Quantitative isolation of radiolabeled metabolites without chromatography: measurements of the biosynthesis of purines, pyrimidines, and urea in isolated hepatocytes

Poly(U) Sepharose column chromatography was used to characterize the poly(A) RNA in RNA fractions differentially extracted from mammalian cells and subcellular components.. RNA fraction A was phenol extracted at pH 5.2 and 4°C and fraction B was phenol extracted from the residual material by elevating the extraction temperature and pH. With labeled RNA from HeLa cells, six peaks were isolated using a decreasing discontinuous KCl gradient (peaks I through IV), 1% sodium dodecylsulfate (peak V), and 90% formamide (peak VI). Peaks I through IV in fraction A were 0.8 to 2.3% polyadenylic acid; peak V was 2.9%; and peak VI, 16.7%. In fraction B RNA, peaks I through IV were 6 to 7.6% polyadenylic acid; peak V, 7.7%; and peak VI, 19.5%. After 24 h labeling of human myeloma cells to achieve a steady state, and subsequent subcellular fractionation, peak III was localized in RNA fraction B from the chromatin; this peak was not found in the polysomes. These and other observations suggest that poly(U) Sepharose chromatography combined with a discontinuous elution scheme is a very sensitive procedure for monitoring metabolic changes in poly(A) RNA subpopulations with time, subcellular location, and RNA extraction procedure.     

Polyadenylated, noncapped RNA from the archaebacterium Methanococcus vannielii.

Polyadenylated [poly(A)+] RNA molecules have been isolated from Methanococcus vannielii by oligodeoxythymidylate-cellulose affinity chromatography at 4 degrees C. Approximately 16% of the label in RNA isolated from cultures allowed to incorporate [3H]uridine for 3 min at 37 degrees C was poly(A)+ RNA. In contrast, less than 1% of the radioactivity in RNA labeled over a period of several generations was contained in poly(A)+ RNA molecules. Electrophoretic separation of poly(A)+ RNA molecules showed a heterogeneous population with mobilities indicative of sizes ranging from 900 to 3,000 bases in length. The population of poly(A)+ RNA molecules was found to have a half-life in vivo of approximately 12 min. Polyadenylate [poly(A)] tracts were isolated by digestion with RNase A and RNase T1 after 3' end labeling of the poly(A)+ RNA with RNA ligase. These radioactively labeled poly(A) oligonucleotides were shown by electrophoresis through DNA sequencing gels to average 10 bases in length, with major components of 5, 9, 10, 11, and 12 bases. The lengths of these poly(A) sequences are in agreement with estimates obtained from RNase A and RNase T1 digestions of [3H]adenine-labeled poly(A)+ RNA molecules. Poly(A)+ RNA molecules from M. vannielii were labeled at their 5' termini with T4 polynucleotide kinase after dephosphorylation with calf intestine alkaline phosphatase. Pretreatment of the RNA molecules with tobacco acid pyrophosphatase did not increase the amount of phosphate incorporated into poly(A)+ RNA molecules by polynucleotide kinase, indicating that the poly(A)+ RNA molecules did not have modified bases (caps) at their 5' termini. The relatively short poly(A) tracts, the lack of 5' cap structures, and the instability of the poly(A)+ RNA molecules isolated from M. vannielii indicate that these archaebacterial poly(A)+ RNAs more closely resemble eubacterial mRNAs than eucaryotic mRNAs.     

Procedure for the Preparation of Milligram Quantities of Adenovirus Messenger Ribonucleic Acid

Late after adenovirus 2 infection (18 hr), nearly all newly synthesized polysomal messenger ribonucleic acid (mRNA) is viral specified. Large amounts of adenovirus mRNA have been purified by utilizing membrane filtration at high ionic strength. With this procedure, molecules that contain polyadenylic acid [poly (A)] tracts are bound selectively, and ribosomal RNA can be separated from the viral mRNA which contains poly(A). Polysomal RNA synthesized 18 hr after infection was labeled in the presence of 0.02 mug of actinomycin D per ml and extracted at pH 9.0. This RNA annealed 40% to 3 mug of adenovirus 2 deoxyribonucleic acid; the RNA selected by membrane filtration bound 80% under the same conditions. The RNA eluted from membrane filters was 80 to 90% greater than 18S and contained species migrating as 31, 27, and 24S. Binding of polysomal RNA to individual membrane filters was linear, using as much as 300 mug of RNA per membrane. A 1.1-mg amount of viral RNA was prepared from 17.7 mg of polysomal RNA that had been purified by extraction at pH 9.0.     

Fractionation and characterization of rat liver poly(A)-containing RNA.

Three fractions of poly(A)-containing RNA were separated from total rat liver RNA using poly(U)-Sepharose 4B affinity chromatography. The poly(A)-containing RNA fractions were released by thermal elution. Fraction 1, eluted under the mildest conditions, and had poly(A) tracts of approx. 200 AMP units in length which appeared to be associated with poly(U) sequences of 20-50 UMP in length. Fraction 1 appeared to be present mainly in the nucleus and, its size distribution was similar to that of fractions 2 and 3. Fractions 2 and 3 eluted at higher temperatures and were associated mainly with polysomal and microsomal fractions. Poly(U) sequences were absent in fractions 2 and 3 while their poly(A) sequences had a size distribution characteristic of those reported in the mRNA of other organisms.     

Changes in expression of albumin and alpha-fetoprotein genes during rat liver development and neoplasia.

Albumin mRNA was isolated and purified from rat liver polysomes by a combination of immunoprecipitation of specific polysomes, poly(U)-Sepharose 4B chromatography, and fractionation of the resulting poly(A)-containing RNA on a sucrose gradient. alpha-Fetoprotein (AFP) mRNA was isolated from Morris hepatoma 7777 by a similar procedure. The purity of the mRNA preparations was determined by analytical gel electrophoresis under denaturing conditions, analysis of sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the polypeptides synthesized in a wheat germ cell-free system, and the kinetics of hybridization to cDNA transcribed from albumin mRNA and AFP mRNA. The albumin mRNA possessed a chain length of approximately 2265 nucleotides and the AFP mRNA possesed a length of approximately 2235 nucleotides when examined under stringent denaturing conditions on agarose gels containing 10 mM methylmercury hydroxide. Analysis of poly(A) content by a hybridization assay with [3H]poly(U) revealed the presence in albumin mRNA of a poly(A) region containing approximately 100 adenosine residues. The AFP mRNA preparation was found to contain an average poly(A) tract of approximately 190 bases. Thus, albumin mRNA appears to contain approximately 330 untranslated nucleotides, and AFP mRNA appears to contain a similar number (approximately 285) of noncoding, nonpoly(A) bases. The purified albumin and AFP mRNA's were used as templates for synthesis of full-length cDNA hybridization probes. Both of the probes selectively hybridized to their templates with kinetics expected for single RNA species the sizes of albumin and AFP mRNA. ROt analysis was used to quantitate albumin and AFP mRNA sequences during normal liver postnatal development and liver oncogenesis. The number of polysomal AFP mRNA molecules per liver was found to drastically decrease during the first weeks of postnatal life, concomitant with a decline in the AFP synthetic capacity of the livers and in the serum concentrations of AFP. During this period, the concentration of albumin mRNA molecules per cell in the liver remained at high, approximately constant levels. In Morris hepatoma 7777, the concentration of AFP-specifying sequences was at least 10(3)-fold higher than that found in normal adult liver, whereas the content of albumin nRNA was four- to five-fold lower. These changes in concentration of albumin and AFP mRNA sequences closely correlated with a parallel variation in the specific protein synthetic capacity of the tissues.     

Effect of 5-fluoroorotic acid administration of the 32 P base composition, DNA-RNA hybridization properties, and labeling of polyadenylate-rich RNA in the cytoplasm of rat liver cells

5-Fluoroorotic acid treatment lowered the (Guanine + Cytosine)/(Adenine + Uracil) base ratio of ³²P-labeled microsomal RNA from a control value of 1.36 to 1.00. Low doses of actinomycin D, which are effective in inhibiting ribosomal RNA synthesis without significantly affecting messenger RNA synthesis, caused a similar decrease in the base ratio. Microsomal RNA labeled by [³H]orotate in the presence of 5-fluoroorotic acid had approximately $\text{1}\text{2}$ the specific radioactivity but twice the hybridization efficiency of RNA labeled in its absence. Evidence is presented that this RNA (1) has a different structure from that of ribosomal RNA, (2) hybridizes to DNA with an efficiency consistent with that of other published studies of polysome-associated messenger RNA, and (3) possesses sequences which are present in other samples of liver microsomal RNA but not in kidney microsomal RNA. These properties differ from those known to be exhibited by 18 S and 28 S ribosomal RNA. Electrophoretic analysis of this [³H]orotate-labeled microsomal RNA indicated that the analogue greatly inhibited precursor incorporation into ribosomal RNA but had little or no effect on incorporation into messenger RNA. Ribosomal RNA and polyadenylate-rich nonribosomal RNA were prepared from total polyribosomes by phenol extraction at pH 7.6 and pH 9.0, respectively. 5-Fluoroorotic acid inhibited [³H]orotate or ³²P_i incorporation into the pH 7.6 fraction much more effectively than incorporation into the pH 9.0 fraction. A subfraction of the pH 9.0 RNA which was retained by a polythymidylate-cellulose column had a greatly increased adenylate content.     

A poly(U) polymerase in tobacco leaves.

A poly(U) polymerizing enzyme has been found in healthy and tobacco mosaic virus-infected tobacco leaves and has been partially purified by affinity chromatography on a gel prepared from agarose with chemically coupled RNA. The enzyme is stimulated by Mn-2+ and dependent on a polynucleotide, preferentially poly(A). The synthesis proceeds optimally at pH 7.6 and 25 degrees C. The enzyme is highly specific for UTP and is inhibited by other ribonucleoside triphosphates. The product was partly sensitive to pancreatic ribonuclease. The synthetic reaction is inhibited in the presence of pyrophosphate but insensitive to 10 mM orthophosphate and high levels of cordycepin, rifampicin and actinomycin D. A molecular weight of about 40,000 has been estimated by sucrose gradient analysis and partition cell ultracentrifugation.     

The polyadenylic sequences in the ribonucleic acid of the fern Anemia phyllitidis

The vegetative prothalli (1–3 weeks old) of Anemia were incubated for 24 h in [¹⁴C]adenine. The RNA was phenol extracted from whole cells and the poly (A) sequences were isolated by nuclease digestion followed by poly (U)-sepharose chromatography. About 2–3% of the total radioactivity was retained on the column. The base composition of the nuclease resistant RNA was: C, 1.4; G, 3.6; A, 93.3; and U, 1.7. It is concluded that Anemia RNA contains poly adenylate sequences.Part of a post-doctoral work. Fellowship awarded by Alexander von Humboldt-Stiftung, Federal Republic of Germany     

The putative 15 S precursor of globin mRNA contains a poly (A) sequence

[3H] Uridine or [3H] adenosine pulse-labelled nuclear RNA was isolated from chicken immature red blood cells and separated on denaturing formamide sucrose gradients. RNA of each gradient fraction was hybridized with unlabelled globin DNA complementary to mRNA (cDNA) and subsequently digested by RNAase A and RNAase T1. The experiments revealed two RNA species with globin coding sequences sedimenting 9 S and approx. 15 S, the latter probably representing a precursor of 9 S globin mRNA. A poly (A) sequence was demonstrated in this RNA by two different approaches. Nuclear RNA pulse-labelled with [3H] uridine was fractionated by chromatography on poly (U)-Sepharose. Part of the 15 S precursor was found in the poly(A)-containing RNA. In the second approach 15 S RNA pulse-labelled with [3H]adenosine was hybridized with globin cDNA, incubated with RNAase A and RNAase T1 and subjected to chromatography on hydroxyapatite. The hybrids were isolated and after separation of the strands degraded with DNAase I, RNAase A and RNAase T1. By this procedure poly(A) sequences of approximately 100 nucleotides could be isolated from the 15 S RNA with globin coding sequences. The poly(A) sequence was completely degraded by RNAase T2.     

Isolation and characterization of polysomes and polyadenylated polysomal RNA from vicia faba meristematic root cells

Undegraded Vicia faba polysomes from meristematic root cells were obtained after homogenization in a medium of low ionic strength provided that the pH was equal to 9.0. By minimizing the shearing forces during the homogenization step, polysomes were obtained free of mitochondrial and nuclear contaminants, measured by differential spectrophotometry and CsCl gradient centrifugation respectively. Poly(A)-containing RNA was obtained by poly(U)-Sepharose chromatography and shown to be virtually free of rRNA and its average size was 13–15 S. Approximately 9% of the purified preparation was annealed by [3H]-poly(U). Sucrose gradient analysis under denaturing conditions showed that the poly(A)-containing RNA were non-degraded. This RNA was used to direct the synthesis of proteins in a heterologous cell-free system from wheat germ.     

Nucleotide sequences in the RNA of mammalian leukemia and sarcoma viruses.

The nucleotide sequences in viral RNA from purified murine sarcoma and hamster leukemia viruses (S+H+) from HTG-1 cells and Rauscher leukemia virus (RLV) from JLS-V 9 cells have been examined by polynucleotide agarose affinity chromatography. There is at least one copy of poly(A) sequences per genomic viral RNA molecule. After heat denaturation of genomic viral RNA (S+H+), there are two types of viral subunits for 34S and 28S species: one that contains poly(A) sequences and one that does not. There are no detectable poly(U) tracts in the viral RNA. However, poly(C) sequences and poly(G) tracts were detected in viral RNA, although less poly(G) than poly(C) tracts were observed. In addition, heat-denatured genomic viral RNA has a greater affinity for poly(G) agarose column than native genomic viral RNA.     

Different binding of poly(A)-containing and poly(A)-free fractions of nuclear ribonucleic acid to ribosomes from rat liver.

Total nuclear RNA extracted from nuclei of rat liver cells by phenol/chloroform in the presence of sodium dodecyl sulphate was separated by combined gel filtration on Sepharose 4 B and affinity chromatography on poly(U) Sepharose into fractions differing in their molecular weights and contents of poly(A) sequences. The poly(A)-containing 45-S RNA became labelled most rapidly if rats were administered [3H] orotic acid. This fraction showed a high template activity when added to postmitochondrial supernatants of the Krebs ascites tumour. Fractions of nRNA, free of poly(A) sequences, had no stimulating effect on protein synthesis in this system. The 45-S RNA-containing poly(A) was readily bound to crude polyribosomes from rat liver at 0 degrees C and both ATP and GTP were necessary for this reaction. Sucrose gradient analyses provided evidence that this RNA species is bound predominantly to 80-S ribosomes. No binding was obtained with polyribosomes washed with 0.5 M KCl. The binding ability of washed polyribosomes was restored by the addition of the ribosomal wash fraction or rat liver cytosol. Crude polyribosomes bound significantly lower quantities of nRNA species free of poly(A) when compared with poly(A)-45-S RNA. The label was scattered through the whole ribosomal sedimentation pattern with no predominant peaks and the binding reaction required neither soluble factors nor nucleotide cofactors. The labelling kinetics and high template activity of poly(A)-45-S nRNA indicate that this fraction contains precursors of cytoplasmic mRNA. Requirements for soluble factors and nucleotide cofactors in the binding of this RNA species to 80-S ribosomes suggest that this binding, unlike that of other nRNA species, has a specific mechanism resembling that of mRNA binding during peptide initiation.     

The putative 15 S precursor of globin mRNA contains a poly(A) sequence

[³H]Uridine or [³H]adenosine pulse-labelled nuclear RNA was isolated from chicken immature red blood cells and separated on denaturing formamide sucrose gradients. RNA of each gradient fraction was hybridized with unlabelled globin DNA complementary to mRNA (cDNA) and subsequently digested by RNAase A and RNAase T₁. The experiments revealed two RNA species with globin coding sequences sedimenting at 9 S and approx. 15 S, the latter probably representing a precursor of 9 S globin mRNA.A poly(A) sequence was demonstrated in this RNA by two different approaches. Nuclear RNA pulse-labelled with [³H]uridine was fractionated by chromatography on poly(U)-Sepharose. Part of the 15 S precursor was found in the poly(A)-containing RNA. In the second approach 15 S RNA pulse-labelled with [³H]adenosine was hybridized with globin cDNA, incubated with RNAase A and RNAase T₁ and subjected to chromatography on hydroxyapatite. The hybrids were isolated and after separation of the strands degraded with DNAase I, RNAase A and RNAase T₁. By this procedure poly(A) sequences of approximately 100 nucleotides could be isolated from the 15 S RNA with globin coding sequences. The poly(A) sequence was completely degraded by RNAase T₂.     

Synthesis of poly(A)-containing RNA by isolated spinach chloroplasts.

Chloroplasts were isolated from spinach leaves and the intact chloroplasts separated by centrifugation on gradients of silica sol. Chloroplasts prepared in this way were almost completely free of cytoplasmic rRNA. The purified chloroplasts were incubated with 32PO4 in the light. The nucleic acids were then extracted and the RNA was fractionated into poly(A)-lacking RNA and poly(A)-containing RNA (poly(A)-RNA) via oligo(dT)-cellulose chromatography. The poly(A)-RNA had a mean size of approximately 18--20 S as determined by polyacrylamide gel electrophoresis. The poly(A)-RNA was digested with RNase A and RNase T1, and the resulting poly(A) segments were subjected to electrophoresis on a 10% w/v polyacrylamide gel 98% v/v formamide). Radioactivity was incorporated into both poly(A)-RNA and poly(A)-lacking RNA and into the poly(A) segments themselves. The poly(A) segments were between 10 and 45 residues long and alkaline hydrolysis of poly(A) segments followed by descending paper chromatography showed that they were composed primarily of adenine residues. There was no 32PO4 incorporation into acid-insoluble material in the dark. We conclude that isolated chloroplasts are capable of synthesizing poly(A)-RNA.     

Structure and function of rat liver polysome populations. I. Complexity, frequency distribution, and degree of uniqueness of free and membrane-bound polysomal polyadenylate-containing RNA populations

Free and membrane-bound polysomes were isolated from rat liver in high yields with minimal degradation, cross-contamination, or contamination by nuclear or nonpolysomal cytoplasmic ribonucleoprotein. Poly(A)+ RNA fractions isolated from free and bound polysomal RNA (poly(A)+ RNAfree and poly(A)+ RNAbound) by oligo(dT) cellulose chromatography exhibited number-average lengths of 1,600 and 1,200 nucleotides, respectively, on formamide sucrose gradients. Poly(A)+ RNAfree and poly(A)+ RNAbound contain 9.1 +/- 0.55 and 10.7 +/- 0.50% poly(A) as measured by hybridization to [3H]poly(U) and comprise 2.37 and 1.22% of their respective polysomal RNA populations. Homologous poly(A)+ RNA-cDNA hybridizations revealed that greater than 95% of the mass of poly(A)+ RNAfree and poly(A)+ RNAbound contain nucleotide complexities of about 3.4 x 10(7) and 6.0 x 10(6), respectively. This represents about 20,000 and 5,000 poly(A)+ RNA species of average sizes. Heterologous hybridizations suggested that considerable overlap exists between poly(A)+ RNAfree and poly(A)+ RNAbound sequences that cannot be attributed to cross-contamination. This was confirmed by conducting heterologous reactions using kinetically enriched cDNA populations. Heterologous hybridizations involving poly(A)+ RNA derived from tightly bound polysomes and cDNAfree indicated tha most of the overlapping sequences are not contributed by loosely bound (high-salt releasable) polysomes. The ramifications of these findings are discussed.