Control track and group visibility more selectively below.
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| Base Position |
| Chromosome position in bases. (Clicks here zoom in 3x) |
| Global |
| Scanning Ribo-seq unique mappers from all studies |
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| Global Aggregate |
| Ribosome profiles from all studies |
| Albert 2014 |
| Genetic influences on translation in yeast. (Albert et al. 2014) |
| Archer 2016 |
| Dynamics of ribosome scanning and recycling revealed by translation complex profiling.(Archer et al. 2016) |
| Baudin-Baillieu 2014 |
| Ribosome profiles of elongating ribosomes from Sacchromyces cerevisiae [PSI+] and [psi-] strains (Baudin-Baillieu et al. 2014) |
| Beaupere17 |
| CAN1 Arginine Permease Deficiency Extends Yeast Replicative Lifespan via Translational Activation of Stress Response Genes. (Beaupere et al. 2017) |
| Brar 2012 |
| Ribosome profiles of elongating ribosomes from the yeast Saccharomyces cerevisiae during meiosis from traditional timecourse, strain ndt80, strain A14201, strain gb15 and strain mata/a (Brar et al. 2012) |
| Cai 2013 |
| Effects of the yeast RNA-binding protein Whi3 on the half-life and abundance of CLN3 mRNA and other targets. (Cai et al. 2013) |
| Dhungel 2015 |
| Parkinson's disease genes VPS35 and EIF4G1 interact genetically and converge on α-synuclein. (Dhungel et al. 2015) |
| Gerashchenko 2014 |
| Translation inhibitors cause abnormalities in ribosome profiling experiments. (Gerashchenko et al. 2014) |
| Gerashchenko 2016 |
| Ribonuclease selection for ribosome profiling. (Gerashchenko et al. 2016) |
| Gerashenko 2012 |
| Ribosome profiles of elongating ribosomes from the yeast Saccharomyces cerevisiae carried out under control conditions (without oxidative stress) and at 5 and 30 minutes of oxidative stress (Gerashenko et al. 2012) |
| Guydosh 14 |
| Dom34 rescues ribosomes in 3' untranslated regions.
(Guydosh et al. 14) |
| Ingolia 2009 |
| Ribosome profiles of elongating ribosomes from the yeast Saccharomyces cerevisiae carried out under both rich and starvation conditions (Ingolia et al. 2009) |
| Jungfleisch 2017 |
| A novel translational control mechanism involving RNA structures within coding sequences. (Jungfleisch et al. 2017) |
| Lareau 2014 |
| Distinct stages of the translation elongation cycle revealed by sequencing ribosome-protected mRNA fragments. (Lareau et al. 2014) |
| Nedialkova15 |
| Optimization of Codon Translation Rates via tRNA Modifications Maintains Proteome Integrity. (Nedialkova et al. 2015) |
| Nissley 2016 |
| Accurate prediction of cellular co-translational folding indicates proteins can switch from post- to co-translational folding (Nissley et al. 2016) |
| Pop 2014 |
| Ribosome profiles of elongating ribosomes from wild type yeast and in mutants with altered tRNA levels in physiological conditions (Pop et al. 2014) |
| Santos19 |
| Cycloheximide can distort measurements of mRNA levels and translation efficiency. (Santos et al. 2019) |
| Schmidt16 |
| The cryo-EM structure of a ribosome-Ski2-Ski3-Ski8 helicase complex. (Schmidt et al. 2016) |
| Sen 2015 |
| Genome-wide analysis of translational efficiency reveals distinct but overlapping functions of yeast DEAD-box RNA helicases Ded1 and eIF4A. (Sen et al. 2015) |
| Sen 2016 |
| eIF4B stimulates translation of long mRNAs with structured 5' UTRs and low closed-loop potential but weak dependence on eIF4G. (Sen et al. 2016) |
| Subtelny 2014 |
| Poly(A)-tail profiling reveals an embryonic switch in translational control. (Subtelny et al. 2014) |
| Thiaville 2016 |
| Global translational impacts of the loss of the tRNA modification t6A in yeast. (Thiaville et al. 2016) |
| Yerlikaya_2015 |
| Ribosome profilings of transcriptome and translatome in Saccharomyces cerevisiae (Yerlikaya et al. 2015) |
| Young 15 |
| Rli1/ABCE1 Recycles Terminating Ribosomes and Controls Translation Reinitiation in 3'UTRs In Vivo.
(Young et al. 15) |
| Zid 2014 |
| Promoter sequences direct cytoplasmic localization and translation of mRNAs during starvation in yeast. (Zid et al. 2014) |
| Zinshteyn 2013 |
| Loss of a conserved tRNA anticodon modification perturbs cellular signaling. (Zinshteyn et al. 2013) |
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| Global Aggregate |
| Ribo-seq unique mappers from all studies |
| Albert 2014 |
| Genetic influences on translation in yeast. (Albert et al. 2014) |
| Baudin-Baillieu 2014 |
| Ribo-seq unique mappers from Sacchromyces cerevisiae [PSI+] and [psi-] strains (Baudin-Baillieu et al. 2014) |
| Beaupere17 |
| CAN1 Arginine Permease Deficiency Extends Yeast Replicative Lifespan via Translational Activation of Stress Response Genes. (Beaupere et al. 2017) |
| Brar 2012 |
| Ribo-seq unique mappers from the yeast Saccharomyces cerevisiae during meiosis from traditional timecourse, strain ndt80, strain A14201, strain gb15 and strain mata/a (Brar et al. 2012) |
| Cai 2013 |
| Effects of the yeast RNA-binding protein Whi3 on the half-life and abundance of CLN3 mRNA and other targets. (Cai et al. 2013) |
| Dhungel 2015 |
| Parkinson's disease genes VPS35 and EIF4G1 interact genetically and converge on α-synuclein. (Dhungel et al. 2015) |
| Gerashchenko 2014 |
| Translation inhibitors cause abnormalities in ribosome profiling experiments. (Gerashchenko et al. 2014) |
| Gerashchenko 2016 |
| Ribonuclease selection for ribosome profiling. (Gerashchenko et al. 2016) |
| Gerashenko 2012 |
| Ribo-seq unique mappers from the yeast Saccharomyces cerevisiae carried out under control conditions (without oxidative stress) and at 5 and 30 minutes of oxidative stress (Gerashenko et al. 2012) |
| Guydosh 14 |
| Dom34 rescues ribosomes in 3' untranslated regions.
(Guydosh et al. 14) |
| Ingolia 2009 |
| Ribo-seq unique mappers from the yeast Saccharomyces cerevisiae carried out under both rich and starved conditions (Ingolia et al. 2009) |
| Jungfleisch 2017 |
| A novel translational control mechanism involving RNA structures within coding sequences. (Jungfleisch et al. 2017) |
| Lareau 2014 |
| Distinct stages of the translation elongation cycle revealed by sequencing ribosome-protected mRNA fragments. (Lareau et al. 2014) |
| Nedialkova15 |
| Optimization of Codon Translation Rates via tRNA Modifications Maintains Proteome Integrity. (Nedialkova et al. 2015) |
| Nissley 2016 |
| Accurate prediction of cellular co-translational folding indicates proteins can switch from post- to co-translational folding (Nissley et al. 2016) |
| Pop 2014 |
| Ribo-seq unique mappers from wild type yeast and in mutants with altered tRNA levels in physiological conditions (Pop et al. 2014) |
| Santos19 |
| Cycloheximide can distort measurements of mRNA levels and translation efficiency. (Santos et al. 2019) |
| Schmidt16 |
| The cryo-EM structure of a ribosome-Ski2-Ski3-Ski8 helicase complex. (Schmidt et al. 2016) |
| Sen 2015 |
| Genome-wide analysis of translational efficiency reveals distinct but overlapping functions of yeast DEAD-box RNA helicases Ded1 and eIF4A. (Sen et al. 2015) |
| Sen 2016 |
| eIF4B stimulates translation of long mRNAs with structured 5' UTRs and low closed-loop potential but weak dependence on eIF4G. (Sen et al. 2016) |
| Subtelny 2014 |
| Poly(A)-tail profiling reveals an embryonic switch in translational control. (Subtelny et al. 2014) |
| Thiaville 2016 |
| Global translational impacts of the loss of the tRNA modification t6A in yeast. (Thiaville et al. 2016) |
| Yerlikaya_2015 |
| This track contains data from Ribosomal sequence experiments carried out by (Yerlikaya et al. 2015) |
| Young 15 |
| Rli1/ABCE1 Recycles Terminating Ribosomes and Controls Translation Reinitiation in 3'UTRs In Vivo.
(Young et al. 15) |
| Zid 2014 |
| Promoter sequences direct cytoplasmic localization and translation of mRNAs during starvation in yeast. (Zid et al. 2014) |
| Zinshteyn 2013 |
| Loss of a conserved tRNA anticodon modification perturbs cellular signaling. (Zinshteyn et al. 2013) |
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| Global aggregate |
| mRNA-seq unique mappers from all studies |
| Albert 2014 |
| Genetic influences on translation in yeast. (Albert et al. 2014) |
| Beaupere17 |
| CAN1 Arginine Permease Deficiency Extends Yeast Replicative Lifespan via Translational Activation of Stress Response Genes. (Beaupere et al. 2017) |
| Brar 2012 |
| mRNA-seq unique mappers from the yeast Saccharomyces cerevisiae during meiosis from traditional timecourse, strain ndt80, strain A14201, strain gb15 and strain mata/a (Brar et al. 2012) |
| Cai 2013 |
| Effects of the yeast RNA-binding protein Whi3 on the half-life and abundance of CLN3 mRNA and other targets. (Cai et al. 2013) |
| Gerashenko 2012 |
| mRNA-seq unique mappers from the yeast Saccharomyces cerevisiae carried out under control conditions (without oxidative stress) and at 5 and 30 minutes of oxidative stress (Gerashenko et al. 2012) |
| Guydosh 14 |
| Dom34 rescues ribosomes in 3' untranslated regions.
(Guydosh et al. 14) |
| Ingolia 2009 |
| mRNA-seq unique mappers from the yeast Saccharomyces cerevisiae carried out under both rich and starved conditions (Ingolia et al. 2009) |
| Jungfleisch 2017 |
| A novel translational control mechanism involving RNA structures within coding sequences. (Jungfleisch et al. 2017) |
| Nedialkova15 |
| Optimization of Codon Translation Rates via tRNA Modifications Maintains Proteome Integrity. (Nedialkova et al. 2015) |
| Pop 2014 |
| mRNA-seq unique mappers from wild type yeast and in mutants with altered tRNA levels in physiological conditions (Pop et al. 2014) |
| Santos19 |
| Cycloheximide can distort measurements of mRNA levels and translation efficiency. (Santos et al. 2019) |
| Schmidt16 |
| The cryo-EM structure of a ribosome-Ski2-Ski3-Ski8 helicase complex. (Schmidt et al. 2016) |
| Sen 2015 |
| Genome-wide analysis of translational efficiency reveals distinct but overlapping functions of yeast DEAD-box RNA helicases Ded1 and eIF4A. (Sen et al. 2015) |
| Sen 2016 |
| eIF4B stimulates translation of long mRNAs with structured 5' UTRs and low closed-loop potential but weak dependence on eIF4G. (Sen et al. 2016) |
| Subtelny 2014 |
| Poly(A)-tail profiling reveals an embryonic switch in translational control. (Subtelny et al. 2014) |
| Yerlikaya 2015 |
| mRNA unique coverage profiling in S.cerevisiae cell (Yerlikaya et al. 2015) |
| Young 15 |
| Rli1/ABCE1 Recycles Terminating Ribosomes and Controls Translation Reinitiation in 3'UTRs In Vivo.
(Young et al. 15) |
| Zid 2014 |
| Promoter sequences direct cytoplasmic localization and translation of mRNAs during starvation in yeast. (Zid et al. 2014) |
| Zinshteyn 2013 |
| Loss of a conserved tRNA anticodon modification perturbs cellular signaling. (Zinshteyn et al. 2013) |
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| Short Match |
| Perfect Matches to Short Sequence () |
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| NCBI RefSeq |
| RefSeq gene predictions from NCBI |
| SGD Genes |
| Protein-Coding Genes from Saccharomyces Genome Database |
| SGD Other |
| Other Features from Saccharomyces Genome Database |
| Ensembl Genes |
| Ensembl Genes |
| TIF-Seq |
| Transcript Isoform Sequencing |
| Conservation |
| 7 yeast Multiz Alignment & Conservation |
| Most Conserved |
| PhastCons Conserved Elements, 7 yeast Multiz Alignment |
| Simple Repeats |
| Simple Tandem Repeats by TRF |
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