA is more severely reduced to 1% of normal. In three heterozygotes, which have mutant phenotypes with respect to fibroin production, only slight increases of total cellular RNA and fibroin mRNA were observed. Thus, the primary biochemical lesion in these mutants is still unknown.The presumed ancestor to B. mori, the wild silkworm B. mandarina, was also analyzed for its fibroin mRNA. The mRNA isolated from fifth instar larvae of B. mandarina is indistinguishable from that of B. mori with respect to its nucleotide sequence, molecular weight and fraction of total cellular RNA.     

Identification of c-myc coding region determinant RNA sequences and structures cleaved by an RNase1-like endoribonuclease

The coding region of c-myc mRNA encompassing the coding region determinant (CRD) nucleotides (nts) 1705-1792 is critical in regulating c-myc mRNA stability. This is in part due to the susceptibility of c-myc CRD RNA to attack by an endoribonuclease. We have previously purified and characterized a mammalian endoribonuclease that cleaves c-myc CRD RNA in vitro. This enzyme is tentatively identified as a 35 kDa RNase1-like endonuclease. In an effort to understand the sequence and secondary structure requirements for RNA cleavage by this enzyme, we have determined the secondary structure of the c-myc CRD RNA nts 1705-1792 using RNase probing technique. The secondary structure of c-myc CRD RNA possesses five stems; two of which contain 4 base pairs (stems I and V) and three consisting of 3 base pairs (stems II, III, and IV). Endonucleolytic assays using the c-myc CRD and several c-myc CRD mutants as substrates led to the following conclusions: (i) the enzyme prefers to cleave in between the dinucleotides UA, CA, and UG in single-stranded regions; (ii) the enzyme is more specific towards UA dinucleotides. These properties further distinguish the enzyme from previously described mammalian endonuclease that cleaves c-myc mRNA in vitro.     

Relative amounts of newly synthesized poly(A)+ and poly(A)- messenger RNA during development of Xenopus laevis

The relative amounts of newly synthesized poly(A)⁺ and poly(A)^? mRNA have been determined in developing embryos of the frog Xenopus laevis. Polysomal RNA was isolated and fractionated into poly(A)⁺ and poly(A)^? RNA fractions with oligo(dT)-cellulose. In normal embryos the newly synthesized polysomal poly(A)⁺ RNA has a heterodisperse size distribution as expected of mRNA. The labeled poly(A)^? RNA of polysomes is composed mainly of rRNA and 4S RNA. The amount of poly(A)^? mRNA in this fraction cannot be quantitated because it represents a very small proportion of the labeled poly(A)^? RNA. By using the anucleolate mutants of Xenopus which do not synthesize rRNA, it is possible to estimate the percentage of mRNA which contains poly(A) and lacks poly(A). All labeled polysomal RNA larger than 4S RNA which does not bind to oligo(dT)-cellulose in the anucleolate mutants is considered presumptive poly(A)^? mRNA. The results indicate that about 80% of the mRNA lacks a poly(A) segment long enough to bind to oligo(dT). The poly(A)⁺ and poly(A)^? mRNA populations have a similar size distribution with a modal molecular weight of about 7 × 10⁵. The poly(A) segment of poly(A)⁺ mRNA is about 125 nucleotides long. Analysis of the poly(A)^? mRNA fraction has shown that it lacks poly(A)₁₂₅.     

RNA synthesis and coding capacity of polyadenylated and nonpolyadenylated mRNA from cultures of differentiating Drosophila melanogaster myoblasts

We have investigated the synthesis and coding capacity of RNA isolated from cultures of differentiating Drosophila embryonic muscle cells. We find that following muscle cell fusion, the sedimentation profile of newly synthesized polyadenylated RNA becomes somewhat lighter. In vitro translation products analyzed by two-dimensional gel electrophoresis indicate that the coding capacity of translatable myogenic mRNA changes during differentiation. A group of several muscle-specific proteins (including the contractile proteins) is translated only from mRNA isolated after the initiation of fusion. This pattern coincides with proteins synthesized in vivo during differentiation. Additionally, we find that polyadenylated and nonpolyadenylated myogenic mRNA from a given developmental stage in culture have extremely similar coding potentials.     

Rapid Method for Direct Extraction of mRNA from Seeded Soils

A protocol for direct extraction of mRNA from soil samples was developed. Soil samples (10 g) were washed twice with 120 mM phosphate buffer (pH 5.2). The lysis of cells, fixation of RNA, and hydrolysis of DNA were achieved by vigorously shaking the washed soil in a 4 M guanidine thiocyanate solution containing 25 mM sodium citrate, 0.5% sarcosyl, and 0.1 M 2-mercaptoethanol. The pH of the homogenized mixture was adjusted with 2 M sodium acetate (pH 4.0); the mRNA was then extracted with phenol and chloroform. Total RNA was precipitated with isopropanol. This method extracts up to 17 μg of total RNA per g (wet weight) of soil containing 8.0 × 10⁸ cells of Pseudomonas aeruginosa PU21, and mRNA has been detected in 160-ng total RNA fractions. This method has been used for the detection of mRNA transcribed from specific biodegradative genes, including the nah and mer operons, in contaminated soils. This extraction method can be completed within a few hours and has tremendous potential for ecological studies of in situ gene expression among soil microbiotas.     

Complexity and characterization of polyadenylated RNA in the mouse brain

The complexity of nuclear RNA, poly(A)hnRNA, poly(A)mRNA, and total poly(A)RNA from mouse brain has been measured by saturation hybridization with nonrepeated DNA. These DNA populations were complementary, respectively, to 21, 13.5, 3.8, and 13.3% of the DNA. From the RNA Cot required to achieve half-sturation, it was estimated that about 2.5–3% of the mass of total nuclear RNA constituted most of the complexity. Similarly, complexity driver molecules constituted 6–7% of the mass of the poly(A)hnRNA. 75–80% of the poly(A)mRNA diversity is contained in an estimated 4–5% of the mass of this mRNA. Poly(A)hnRNA constituted about 20% of the mass of nuclear RNA and was comprised of molecules which sedimented in DMSO-sucrose gradients largely between 16S and 60S. The number average size of poly(A)hnRNA determined by sedimentation, electron microscopy, or poly(A) content was 4200–4800 nucleotides. Poly(A)mRNA constituted about 2% of the total polysomal RNA, and the number average size was 1100–1400 nucleotides. The complexity of whole cell poly(A)RNA, which contains both poly(A)hnRNA and poly(A)mRNA populations, was the same as poly(A)hnRNA. This implies that cytoplasmic polyadenylation does not occur to any apparent qualitative extent and that poly(A)mRNA is a subset of the poly(A)hnRNA population. The complexity of poly(A)hnRNA and poly(A)mRNA in kilobases was 5 × 10⁵ and 1.4 × 10⁵, respectively. DNA which hybridized with poly(A)mRNA renatures in the presence of excess total DNA at the same rate as nonrepetitive tracer DNA. Hence saturation values are due to hybridization with nonrepeated DNA and are therefore a direct measure of the sequence complexity of poly(A)mRNA. These results indicate that the nonrepeated sequence complexity of the poly(A)mRNA population is equal to about one fourth that observed for poly(A)hnRNA.