@article {49734, title = {Genomic variation. Impact of regulatory variation from RNA to protein.}, journal = {Science}, volume = {347}, year = {2015}, month = {2015 Feb 6}, pages = {664-7}, abstract = {

The phenotypic consequences of expression quantitative trait loci (eQTLs) are presumably due to their effects on protein expression levels. Yet the impact of genetic variation, including eQTLs, on protein levels remains poorly understood. To address this, we mapped genetic variants that are associated with eQTLs, ribosome occupancy (rQTLs), or protein abundance (pQTLs). We found that most QTLs are associated with transcript expression levels, with consequent effects on ribosome and protein levels. However, eQTLs tend to have significantly reduced effect sizes on protein levels, which suggests that their potential impact on downstream phenotypes is often attenuated or buffered. Additionally, we identified a class of cis QTLs that affect protein abundance with little or no effect on messenger RNA or ribosome levels, which suggests that they may arise from differences in posttranslational regulation.

}, keywords = {3{\textquoteright} Flanking Region, 5{\textquoteright} Flanking Region, Cell Line, Exons, Gene Expression Regulation, Genetic Variation, HUMANS, PHENOTYPE, Protein Biosynthesis, Quantitative Trait Loci, Ribosomes, RNA, Messenger, Transcription, Genetic}, issn = {1095-9203}, doi = {10.1126/science.1260793}, author = {Battle, Alexis and Khan, Zia and Wang, Sidney H and Mitrano, Amy and Ford, Michael J and Pritchard, Jonathan K and Gilad, Yoav} } @article {49727, title = {Haem oxygenase is synthetically lethal with the tumour suppressor fumarate hydratase.}, journal = {Nature}, volume = {477}, year = {2011}, month = {2011 Sep 8}, pages = {225-8}, abstract = {

Fumarate hydratase (FH) is an enzyme of the tricarboxylic acid cycle (TCA cycle) that catalyses the hydration of fumarate into malate. Germline mutations of FH are responsible for hereditary leiomyomatosis and renal-cell cancer (HLRCC). It has previously been demonstrated that the absence of FH leads to the accumulation of fumarate, which activates hypoxia-inducible factors (HIFs) at normal oxygen tensions. However, so far no mechanism that explains the ability of cells to survive without a functional TCA cycle has been provided. Here we use newly characterized genetically modified kidney mouse cells in which Fh1 has been deleted, and apply a newly developed computer model of the metabolism of these cells to predict and experimentally validate a linear metabolic pathway beginning with glutamine uptake and ending with bilirubin excretion from Fh1-deficient cells. This pathway, which involves the biosynthesis and degradation of haem, enables Fh1-deficient cells to use the accumulated TCA cycle metabolites and permits partial mitochondrial NADH production. We predicted and confirmed that targeting this pathway would render Fh1-deficient cells non-viable, while sparing wild-type Fh1-containing cells. This work goes beyond identifying a metabolic pathway that is induced in Fh1-deficient cells to demonstrate that inhibition of haem oxygenation is synthetically lethal when combined with Fh1 deficiency, providing a new potential target for treating HLRCC patients.

}, keywords = {Animals, Bilirubin, Cell Line, Cells, Cultured, Citric Acid Cycle, Computer simulation, Fumarate Hydratase, Fumarates, Genes, Lethal, Genes, Tumor Suppressor, Glutamine, Heme, Heme Oxygenase (Decyclizing), Kidney Neoplasms, Leiomyomatosis, Mice, Mitochondria, Mutation, NAD, Neoplastic Syndromes, Hereditary, Skin Neoplasms, Uterine Neoplasms}, issn = {1476-4687}, doi = {10.1038/nature10363}, author = {Frezza, Christian and Zheng, Liang and Folger, Ori and Rajagopalan, Kartik N and MacKenzie, Elaine D and Jerby, Livnat and Micaroni, Massimo and Chaneton, Barbara and Adam, Julie and Hedley, Ann and Kalna, Gabriela and Tomlinson, Ian P M and Pollard, Patrick J and Watson, Dave G and Deberardinis, Ralph J and Shlomi, Tomer and Ruppin, Eytan and Gottlieb, Eyal} } @article {49697, title = {Localization of sequences required for size-specific splicing of a small Drosophila intron in vitro.}, journal = {J Mol Biol}, volume = {253}, year = {1995}, month = {1995 Oct 27}, pages = {426-37}, abstract = {

Many introns in Drosophila and other invertebrates are less than 80 nucleotides in length, too small to be recognized by the vertebrate splicing machinery. Comparison of nuclear splicing extracts from human HeLa and Drosophila Kc cells has revealed species-specificity, consistent with the observed size differences. Here we present additional results with the 68 nucleotide fifth intron of the Drosophila myosin heavy chain gene. As observed with the 74 nucleotide second intron of the Drosophila white gene, the wild-type myosin intron is accurately spliced in a homologous extract, and increasing the size by 16 nucleotides both eliminates splicing in the Drosophila extract and allows accurate splicing in the human extract. In contrast to previous results, however, an upstream cryptic 5{\textquoteright} splice site is activated when the wild-type myosin intron is tested in a human HeLa cell nuclear extract, resulting in the removal of a 98 nucleotide intron. The size dependence of splicing in Drosophila extracts is also intron-specific; we noted that a naturally larger (150 nucleotide) intron from the ftz gene is efficiently spliced in Kc cell extracts that do not splice enlarged introns (of 84, 90, 150 or 350 nucleotides) derived from the 74 nucleotide white intron. Here, we have exploited that observation, using a series of hybrid introns to show that a region of 46 nucleotides at the 3{\textquoteright} end of the white intron is sufficient to confer the species-specific size effect. At least two sequence elements within this region, yet distinct from previously described branchpoint and pyrimidine tract signals, are required for efficient splicing of small hybrid introns in vitro.

}, keywords = {Animals, Base Sequence, Cell Line, DNA, Drosophila, Genes, Insect, HeLa Cells, HUMANS, Introns, Molecular Sequence Data, Myosin Heavy Chains, RNA Splicing, Species Specificity}, issn = {0022-2836}, doi = {10.1006/jmbi.1995.0564}, author = {Guo, M and Mount, S M} } @article {49698, title = {Suppressor U1 snRNAs in Drosophila.}, journal = {Genetics}, volume = {138}, year = {1994}, month = {1994 Oct}, pages = {365-78}, abstract = {

Although the role of U1 small nuclear RNAs (snRNAs) in 5{\textquoteright} splice site recognition is well established, suppressor U1 snRNAs active in intact multicellular animals have been lacking. Here we describe suppression of a 5{\textquoteright} splice site mutation in the Drosophila melanogaster white gene (wDR18) by compensatory changes in U1 snRNA. Mutation of positions -1 and +6 of the 5{\textquoteright} splice site of the second intron (ACG[GTGAGT to ACC]GTGAGC) results in the accumulation of RNA retaining this 74-nucleotide intron in both transfected cells and transgenic flies. U1-3G, a suppressor U1 snRNA which restores base-pairing at position +6 of the mutant intron, increases the ratio of spliced to unspliced wDR18 RNA up to fivefold in transfected Schneider cells and increases eye pigmentation in wDR18 flies. U1-9G, which targets position -1, suppresses wDR18 in transfected cells less well. U1-3G,9G has the same effect as U1-3G although it accumulates to lower levels. Suppression of wDR18 has revealed that the U1b embryonic variant (G134 to U) is active in Schneider cells and pupal eye discs. However, the combination of 9G with 134U leads to reduced accumulation of both U1b-9G and U1b-3G,9G, possibly because nucleotides 9 and 134 both participate in a potential long-range intramolecular base-pairing interaction. High levels of functional U1-3G suppressor reduce both viability and fertility in transformed flies. These results show that, despite the difficulties inherent in stably altering splice site selection in multicellular organisms, it is possible to obtain suppressor U1 snRNAs in flies.

}, keywords = {Alternative Splicing, Animals, Base Sequence, Cell Line, Cell Nucleus, DNA Primers, Drosophila melanogaster, Female, Genes, Suppressor, Genetic Variation, GENOTYPE, Introns, Male, Molecular Sequence Data, Mutagenesis, Site-Directed, Nucleic Acid Conformation, Oligodeoxyribonucleotides, PHENOTYPE, Recombinant Proteins, Ribonucleoprotein, U1 Small Nuclear, RNA, Small Nuclear, Transfection, Transformation, Genetic}, issn = {0016-6731}, author = {Lo, P C and Roy, D and Mount, S M} } @article {49721, title = {Are snRNPs involved in splicing?}, journal = {Nature}, volume = {283}, year = {1980}, month = {1980 Jan 10}, pages = {220-4}, keywords = {Animals, Base Sequence, Cell Line, Chickens, Erythrocytes, HUMANS, Liver, Lupus Erythematosus, Systemic, Molecular Weight, Nucleic Acid Precursors, Nucleoproteins, Ribonucleoproteins, RNA, Heterogeneous Nuclear, Species Specificity}, issn = {0028-0836}, author = {Lerner, M R and Boyle, J A and Mount, S M and Wolin, S L and Steitz, J A} }