03503nas a2200709 4500008004100000022001400041245008200055210006900137260001500206300001600221490000700237520139500244653001201639653002301651653001801674653002301692653001001715653001901725653002201744653002501766653001801791653001301809653001101822653001301833653002301846653001301869653001001882100002401892700001801916700002601934700002501960700002101985700002102006700002602027700002002053700002902073700002302102700002902125700002602154700002002180700002702200700002702227700001802254700001902272700003002291700001802321700003402339700001902373700002902392700002702421700001902448700002502467700001702492700002802509700002802537700001902565700002202584700001902606700002002625710004302645856010502688 2021 eng d a1362-496200aCSVS, a crowdsourcing database of the Spanish population genetic variability.0 aCSVS a crowdsourcing database of the Spanish population genetic c2021 01 08 aD1130-D11370 v493 a
The knowledge of the genetic variability of the local population is of utmost importance in personalized medicine and has been revealed as a critical factor for the discovery of new disease variants. Here, we present the Collaborative Spanish Variability Server (CSVS), which currently contains more than 2000 genomes and exomes of unrelated Spanish individuals. This database has been generated in a collaborative crowdsourcing effort collecting sequencing data produced by local genomic projects and for other purposes. Sequences have been grouped by ICD10 upper categories. A web interface allows querying the database removing one or more ICD10 categories. In this way, aggregated counts of allele frequencies of the pseudo-control Spanish population can be obtained for diseases belonging to the category removed. Interestingly, in addition to pseudo-control studies, some population studies can be made, as, for example, prevalence of pharmacogenomic variants, etc. In addition, this genomic data has been used to define the first Spanish Genome Reference Panel (SGRP1.0) for imputation. This is the first local repository of variability entirely produced by a crowdsourcing effort and constitutes an example for future initiatives to characterize local variability worldwide. CSVS is also part of the GA4GH Beacon network. CSVS can be accessed at: http://csvs.babelomics.org/.
10aAlleles10aChromosome Mapping10aCrowdsourcing10aDatabases, Genetic10aExome10aGene Frequency10aGenetic Variation10aGenetics, Population10aGenome, Human10aGenomics10aHumans10aInternet10aPrecision Medicine10aSoftware10aSpain1 aPeña-Chilet, Maria1 aRoldán, Gema1 aPerez-Florido, Javier1 aOrtuno, Francisco, M1 aCarmona, Rosario1 aAquino, Virginia1 aLópez-López, Daniel1 aLoucera, Carlos1 aFernandez-Rueda, Jose, L1 aGallego, Asunción1 aGarcia-Garcia, Francisco1 aGonzález-Neira, Anna1 aPita, Guillermo1 aNúñez-Torres, Rocío1 aSantoyo-López, Javier1 aAyuso, Carmen1 aMinguez, Pablo1 aAvila-Fernandez, Almudena1 aCorton, Marta1 aMoreno-Pelayo, Miguel, Ángel1 aMorin, Matías1 aGallego-Martinez, Alvaro1 aLopez-Escamez, Jose, A1 aBorrego, Salud1 aAntiňolo, Guillermo1 aAmigo, Jorge1 aSalgado-Garrido, Josefa1 aPasalodos-Sanchez, Sara1 aMorte, Beatriz1 aCarracedo, Ángel1 aAlonso, Ángel1 aDopazo, Joaquin1 aSpanish Exome Crowdsourcing Consortium uhttp://clinbioinfosspa.es/content/csvs-crowdsourcing-database-spanish-population-genetic-variability03274nas a2200469 4500008004100000022001400041245010000055210006900155260001600224520184400240653001202084653000802096653001802104653002402122653001902146653000802165100002102173700001902194700001702213700002402230700002302254700002902277700002302306700002302329700002102352700001902373700002202392700003302414700002302447700001602470700002602486700002802512700002002540700002002560700002702580700002002607700002702627700001902654700002702673700002502700856007902725 2016 eng d a1537-171900a267 Spanish exomes reveal population-specific differences in disease-related genetic variation.0 a267 Spanish exomes reveal populationspecific differences in dise c2016 Jan 133 aRecent results from large-scale genomic projects suggest that allele frequencies, which are highly relevant for medical purposes, differ considerably across different populations. The need for a detailed catalogue of local variability motivated the whole exome sequencing of 267 unrelated individuals, representative of the healthy Spanish population. Like in other studies, a considerable number of rare variants were found (almost one third of the described variants). There were also relevant differences in allelic frequencies in polymorphic variants, including about 10,000 polymorphisms private to the Spanish population. The allelic frequencies of variants conferring susceptibility to complex diseases (including cancer, schizophrenia, Alzheimer disease, type 2 diabetes and other pathologies) were overall similar to those of other populations. However, the trend is the opposite for variants linked to Mendelian and rare diseases (including several retinal degenerative dystrophies and cardiomyopathies) that show marked frequency differences between populations. Interestingly, a correspondence between differences in allelic frequencies and disease prevalence was found, highlighting the relevance of frequency differences in disease risk. These differences are also observed in variants that disrupt known drug binding sites, suggesting an important role for local variability in population-specific drug resistances or adverse effects. We have made the Spanish population variant server web page that contains population frequency information for the complete list of 170,888 variant positions we found publicly available (http://spv.babelomics.org/), We show that it if fundamental to determine population-specific variant frequencies in order to distinguish real disease associations from population-specific polymorphisms.10adisease10aNGS10apolymorphisms10aPopulation genomics10aprioritization10aSNP1 aDopazo, Joaquín1 aAmadoz, Alicia1 aBleda, Marta1 aGarcía-Alonso, Luz1 aAlemán, Alejandro1 aGarcia-Garcia, Francisco1 aRodriguez, Juan, A1 aDaub, Josephine, T1 aMuntané, Gerard1 aRueda, Antonio1 aVela-Boza, Alicia1 aLópez-Domingo, Francisco, J1 aFlorido, Javier, P1 aArce, Pablo1 aRuiz-Ferrer, Macarena1 aMéndez-Vidal, Cristina1 aArnold, Todd, E1 aSpleiss, Olivia1 aAlvarez-Tejado, Miguel1 aNavarro, Arcadi1 aBhattacharya, Shomi, S1 aBorrego, Salud1 aSantoyo-López, Javier1 aAntiňolo, Guillermo uhttps://mbe.oxfordjournals.org/content/early/2016/02/17/molbev.msw005.full02094nas a2200349 4500008004100000022001400041245011200055210006900167260000900236300001000245490000600255520101800261100002001279700003401299700002701333700002701360700002201387700002301409700002401432700002101456700001901477700002001496700002301516700002201539700001901561700003301580700002001613700002301633700002001656700002101676856004701697 2016 eng d a2041-172300aExtension of human lncRNA transcripts by RACE coupled with long-read high-throughput sequencing (RACE-Seq).0 aExtension of human lncRNA transcripts by RACE coupled with longr c2016 a123390 v73 aLong non-coding RNAs (lncRNAs) constitute a large, yet mostly uncharacterized fraction of the mammalian transcriptome. Such characterization requires a comprehensive, high-quality annotation of their gene structure and boundaries, which is currently lacking. Here we describe RACE-Seq, an experimental workflow designed to address this based on RACE (rapid amplification of cDNA ends) and long-read RNA sequencing. We apply RACE-Seq to 398 human lncRNA genes in seven tissues, leading to the discovery of 2,556 on-target, novel transcripts. About 60% of the targeted loci are extended in either 5’ or 3’, often reaching genomic hallmarks of gene boundaries. Analysis of the novel transcripts suggests that lncRNAs are as long, have as many exons and undergo as much alternative splicing as protein-coding genes, contrary to current assumptions. Overall, we show that RACE-Seq is an effective tool to annotate an organism’s deep transcriptome, and compares favourably to other targeted sequencing techniques.1 aLagarde, Julien1 aUszczynska-Ratajczak, Barbara1 aSantoyo-López, Javier1 aGonzalez, Jose, Manuel1 aTapanari, Electra1 aMudge, Jonathan, M1 aSteward, Charles, A1 aWilming, Laurens1 aTanzer, Andrea1 aHowald, Cédric1 aChrast, Jacqueline1 aVela-Boza, Alicia1 aRueda, Antonio1 aLópez-Domingo, Francisco, J1 aDopazo, Joaquin1 aReymond, Alexandre1 aGuigó, Roderic1 aHarrow, Jennifer uhttp://www.nature.com/articles/ncomms1233901158nas a2200313 4500008004100000245011100041210006900152260001600221490000600237100002000243700003400263700002700297700002700324700002200351700002400373700002500397700002100422700001900443700002000462700002300482700002200505700001900527700003300546700002000579700002300599700002000622700002100642856018100663 2016 eng d00aExtension of human lncRNA transcripts by RACE coupled with long-read high-throughput sequencing (RACE-Seq)0 aExtension of human lncRNA transcripts by RACE coupled with longr cJan-11-20160 v71 aLagarde, Julien1 aUszczynska-Ratajczak, Barbara1 aSantoyo-López, Javier1 aGonzalez, Jose, Manuel1 aTapanari, Electra1 aMudge, Jonathan, M.1 aSteward, Charles, A.1 aWilming, Laurens1 aTanzer, Andrea1 aHowald, Cédric1 aChrast, Jacqueline1 aVela-Boza, Alicia1 aRueda, Antonio1 aLopez-Domingo, Francisco, J.1 aDopazo, Joaquin1 aReymond, Alexandre1 aGuigó, Roderic1 aHarrow, Jennifer uhttp://www.nature.com/articles/ncomms12339http://www.nature.com/articles/ncomms12339.pdfhttp://www.nature.com/articles/ncomms12339.pdfhttp://www.nature.com/articles/ncomms1233902676nas a2200541 4500008004100000022001400041245013100055210006900186260000900255300000900264490000600273520115300279653001201432100002001444700002001464700001601484700001701500700002501517700001601542700002001558700001801578700002101596700001801617700002001635700002001655700002101675700001401696700001501710700001801725700001901743700002601762700002701788700002701815700001601842700001301858700002101871700002601892700001801918700001601936700001801952700001501970700001501985700001302000700001502013700001302028700001602041856007702057 2014 eng d a2041-172300aAssessing technical performance in differential gene expression experiments with external spike-in RNA control ratio mixtures.0 aAssessing technical performance in differential gene expression c2014 a51250 v53 aThere is a critical need for standard approaches to assess, report and compare the technical performance of genome-scale differential gene expression experiments. Here we assess technical performance with a proposed standard ’dashboard’ of metrics derived from analysis of external spike-in RNA control ratio mixtures. These control ratio mixtures with defined abundance ratios enable assessment of diagnostic performance of differentially expressed transcript lists, limit of detection of ratio (LODR) estimates and expression ratio variability and measurement bias. The performance metrics suite is applicable to analysis of a typical experiment, and here we also apply these metrics to evaluate technical performance among laboratories. An interlaboratory study using identical samples shared among 12 laboratories with three different measurement processes demonstrates generally consistent diagnostic power across 11 laboratories. Ratio measurement variability and bias are also comparable among laboratories for the same measurement process. We observe different biases for measurement processes using different mRNA-enrichment protocols.10aRNA-seq1 aMunro, Sarah, A1 aLund, Steven, P1 aPine, Scott1 aBinder, Hans1 aClevert, Djork-Arné1 aConesa, Ana1 aDopazo, Joaquin1 aFasold, Mario1 aHochreiter, Sepp1 aHong, Huixiao1 aJafari, Nadereh1 aKreil, David, P1 aLabaj, Paweł, P1 aLi, Sheng1 aLiao, Yang1 aLin, Simon, M1 aMeehan, Joseph1 aMason, Christopher, E1 aSantoyo-López, Javier1 aSetterquist, Robert, A1 aShi, Leming1 aShi, Wei1 aSmyth, Gordon, K1 aStralis-Pavese, Nancy1 aSu, Zhenqiang1 aTong, Weida1 aWang, Charles1 aWang, Jian1 aXu, Joshua1 aYe, Zhan1 aYang, Yong1 aYu, Ying1 aSalit, Marc uhttp://www.nature.com/ncomms/2014/140925/ncomms6125/full/ncomms6125.html02364nas a2200265 4500008004100000022001400041245009900055210006900154260001300223300001100236490000600247520144900253100003301702700002801735700002701763700002201790700002301812700001901835700002401854700003201878700002001910700001901930700002501949856012401974 2014 eng d a2324-926900aDeciphering intrafamilial phenotypic variability by exome sequencing in a Bardet-Biedl family.0 aDeciphering intrafamilial phenotypic variability by exome sequen c2014 Mar a124-330 v23 aBardet-Biedl syndrome (BBS) is a model ciliopathy characterized by a wide range of clinical variability. The heterogeneity of this condition is reflected in the number of underlying gene defects and the epistatic interactions between the proteins encoded. BBS is generally inherited in an autosomal recessive trait. However, in some families, mutations across different loci interact to modulate the expressivity of the phenotype. In order to investigate the magnitude of epistasis in one BBS family with remarkable intrafamilial phenotypic variability, we designed an exome sequencing-based approach using SOLID 5500xl platform. This strategy allowed the reliable detection of the primary causal mutations in our family consisting of two novel compound heterozygous mutations in McKusick-Kaufman syndrome (MKKS) gene (p.D90G and p.V396F). Additionally, exome sequencing enabled the detection of one novel heterozygous NPHP4 variant which is predicted to activate a cryptic acceptor splice site and is only present in the most severely affected patient. Here, we provide an exome sequencing analysis of a BBS family and show the potential utility of this tool, in combination with network analysis, to detect disease-causing mutations and second-site modifiers. Our data demonstrate how next-generation sequencing (NGS) can facilitate the dissection of epistatic phenomena, and shed light on the genetic basis of phenotypic variability.
1 adel Pozo, María, González-1 aMéndez-Vidal, Cristina1 aSantoyo-López, Javier1 aVela-Boza, Alicia1 aBravo-Gil, Nereida1 aRueda, Antonio1 aGarcía-Alonso, Luz1 aVázquez-Marouschek, Carmen1 aDopazo, Joaquin1 aBorrego, Salud1 aAntiňolo, Guillermo uhttp://clinbioinfosspa.es/content/deciphering-intrafamilial-phenotypic-variability-exome-sequencing-bardet-biedl-family02250nas a2200241 4500008004100000245010000041210006900141300001200210490000600222520144700228100003301675700002801708700002701736700002201763700002301785700001901808700002401827700003201851700002101883700001901904700002501923856006001948 2014 eng d00aDeciphering intrafamilial phenotypic variability by exome sequencing in a Bardet–Biedl family0 aDeciphering intrafamilial phenotypic variability by exome sequen a124-1330 v23 aBardet–Biedl syndrome (BBS) is a model ciliopathy characterized by a wide range of clinical variability. The heterogeneity of this condition is reflected in the number of underlying gene defects and the epistatic interactions between the proteins encoded. BBS is generally inherited in an autosomal recessive trait. However, in some families, mutations across different loci interact to modulate the expressivity of the phenotype. In order to investigate the magnitude of epistasis in one BBS family with remarkable intrafamilial phenotypic variability, we designed an exome sequencing–based approach using SOLID 5500xl platform. This strategy allowed the reliable detection of the primary causal mutations in our family consisting of two novel compound heterozygous mutations in McKusick–Kaufman syndrome (MKKS) gene (p.D90G and p.V396F). Additionally, exome sequencing enabled the detection of one novel heterozygous NPHP4 variant which is predicted to activate a cryptic acceptor splice site and is only present in the most severely affected patient. Here, we provide an exome sequencing analysis of a BBS family and show the potential utility of this tool, in combination with network analysis, to detect disease-causing mutations and second-site modifiers. Our data demonstrate how next-generation sequencing (NGS) can facilitate the dissection of epistatic phenomena, and shed light on the genetic basis of phenotypic variability.1 adel Pozo, María, González-1 aMéndez-Vidal, Cristina1 aSantoyo-López, Javier1 aVela-Boza, Alicia1 aBravo-Gil, Nereida1 aRueda, Antonio1 aGarcía-Alonso, Luz1 aVázquez-Marouschek, Carmen1 aDopazo, Joaquín1 aBorrego, Salud1 aAntiňolo, Guillermo uhttp://onlinelibrary.wiley.com/doi/10.1002/mgg3.50/full01909nas a2200265 4500008004100000022001400041245007900055210006900134260001600203300001100219490000700230520106400237653001001301653001801311653004201329653001101371653002701382653001301409100003301422700002301455700001901478700002001497700002701517856009901544 2014 eng d a1367-481100angsCAT: a tool to assess the efficiency of targeted enrichment sequencing.0 angsCAT a tool to assess the efficiency of targeted enrichment se c2014 Jun 15 a1767-80 v303 aMOTIVATION: Targeted enrichment sequencing by next-generation sequencing is a common approach to interrogate specific loci or the whole exome in the human genome. The efficiency and the lack of bias in the enrichment process need to be assessed as a quality control step before performing downstream analysis of the sequence data. Tools that can report on the sensitivity, specificity, uniformity and other enrichment-specific features are needed.
RESULTS: We have implemented the next-generation sequencing data Capture Assessment Tool (ngsCAT), a tool that takes the information of the mapped reads and the coordinates of the targeted regions as input files, and generates a report with metrics and figures that allows the evaluation of the efficiency of the enrichment process. The tool can also take as input the information of two samples allowing the comparison of two different experiments.
AVAILABILITY AND IMPLEMENTATION: Documentation and downloads for ngsCAT can be found at http://www.bioinfomgp.org/ngscat.
10aExome10aGenome, Human10aHigh-Throughput Nucleotide Sequencing10aHumans10aSequence Analysis, DNA10aSoftware1 aLópez-Domingo, Francisco, J1 aFlorido, Javier, P1 aRueda, Antonio1 aDopazo, Joaquin1 aSantoyo-López, Javier uhttp://clinbioinfosspa.es/content/ngscat-tool-assess-efficiency-targeted-enrichment-sequencing02932nas a2200397 4500008004100000022001400041245010000055210006900155260001600224300000800240490000700248520172500255653001201980653001001992653001702002653002202019653002502041653001802066653001302084653001102097653002002108653001302128653001402141653002502155653002902180653002702209653001102236100002402247700002902271700003102300700002202331700002702353700002502380700002002405856010902425 2014 eng d a1744-429200aThe role of the interactome in the maintenance of deleterious variability in human populations.0 arole of the interactome in the maintenance of deleterious variab c2014 Sep 26 a7520 v103 aRecent genomic projects have revealed the existence of an unexpectedly large amount of deleterious variability in the human genome. Several hypotheses have been proposed to explain such an apparently high mutational load. However, the mechanisms by which deleterious mutations in some genes cause a pathological effect but are apparently innocuous in other genes remain largely unknown. This study searched for deleterious variants in the 1,000 genomes populations, as well as in a newly sequenced population of 252 healthy Spanish individuals. In addition, variants causative of monogenic diseases and somatic variants from 41 chronic lymphocytic leukaemia patients were analysed. The deleterious variants found were analysed in the context of the interactome to understand the role of network topology in the maintenance of the observed mutational load. Our results suggest that one of the mechanisms whereby the effect of these deleterious variants on the phenotype is suppressed could be related to the configuration of the protein interaction network. Most of the deleterious variants observed in healthy individuals are concentrated in peripheral regions of the interactome, in combinations that preserve their connectivity, and have a marginal effect on interactome integrity. On the contrary, likely pathogenic cancer somatic deleterious variants tend to occur in internal regions of the interactome, often with associated structural consequences. Finally, variants causative of monogenic diseases seem to occupy an intermediate position. Our observations suggest that the real pathological potential of a variant might be more a systems property rather than an intrinsic property of individual proteins.
10aAlleles10aExome10aGene Library10aGenetic Variation10aGenetics, Population10aGenome, Human10aGenomics10aHumans10aModels, Genetic10amutation10aPhenotype10aProtein Conformation10aProtein Interaction Maps10aSequence Analysis, DNA10aWhites1 aGarcía-Alonso, Luz1 aJiménez-Almazán, Jorge1 aCarbonell-Caballero, José1 aVela-Boza, Alicia1 aSantoyo-López, Javier1 aAntiňolo, Guillermo1 aDopazo, Joaquin uhttp://clinbioinfosspa.es/content/role-interactome-maintenance-deleterious-variability-human-populations03066nas a2200241 4500008004100000022001400041245015200055210006900207260000900276300001200285490000700297520223800304100002802542700003302570700002202603700002702625700003302652700003202685700002002717700001902737700002502756856004302781 2013 eng d a1090-053500aWhole-exome sequencing identifies novel compound heterozygous mutations in USH2A in Spanish patients with autosomal recessive retinitis pigmentosa.0 aWholeexome sequencing identifies novel compound heterozygous mut c2013 a2187-950 v193 aPURPOSE: Retinitis pigmentosa (RP) is an inherited retinal dystrophy characterized by extreme genetic and clinical heterogeneity. Thus, the diagnosis is not always easily performed due to phenotypic and genetic overlap. Current clinical practices have focused on the systematic evaluation of a set of known genes for each phenotype, but this approach may fail in patients with inaccurate diagnosis or infrequent genetic cause. In the present study, we investigated the genetic cause of autosomal recessive RP (arRP) in a Spanish family in which the causal mutation has not yet been identified with primer extension technology and resequencing. METHODS: We designed a whole-exome sequencing (WES)-based approach using NimbleGen SeqCap EZ Exome V3 sample preparation kit and the SOLiD 5500×l next-generation sequencing platform. We sequenced the exomes of both unaffected parents and two affected siblings. Exome analysis resulted in the identification of 43,204 variants in the index patient. All variants passing filter criteria were validated with Sanger sequencing to confirm familial segregation and absence in the control population. In silico prediction tools were used to determine mutational impact on protein function and the structure of the identified variants. RESULTS: Novel Usher syndrome type 2A (USH2A) compound heterozygous mutations, c.4325T>C (p.F1442S) and c.15188T>G (p.L5063R), located in exons 20 and 70, respectively, were identified as probable causative mutations for RP in this family. Family segregation of the variants showed the presence of both mutations in all affected members and in two siblings who were apparently asymptomatic at the time of family ascertainment. Clinical reassessment confirmed the diagnosis of RP in these patients. CONCLUSIONS: Using WES, we identified two heterozygous novel mutations in USH2A as the most likely disease-causing variants in a Spanish family diagnosed with arRP in which the cause of the disease had not yet been identified with commonly used techniques. Our data reinforce the clinical role of WES in the molecular diagnosis of highly heterogeneous genetic diseases where conventional genetic approaches have previously failed in achieving a proper diagnosis.1 aMéndez-Vidal, Cristina1 adel Pozo, María, González-1 aVela-Boza, Alicia1 aSantoyo-López, Javier1 aLópez-Domingo, Francisco, J1 aVázquez-Marouschek, Carmen1 aDopazo, Joaquin1 aBorrego, Salud1 aAntiňolo, Guillermo uhttp://www.molvis.org/molvis/v19/2187/01700nas a2200265 4500008004100000245004500041210004400086260000900130300001300139490000600152520096600158653000801124653001401132100002001146700001601166700002701182700002001209700002001229700002301249700001901272700001901291700002001310700002001330856008401350 2010 eng d00aInitial genomics of the human nucleolus.0 aInitial genomics of the human nucleolus c2010 ae10008890 v63 aWe report for the first time the genomics of a nuclear compartment of the eukaryotic cell. 454 sequencing and microarray analysis revealed the pattern of nucleolus-associated chromatin domains (NADs) in the linear human genome and identified different gene families and certain satellite repeats as the major building blocks of NADs, which constitute about 4% of the genome. Bioinformatic evaluation showed that NAD-localized genes take part in specific biological processes, like the response to other organisms, odor perception, and tissue development. 3D FISH and immunofluorescence experiments illustrated the spatial distribution of NAD-specific chromatin within interphase nuclei and its alteration upon transcriptional changes. Altogether, our findings describe the nature of DNA sequences associated with the human nucleolus and provide insights into the function of the nucleolus in genome organization and establishment of nuclear architecture.
10aNGS10anucleolus1 aNémeth, Attila1 aConesa, Ana1 aSantoyo-López, Javier1 aMedina, Ignacio1 aMontaner, David1 aPéterfia, Bálint1 aSolovei, Irina1 aCremer, Thomas1 aDopazo, Joaquin1 aLängst, Gernot uhttp://www.plosgenetics.org/article/info%3Adoi%2F10.1371%2Fjournal.pgen.100088900811nas a2200265 4500008004100000022001400041245005600055210005500111300001100166490000700177100002100184700002300205700002100228700002100249700002300270700002300293700001800316700001500334700002000349700002300369700002700392700001600419700002100435856008900456 2009 eng d a1557-810000aModeling and managing experimental data using FuGE.0 aModeling and managing experimental data using FuGE a239-510 v131 aJones, Andrew, R1 aLister, Allyson, L1 aHermida, Leandro1 aWilkinson, Peter1 aEisenacher, Martin1 aBelhajjame, Khalid1 aGibson, Frank1 aLord, Phil1 aPocock, Matthew1 aRosenfelder, Heiko1 aSantoyo-López, Javier1 aWipat, Anil1 aPaton, Norman, W uhttp://clinbioinfosspa.es/content/modeling-and-managing-experimental-data-using-fuge00979nas a2200325 4500008004100000020001400041245008100055210006900136260004400205300001400249490000600263653001900269653001500288653001000303100002300313700002200336700002200358700001800380700002200398700001700420700002700437700002100464700001700485700002100502700001700523700003100540700001800571700002300589856004100612 2009 eng d a1548-709100aStatistical methods for analysis of high-throughput RNA interference screens0 aStatistical methods for analysis of highthroughput RNA interfere bNature Publishing Groupc2009/08//print a569 - 5750 v610agene silencing10aregulation10asiRNA1 aBirmingham, Amanda1 aSelfors, Laura, M1 aForster, Thorsten1 aWrobel, David1 aKennedy, Caleb, J1 aShanks, Emma1 aSantoyo-López, Javier1 aDunican, Dara, J1 aLong, Aideen1 aKelleher, Dermot1 aSmith, Queta1 aBeijersbergen, Roderick, L1 aGhazal, Peter1 aShamu, Caroline, E uhttp://dx.doi.org/10.1038/nmeth.1351