Sequences hybridizing to mRNA, oligo(dT) and dsRNA from pre-mRNA are contiguous in the cloned mouse DNA fragments.

Fragments from the DNA of mouse embryos produced by restriction endonucleases HindIII were cloned in pBR322 plasmid and examined for the ability to hybridize in situ with [32P] labeled cDNA synthesized from the polysomal poly(A)+mRNA template. Several of the selected clones were examined for the presence of specific sequences inside the cloned mouse DNA fragments by the blotting procedure of southern [1]. The data obtained indicate that the majority of the cloned mouse DNA fragments contained sequences hybridizing with cDNA, oligo(dT) and double-stranded regions from pre-mRNA. The results of hybridization experiments and double digestion with HindIII+HaeIII endonucleases provide evidence that these sequences could be contiguous in the given restriction DNA fragments.     

Molecular cloning of DNA complementary to mRNA of rat liver serine dehydratase

A cDNA clone containing sequences complementary to the mRNA cording for rat hepatic serine dehydratase was isolated to study the multihormonal regulation of this enzyme. Serine dehydratase mRNA was partially purified (50-fold enrichment, 8.2% of the total mRNA activity) from the liver of rats fed high protein diet by polysome immunoadsorption followed by oligo(dT)-cellulose column chromatography. This preparation was used as template for synthesis of cDNA. Double-stranded cDNA sequences were inserted into the plasmid pBR322 and cloned in Escherichia coli DH1. Of 860 transformants screened, 6 clones containing DNA complementary to serine dehydratase mRNA were identified by differential colony hybridization and hybrid-selected translation. The length of serine dehydratase mRNA was estimated to be 1,500 bases by Northern blot analysis. One cloned cDNA comprised about 1,000 base pairs, or 65% of the length of the mRNA. The amount of the mRNA was greatly increased in the liver of rats given high protein diet.     

Molecular cloning of DNA sequences complementary to rat liver glucose-6-phosphate dehydrogenase mRNA. Nutritional regulation of mRNA levels

The nutritional regulation of rat liver glucose-6-phosphate dehydrogenase was studied using a cloned DNA complementary to glucose-6-phosphate dehydrogenase mRNA. The recombinant cDNA clones were isolated from a double-stranded cDNA library constructed from poly(A+) RNA immunoenriched for glucose-6-phosphate dehydrogenase mRNA. Immunoenrichment was accomplished by adsorption of polysomes with antibodies directed against glucose-6-phosphate dehydrogenase in conjunction with protein A-Sepharose and oligo(dT)-cellulose chromatography. Poly(A+) RNA encoding glucose-6-phosphate dehydrogenase was enriched approximately 20,000-fold using these procedures. Double-stranded cDNA was synthesized from the immunoenriched poly(A+) RNA and inserted into pBR322 using poly(dC)-poly(dG) tailing. Escherichia coli MC1061 was transformed, and colonies were screened for glucose-6-phosphate dehydrogenase cDNA sequences by differential colony hybridization. Plasmid DNA was purified from clones which gave positive signals, and the identity of the glucose-6-phosphate dehydrogenase clones was verified by hybrid-selected translation. A collection of glucose-6-phosphate dehydrogenase cDNA plasmids with overlapping restriction maps was obtained. Northern blot analysis of rat liver poly(A+) RNA using nick-translated, 32P-labeled cDNA inserts revealed that the glucose-6-phosphate dehydrogenase mRNA is 2.3 kilobases in length. RNA blot analysis showed that refeeding fasted rats a high carbohydrate diet results in a 13-fold increase in the amount of hybridizable hepatic glucose-6-phosphate dehydrogenase mRNA which parallels the increase in enzyme activity. These results suggest that the nutritional regulation of hepatic glucose-6-phosphate dehydrogenase occurs at a pretranslational level.     

Molecular cloning of cDNAs for the nerve-cell specific phosphoprotein, synapsin I.

To provide access to synapsin I-specific DNA sequences, we have constructed cDNA clones complementary to synapsin I mRNA isolated from rat brain. Synapsin I mRNA was specifically enriched by immunoadsorption of polysomes prepared from the brains of 10-14 day old rats. Employing this enriched mRNA, a cDNA library was constructed in pBR322 and screened by differential colony hybridization with single-stranded cDNA probes made from synapsin I mRNA and total polysomal poly(A)+ RNA. This screening procedure proved to be highly selective. Five independent recombinant plasmids which exhibited distinctly stronger hybridization with the synapsin I probe were characterized further by restriction mapping. All of the cDNA inserts gave restriction enzyme digestion patterns which could be aligned. In addition, some of the cDNA inserts were shown to contain poly(dA) sequences. Final identification of synapsin I cDNA clones relied on the ability of the cDNA inserts to hybridize specifically to synapsin I mRNA. Several plasmids were tested by positive hybridization selection. They specifically selected synapsin I mRNA which was identified by in vitro translation and immunoprecipitation of the translation products. The established cDNA clones were used for a blot-hybridization analysis of synapsin I mRNA. A fragment (1600 bases) from the longest cDNA clone hybridized with two discrete RNA species 5800 and 4500 bases long, in polyadenylated RNA from rat brain and PC12 cells. No hybridization was detected to RNA from rat liver, skeletal muscle or cardiac muscle.     

Cloning of cDNA sequences for an Artemia salina hnRNP protein: evidence for conservation through evolution.

A cDNA clone was isolated for Artemia salina protein HD40, a component of heterogenous nuclear ribonucleoproteins. Enriched Artemia 15S poly(A)+ RNA was used as a template and double-stranded cDNA sequences were inserted into the Pst I restriction endonuclease site of E. coli plasmid pBR322. Recombinant colonies were analyzed by positive hybrid selection of poly(A)+ RNA that directs the synthesis of protein HD40 in an in vitro assay. In vitro translation of the mRNA selected by recombinant clone 87HD yields a protein that is immunoprecipitated by anti-HD40 antibodies and that comigrates with authentic HD40 on gel electrophoresis. Partial proteolysis of protein HD40 and the in vitro translated product selected by clone 87HD produces the same peptide patterns. The size of the cloned insert is about 820 bp. The length of HD40 mRNA as determined by Northern blot analysis, is about 1500 nucleotides. Southern blot analysis performed with DNA of different species (plant, avian, mammal) shows cross-hybridizing bands when probed with clone 87HD DNA suggesting that the HD40 gene is evolutionarily conserved.     

A micromethod for measuring the molar concentration of polyadenylated RNA in the presence of ribosomal RNA

A method has been developed for measuring the molar concentration of RNA and the mole fraction of polyadenylated RNA. Using known mixtures of globin mRNA and rRNA composed of 20 to 85% rRNA, the molar concentration of globin mRNA, a polyadenylated species, was determined in 45 min, with the consumption of less than 100 ng of total RNA. The technique is particularly well suited for determining the molar concentration of poly(A)+ RNA after chromatographic enrichment in columns of oligo(dT)-cellulose or poly(U)-Sepharose. The method makes possible the adoption of a molar standard.     

Interferon-induced 56,000 Mr protein and its mRNA in human cells: molecular cloning and partial sequence of the cDNA.

Treatment of responsive cells by interferons (IFNs) induces within a few hours a rise in the concentration of several proteins and mRNAs. In order to characterize these IFN-induced mRNA species, we have cloned in E. coli the cDNA made from a 17-18S poly(A)+ RNA of human fibroblastoid cells (SV80) treated with IFN-beta. We describe here a pBR322 recombinant plasmid (C56) which contains a 400 bp cDNA insert corresponding to a 18S mRNA species newly induced by IFN. The C56 mRNA codes for a 56,000 dalton protein easily detectable by hybridization-translation experiments. The sequence of 66 of the carboxy-terminal amino-acids of the protein can be deduced from the cDNA sequence. IFNs-alpha, beta or gamma are able to activate the expression of this gene in human fibroblasts as well as lymphoblastoid cells. The mRNA is not detectable without IFN; it reaches maximum levels (0.1% of the total poly(A)+ RNA) within 4-8 hrs and decreases after 16 hrs.     

Construction and characterization of a cDNA clone containing a portion of the bovine prolactin sequence.

Poly(A)-containing RNA from the bovine anterior pituitary has been used as a template for the enzymatic synthesis of double-stranded cDNA. The resulting double-stranded cDNA was inserted into the Pst I site of pBR322 with the oligo(dG)-oligo(dC) tailing technique and subsequently cloned in E. coli chi 1776. Clones containing sequences complementary to prolactin mRNA were identified by colony hybridization with partially purified prolactin cDNA. A 250 base pair sequence from one prolactin positive clone was extensively characterized and shown to contain the coding information for amino acids 119-192 of authentic bovine prolactin. The recombinant DNA from this clone was covalently attached to diazotized aminocellulose and used to purify prolactin mRNA from a mixture of mRNAs.     

The structure of cloned 3'-terminal RNA region of bovine leukemia virus (BLV)

cDNA synthesized on the bovine leukemia virus RNA template has been cloned in the pBR322 Pst I site. Colony hybridization with BLV RNA fragments and oligo (dT) has revealed a clone with cDNA insert containing 660 3'-terminal nucleotides of the BLV genome. The nucleotide sequence of the insert corresponding to U3 and R regions of the long terminal repeats (LTR) of viral genome has been determined. BLV U3, like U3 of other retroviruses, presumably contains promoter. The unusually long R region (about 230 bp), a certain homology with ATLV U3-R and some other structural features allow to group BLV LTR together with ATLV LTR in a separate class of retroviral LTR.