A characterization of globin mRNA sequences in the nucleus of duck immature red blood cells

Studies were performed with duck immature red blood cells to identify and characterize the globin mRNA sequences in nuclear RNA. Annealing of ³H-globin cDNA to unlabeled nuclear RNA has identified three distinct size classes of nuclear RNA molecules containing globin mRNA sequences. The largest size class contained 1–2% of total nuclear globin mRNA sequences and sedimented through 85% formamide-sucrose gradients at the same rate as 28S ribosomal RNA. Chromatography on oligo(dT)-cellulose indicated that most of these molecules are not polyadenylated. The bulk of nuclear globin mRNA sequences (70%) was contained in polyadenylated RNA molecules which sedimented at 16.5S. The remainder of nuclear globin mRNA sequences (～30%) was detected in molecules sedimenting at 10S (the position of cytoplasmic globin mRNA).To determine whether a precursor-product relationship exists between these nuclear molecules and cytoplasmic globin mRNA, pulse-label and chase experiments were performed. Labeled globin mRNA sequences were assayed by annealing to globin cDNA-cellulose. Labeled 28S nuclear globin RNA sequences could not be detected, perhaps due to technical reasons. 16.5S nuclear globin RNA was labeled and chased into cytoplasmic globin mRNA sequences. The half-life of 16.5S nuclear globin RNA was estimated to be less than 30 min. These results demonstrate that in duck immature red blood cells, globin mRNA is transcribed as a larger precursor. Furthermore, size characterization of this precursor during pulse-label and chase periods suggests that it is processed within the nucleus to 10S globin RNA.     

A precursor of globin messenger RNA

The size of pulse-labeled globin messenger RNA nucleotide sequences was investigated, to determine whether newly transcribed globin mRNA molecules are larger than steady-state globin mRNA. Molecular hybridization techniques were used to compare directly the sedimentation of steady-state (unlabeled) and pulse-labeled (radioactive) globin mRNA sequences in the same analytical sucrose gradient. In gradients containing 98% formamide, radioactive globin mRNA sequences from mouse fetal liver cells labeled for 15 to 20 minutes with [³H]uridine sediment in a broad band with a peak at approximately 14 S, while steady-state globin mRNA sediments at 10 S. The large radioactive RNA can be recovered from one gradient and recentrifuged in a second gradient, in which it again sediments in a broad band with a peak at 14 S. The large radioactive RNA is cleaved to 10 S during a 75-minute “chase” with either actinomycin D or unlabeled uridine plus cytidine. The estimated half-life of the precursor is 45 minutes or less under these conditions. A covalent RNA precursor larger than 18 S with a similar turnover rate is not observed.     

Sequences coding for proteins expressed in liver and for globin in poly(A)+ and poly(A)− RNA fractions from nuclei and cytoplasm of chicken immature red blood cells

By hybridization with [³H]labeled globin cDNA the contents of globin coding sequences in total nuclear RNA, poly(A)⁺nuclear RNA, poly(A)^--nuclear RNA and polysomal RNA of chicken immature red blood cells was determined to be 0.86%, 20%, 0.42% and 1% respectively. As the poly(A)⁺-fraction comprises only about 2% of total nuclear RNA, globin coding sequences are distributed with 49% in the poly(A)⁺-fraction and with 51% in the poly(A)^--fraction.Part of the mRNA sequences which are found in liver are also transcribed in immature red blood cells. These sequences are enriched in poly(A)⁺-nuclear RNA as the globin coding sequences but their total amount in the poly(A)⁺-fraction is much smaller than in the poly(A)^--fraction.When nuclear RNA from immature red blood cells was translated in an ascites tumor cell-free system, 20% of the newly synthesized proteins were globin chains. The percentage of globin chains in the newly synthesized proteins increased to over 70% when poly(A)⁺-nuclear RNA was translated. Only about 7.5% of globin chains were found in proteins coded by poly(A)^--nuclear RNA.     

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.     

Quantitation of labeled globin messenger RNA by hybridization with excess complementary DNA covalently bound to cellulose.

A method is described to quantitate labeled globin mRNA by hybridization with excess cDNA which was enzymatically polymerized on oligo(dT)-cellulose. In a large excess of cDNA-cellulose the rate of RNA hybridization was dependent on DNA concentration and not on RNA concentration. Nonhybridized RNA can be digested by RNase and washed from the cDNA which is covalently bound to cellulose. This enables the detection of labeled globin mRNA even when present in a porportion as low as 0.02-0.03% of the total RNA.     

Ribonucleotide sequence homology among avian oncornaviruses.

RNA sequence relatedness among avian RNA tumor virus genomes was analyzed by inhibition of DNA-RNA hybrid formation between 3H-labeled 35S viral RNA and an excess of leukemic or normal chicken cell DNA with increasing concentrations of unlabeled 35S viral RNA. The avian viruses tested were Rous associated virus (RAV)-3, avian myeloblastosis virus (AMV), RAV-60, RAV-61, and B-77 sarcoma virus. Hybridization of 3H-labeled 35S AMV RNA with DNA from normal chicken cells was inhibited by unlabeled 35S RAV-0 RNA as effeciently (100%) as by unlabeled AMV RNA. Hybridization between 3H-labeled 35S AMV RNA and DNA from leukemic chicken myeloblasts induced by AMV was suppressed 100 and 68% by unlabeled 35S RNA from AMV and RAV-0, respectively. Hybridization between 3H-labeled RAV-0 and leukemic chicken myeloblast DNA was inhibited 100 and 67% by unlabeled 35S RNA from RAV-0 and AMV, respectively. It appears therefore that the AMV and RAV-0 genomes are 67 to 70% homologous and that AMV hybridizes to RAV-0 like sequences in normal chicken DNA. Hybridization between AMV RNA and leukemic chicken DNA was inhibited 40% by RNA from RAV-60 or RAV-61 and 50% by B-77 RNA. Hybridization between RAV-0 RNA and leukemic chicken DNA was inhibited 80% by RAV-60 or RAV-61 and 70% by B-77 RNA. Hybridization between 3H-labeled 35S RNA from RAV-60 or RAV-61 and leukemic chicken myeloblast DNA was reduced equally by RNA from RAV-60, RAV-61, AMV or RAV-0; this suggests that RNA from RAV-60 and RAV-61 hybridizes with virus-specific sequences in leukemic DNA which are shared by AMV, RAV-0, RAV-60, and RAV-61 RNA'S. Hybridization between 3H-labeled 35S RNA from RAV-61 and normal pheasant DNA was inhibited 100% by homologous viral RNA, 22 TO 26% BY RNA from AMV or RAV-0, and 30 to 33% by RNA from RAV-60 or B-77. Nearly complete inhibition of hybricization between RAV-0 RNA and leukemic chicken DNA by a mixture of AMV and B-77 35S RNAs indicates that the RNA sequences shared by B-77 virus and RAV-0. It appears that different avian RNA tumor virus genomes have from 50 to 80% homology in nucleotide sequences and that the degree of hybridization between normal chicken cell DNA and a given viral RNA can be predicted from the homology that exists between the viral RNA tested and RAV-0 RNA.     

Ribonucleotide Sequence Homology Among Avian Oncornaviruses

RNA sequence relatedness among avian RNA tumor virus genomes was analyzed by inhibition of DNA-RNA hybrid formation between ³H-labeled 35S viral RNA and an excess of leukemic or normal chicken cell DNA with increasing concentrations of unlabeled 35S viral RNA. The avian viruses tested were Rous associated virus (RAV)-0, avian myeloblastosis virus (AMV), RAV-60, RAV-61, and B-77 sarcoma virus. Hybridization of ³H-labeled 35S AMV RNA with DNA from normal chicken cells was inhibited by unlabeled 35S RAV-0 RNA as efficiently (100%) as by unlabeled AMV RNA. Hybridization between ³H-labeled 35S AMV RNA and DNA from leukemic chicken myeloblasts induced by AMV was suppressed 100 and 68% by unlabeled 35S RNA from AMV and RAV-0, respectively. Hybridization between ³H-labeled RAV-0 and leukemic chicken myeloblast DNA was inhibited 100 and 67% by unlabeled 35S RNA from RAV-0 and AMV, respectively. It appears therefore that the AMV and RAV-0 genomes are 67 to 70% homologous and that AMV hybridizes to RAV-0 like sequences in normal chicken DNA. Hybridization between AMV RNA and leukemic chicken DNA was inhibited 40% by RNA from RAV-60 or RAV-61 and 50% by B-77 RNA. Hybridization between RAV-0 RNA and leukemic chicken DNA was inhibited 80% by RAV-60 or RAV-61 and 70% by B-77 RNA. Hybridization between ³H-labeled 35S RNA from RAV-60 or RAV-61 and leukemic chicken myeloblast DNA was reduced equally by RNA from RAV-60, RAV-61, AMV or RAV-0; this suggests that RNA from RAV-60 and RAV-61 hybridizes with virus-specific sequences in leukemic DNA which are shared by AMV, RAV-0, RAV-60, and RAV-61 RNAs. Hybridization between ³H-labeled 35S RNA from RAV-61 and normal pheasant DNA was inhibited 100% by homologous viral RNA, 22 to 26% by RNA from AMV or RAV-0, and 30 to 33% by RNA from RAV-60 or B-77. Nearly complete inhibition of hybridization between RAV-0 RNA and leukemic chicken DNA by a mixture of AMV and B-77 35S RNAs indicates that the RNA sequences shared by B-77 virus and RAV-0 are different from the sequences shared by AMV and RAV-0. It appears that different avian RNA tumor virus genomes have from 50 to 80% homology in nucleotide sequences and that the degree of hybridization between normal chicken cell DNA and a given viral RNA can be predicted from the homology that exists between the viral RNA tested and RAV-0 RNA.     

Frequency distribution of messenger sequences within polysomal mRNA and nuclear RNA from rat liver.

DNA complementary to polysomal poly(A)-containing mRNA (cDNA) of male rat liver was used to study the diversity of messenger sequences in the nucleus and in polysomes. 1. Hybridization of cDNA against an excess of its own polysomal mRNA template revealed that about 10,000 different mRNA species are expressed in the liver tissue. They are distributed in a wide frequency range derived from approximately 0.5% of the total genome. 2. Hybridization of the cDNA against total nuclear RNA shows that messenger sequences comprise less than 1% of the mass of total nuclear RNA. Messenger sequences have a different frequency distribution in nucleus and cytoplasm. 3. In hybridizations using cDNA, which had been fractionated into sequences representing abundant and scarce polysomal mRNA molecules, it was found that although abundant cytoplasmic messenger sequences are also abundant in the nucleus, they exist in a significantly lower frequency range in the nuclear compartment.     

Chicken histone H5: selection of a cDNA recombinant using an extended synthetic primer

We describe the use of a synthetic primer to select a cDNA recombinant clone containing H5 coding sequences. The strategy used was as follows: 1. Prepare oligo(dT) cellulose-bound mRNA from chicken reticulocytes and select 11S-18S material from sucrose gradients. 2. Use this RNA fraction both to prepare a cDNA library and as a template for H5-specific cDNA synthesis using a synthetic primer. 3. Screen out most globin cDNA recombinants with oligo(dT)-primed globin cDNA. 4. Search for H5 recombinants using H5 specific cDNA and verify the identity by DNA sequencing. Our screening suggests an H5 mRNA abundance of about two parts per thousand in chicken reticulocyte poly(A)-containing RNA. The isolation of an H5 cDNA recombinant clone is an initial step in the study of H5 genes and their relationship to H1 and core histone genes.     

Cordycepin. An inhibitor of newly synthesized globin messenger RNA.

The effect of cordycepin (3'-deoxyadenosine) on newly synthesized globin mRNA in cultured mouse fetal liver erythroid cells is investigated. At cordycepin concentrations that do not inhibit amino acid incorporation into acid-precipitable material, the quantity of pulse-labeled (radioactive) globin mRNA nucleotide sequences is reduced by 90%, as compared to adenosine-treated controls. The reduction of radioactivity in globin-specific RNA sequences is greater than the inhibition of total RNA synthesis in experiments in which the labeling times range from 6 to 60 min. Control experiments demonstrate that cordycepin does not reduce the recovery of total cell RNA or steady state (unlabeled) globin mRNA. The hybridization assay used to detect radioactive globin mRNA sequences is independent of the cellular location or the number of 3'-terminal adenylate residues in the mRNA-containing molecules. These data thus indicate that cordycepin inhibits newly synthesized mRNA as effectively as it inhibits ribosomal and transfer RNA synthesis.     

Globin mRNA sequences in polyadenylated and nonpolyadenylated nuclear precursor-messenger RNA from avian erythroblasts

Nuclear RNA from immature duck erythrocytes was fractionated into polyadenylated and nonpolyadenylated fractions, and globin mRNA sequences were determined by hybridization to DNA complementary to globin mRNA.80–90% of labeled nuclear RNA is found to be nonpolyadenylated, and 70–80% of the globin mRNA sequences present in the nucleus are found in nonpolyadenylated molecules. These data suggest that polyadenylation does not specifically select for globin mRNA sequences.The nonpolyadenylated globin mRNA sequences present in the nucleus are found mostly in molecules of small size, close to the size of polyribosomal globin mRNA, suggesting that polyadenylation is a later event in globin mRNA formation.