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.     

Retracted: Chemoresistance in gastric cancer is attributed to the overexpression of excision repair cross-complementing 1 (ERCC1) caused by microRNA-122 dysregulation

MicroRNAs are deemed as key regulators of gene expression. In particular, the elevated expression of excision repair cross-complementing 1 (ERCC1) significantly reduced the effectiveness of gastric cancer treatment by cisplatin (CDDP)-based therapies. In this paper, qRT-PCR and western blot were adopted to measure miR-122 and ERCC1 messenger RNA (mRNA) expression in all samples. Luciferase assay was carried out to verify the role of ERCC1 as a target of miR-122. The CCK-8 assay was carried out to study the effect of ERCC1 and miR-122 on cell survival and apoptosis. The results demonstrated that miR-122 expression was reduced in cisplatin-resistant gastric cancer. Using bioinformatic analysis, miR-122 was shown to target the 3′-UTR of human ERCC1. A dual-luciferase assay demonstrated that miR-122 downregulated ERCC1 expression, while the mutations in ERCC1 3′-UTR abolished its interaction with miR-122. Transfection of miR-122 mimics decreased the levels of ERCC1 mRNA and protein expression, while the transfection of miR-122 inhibitors increased the levels of both ERCC1 mRNA and protein expression. Furthermore, we found that overexpressed miR-122 promoted the proliferation of MKN74 cells and reduced their apoptotic by targeting ERCC1. In addition, the levels of miR-122 and ERCC1 were negatively correlated in gastric cancer samples. In summary, the reduced miR-122 expression may play an essential role in the induction of cisplatin-resistance by increasing ERCC1 expression.     

Poly(adenylic acid)-containing and -deficient messenger RNA of mouse liver

RNA was isolated and fractionated into poly(A)-containing and -deficient classes by oligo(dT) chromatography. Approximately 99% of the poly(A) material bound to the oligo(dT); that which did not bind contained substantially shorter poly(A) chains. All RNA fractions retained an ability to initiate cell-free translation, with the poly(A)-deficient fraction containing half the total translational activity, i.e., mRNA. Two-dimensional polyacrylamide gel analysis of the cell-free translation products revealed three classes of mRNA: 1, mRNA preferentially containing poly(A), including the abundant liver mRNA species; 2, poly(A)-deficient mRNA, including many mid- and low-abundant mRNAs exhibiting less than 10% contamination in the poly(A)-containing fraction fraction; and 3, bimorphic species of mRNA proportioned between both the poly(A)-containing and -deficient fractions. Poly(A)-containing and bimorphic mRNA classes were further characterized by cDNA hybridizations. The capacity of various RNA fractions to prime cDNA synthesis was determined. Compared to total RNA, the poly(A)-containing RNA retained 70% of the priming capacity, while 20% was found in the poly(A)-deficient fraction. Poly(A)-containing, poly(A)-deficient, and total RNA fractions were hybridized to cDNAs synthesized from (+)poly(A)RNA. Poly(A)-containing RNA hybridized with an average R0t 1/2 approximately 20 times faster than total RNA. Poly(A)-deficient RNA hybridized with an average R0t 1/2 approximately 3-4 times slower than total RNA. These R0t 1/2 shifts indicated that in excess of three-quarters of the total hybridizable RNA was recovered in the poly(A)-containing fraction and that less than one-quarter was recovered in the poly(A)-deficient RNA fraction. Abundancy classes were less distinct in heterologous hybridizations. In all cases the extent of hybridization was similar, indicating that while the amount of various mRNA species varied among the RNA fractions, most hybridizing species of RNA were present in each RNA fraction. cDNA to the abundant class of mRNAs was purified and hybridized to both (+)- and (-)poly(A)RNA. Messenger RNA corresponding to the more abundant species was enriched in the poly(A)-containing fraction at least 2-fold over the less abundant species of mRNA, with less than 10% of the abundant mRNAs appearing inthe poly(A)-deficient fraction.     

Direct isolation of poly(A)+ RNA from 4 M guanidine thiocyanate-lysed cell extracts using locked nucleic acid-oligo(T) capture

LNA oligonucleotides constitute a class of bicyclic RNA analogues having an exceptionally high affinity for their complementary DNA and RNA target molecules. We here report a novel method for highly efficient isolation of intact poly(A)+ RNA using an LNA-substituted oligo(dT) affinity ligand, based on the increased affinity of LNA-T for complementary poly(A) tracts. Poly(A)+ RNA was isolated directly from 4 M guanidine thiocyanate-lysed Caenorhabditis elegans worm extracts as well as from lysed human K562 and vincristine-resistant K562/VCR leukemia cells using LNA_2.T oligonucleotide as an affinity probe, in which every second thymidine was substituted by LNA thymidine. In accordance with the significantly increased stability of the LNA_2.T-A duplexes in 4 M GuSCN, we obtained a 30- to 50-fold mRNA yield increase using the LNA-substituted oligo(T) affinity probe compared with DNA-oligo(dT)-selected mRNA samples. The LNA_2.T affinity probe was, furthermore, highly efficient in isolation of poly(A)+ RNA in a low salt concentration range of 50-100 mM NaCl in poly(A) binding buffer, as validated by selecting the mRNA pools from total RNA samples extracted from different Saccharomyces cerevisiae strains, followed by northern blot analysis. Finally, we demonstrated the utility of the LNA-oligo(T)-selected mRNA in quantitative real-time PCR by analysing the relative expression levels of the human mdr1 multidrug resistance gene in the two K562 cell lines employing pre-validated Taqman assays. Successful use of the NH2-modified LNA_2.T probe in isolation of human mRNA implies that the LNA-oligo(T) method could be automated for streamlined, high throughput expression profiling by real-time PCR by covalently coupling the LNA affinity probe to solid, pre-activated surfaces, such as microtiter plate wells or magnetic particles.     

Isolation of rat liver albumin messenger RNA.

Rat liver albumin messenger RNA has been purified to apparent homogeneity by means of polysome immunoprecipitation and poly(U)-Sepharose affinity chromatography. Specific polysomes synthesizing albumin were separated from total liver polysomes through a double antibody technique which allowed isolation of a specific immunoprecipitate. The albumin-polysome immunoprecipitate was dissolved in detergent and the polysomal RNA was separated from protein by sucrose gradient centrifugation. Albumin mRNA was then separated from ribosomal RNA by affinity chromatography through the binding of poly(U)-Sepharose to the polyadenylate 3' terminus of the mRNA. Pure albumin mRNA migrated as an 18 S peak on 85% formamide-containing linear sucrose gradients and as a 22 S peak on 2.5% polyacrylamide gels in sodium dodecyl sulfate. It coded for the translation of authentic liver albumin when added to a heterologous protein-synthesizing cell-free system derived from either rabbit reticulocyte lysates or wheat germ extracts. Translation analysis in reticulocyte lysates indicated that albumin polysomes were purified approximately 9-fold from total liver polysomes, and that albumin mRNA was purified approximately 74-fold from albumin polysomal RNA. The total translation product in the mRNA-dependent wheat germ system, upon addition of the pure mRNA, was identified as authentic albumin by means of gel electrophoresis and tryptic peptide chromatography.