Project description:The normal functions of genomes depend on the precise expression of messenger RNAs and noncoding RNAs (ncRNAs) such as transfer RNAs and microRNAs in eukaryotes. These ncRNAs and functional RNA structures (FRSs) act as regulators or response elements for cellular factors and participate in transcription, posttranscriptional processing, and translation. Knowledge discovery of these FRSs in huge DNA/RNA sequence databases is a very important step to reach our goal of going from genomic sequence data to biological knowledge for understanding RNA-based regulation. Analyses of a large number of FRSs have indicated that the FRS can be well characterized by some quantitative measures such as significance and well-ordered scores of the local segment. Various data mining tools have been developed and successfully applied to FRS discovery in genomic sequence databases. Here, we summarize our efforts in the computational discovery of structured features of ncRNAs and FRSs within complex genomes by EDscan and SigED.

Project description:RNA performs a diverse array of important functions across all cellular life. These functions include important roles in translation, building translational machinery and maturing messenger RNA. More recent discoveries include the miRNAs and bacterial sRNAs that regulate gene expression, the thermosensors, riboswitches and other cis-regulatory elements that help prokaryotes sense their environment and eukaryotic piRNAs that suppress transposition. However, there can be a long period between the initial discovery of a RNA and determining its function. We present a bioinformatic approach to characterize RNA motifs, which are critical components of many RNA structure-function relationships. These motifs can, in some instances, provide researchers with functional hypotheses for uncharacterized RNAs. Moreover, we introduce a new profile-based database of RNA motifs--RMfam--and illustrate some applications for investigating the evolution and functional characterization of RNA. All the data and scripts associated with this work are available from: https://github.com/ppgardne/RMfam.

Project description:Pervasive transcriptional activity is observed across diverse species. The genomes of extant organisms have undergone billions of years of evolution, making it unclear whether these genomic activities represent effects of selection or ‘noise’1,2,3,4. Characterizing default genome states could help understand whether pervasive transcriptional activity has biological meaning. Here we addressed this question by introducing a synthetic 101-kb locus into the genomes of Saccharomyces cerevisiae and Mus musculus and characterizing genomic activity. The locus was designed by reversing but not complementing human HPRT1, including its flanking regions, thus retaining basic features of the natural sequence but ablating evolved coding or regulatory information. We observed widespread activity of both reversed and native HPRT1 loci in yeast, despite the lack of evolved yeast promoters. By contrast, the reversed locus displayed no activity at all in mouse embryonic stem cells, and instead exhibited repressive chromatin signatures. The repressive signature was alleviated in a locus variant lacking CpG dinucleotides; nevertheless, this variant was also transcriptionally inactive. These results show that synthetic genomic sequences that lack coding information are active in yeast, but inactive in mouse embryonic stem cells, consistent with a major difference in ‘default genomic states’ between these two divergent eukaryotic cell types, with implications for understanding pervasive transcription, horizontal transfer of genetic information and the birth of new genes.

Project description:Pervasive transcriptional activity is observed across diverse species. The genomes of extant organisms have undergone billions of years of evolution, making it unclear whether these genomic activities represent effects of selection or 'noise'1-4. Characterizing default genome states could help understand whether pervasive transcriptional activity has biological meaning. Here we addressed this question by introducing a synthetic 101-kb locus into the genomes of Saccharomyces cerevisiae and Mus musculus and characterizing genomic activity. The locus was designed by reversing but not complementing human HPRT1, including its flanking regions, thus retaining basic features of the natural sequence but ablating evolved coding or regulatory information. We observed widespread activity of both reversed and native HPRT1 loci in yeast, despite the lack of evolved yeast promoters. By contrast, the reversed locus displayed no activity at all in mouse embryonic stem cells, and instead exhibited repressive chromatin signatures. The repressive signature was alleviated in a locus variant lacking CpG dinucleotides; nevertheless, this variant was also transcriptionally inactive. These results show that synthetic genomic sequences that lack coding information are active in yeast, but inactive in mouse embryonic stem cells, consistent with a major difference in 'default genomic states' between these two divergent eukaryotic cell types, with implications for understanding pervasive transcription, horizontal transfer of genetic information and the birth of new genes.

Project description:Understanding default genome states would help interpret whether pervasive transcriptional activity has biological meaning. The genomes of extant organism have undergone billions of years of evolution, making it unclear whether observed genomic activities represent the effects of selection or “noise”. We addressed this question by introducing a novel 101-kb locus into the genomes of S. cerevisiae and M. musculus, and characterizing genomic activity. The locus was designed by reversing but not complementing human HPRT1, including substantial flank-ing regions, retaining basic sequence features but ablating evolved coding or regulatory infor-mation. We observed widespread activity of both reversed and native HPRT1 loci in yeast, de-spite the lack of evolved yeast promoters. In contrast, the reversed locus displayed no activity at all in mouse embryonic stem cells, instead showing repressive chromatin signatures. The re-pressive signature was alleviated in a locus variant lacking CpG dinucleotides; nevertheless this variant too was transcriptionally inactive. These results show that novel genomic sequences lacking coding information are active in yeast, but inactive in mouse embryonic stem cells, con-sistent with a major difference in “default genomic states” between these two divergent eukary-otic cell types, with implications for understanding pervasive transcription, horizontal transfer of genetic information, and new gene birth.

Project description:Understanding default genome states would help interpret whether pervasive transcriptional activity has biological meaning. The genomes of extant organism have undergone billions of years of evolution, making it unclear whether observed genomic activities represent the effects of selection or “noise”. We addressed this question by introducing a novel 101-kb locus into the genomes of S. cerevisiae and M. musculus, and characterizing genomic activity. The locus was designed by reversing but not complementing human HPRT1, including substantial flank-ing regions, retaining basic sequence features but ablating evolved coding or regulatory infor-mation. We observed widespread activity of both reversed and native HPRT1 loci in yeast, de-spite the lack of evolved yeast promoters. In contrast, the reversed locus displayed no activity at all in mouse embryonic stem cells, instead showing repressive chromatin signatures. The re-pressive signature was alleviated in a locus variant lacking CpG dinucleotides; nevertheless this variant too was transcriptionally inactive. These results show that novel genomic sequences lacking coding information are active in yeast, but inactive in mouse embryonic stem cells, con-sistent with a major difference in “default genomic states” between these two divergent eukary-otic cell types, with implications for understanding pervasive transcription, horizontal transfer of genetic information, and new gene birth.

Project description:Understanding default genome states would help interpret whether pervasive transcriptional activity has biological meaning. The genomes of extant organism have undergone billions of years of evolution, making it unclear whether observed genomic activities represent the effects of selection or “noise”. We addressed this question by introducing a novel 101-kb locus into the genomes of S. cerevisiae and M. musculus, and characterizing genomic activity. The locus was designed by reversing but not complementing human HPRT1, including substantial flank-ing regions, retaining basic sequence features but ablating evolved coding or regulatory infor-mation. We observed widespread activity of both reversed and native HPRT1 loci in yeast, de-spite the lack of evolved yeast promoters. In contrast, the reversed locus displayed no activity at all in mouse embryonic stem cells, instead showing repressive chromatin signatures. The re-pressive signature was alleviated in a locus variant lacking CpG dinucleotides; nevertheless this variant too was transcriptionally inactive. These results show that novel genomic sequences lacking coding information are active in yeast, but inactive in mouse embryonic stem cells, con-sistent with a major difference in “default genomic states” between these two divergent eukary-otic cell types, with implications for understanding pervasive transcription, horizontal transfer of genetic information, and new gene birth.

Project description:Understanding default genome states would help interpret whether pervasive transcriptional activity has biological meaning. The genomes of extant organism have undergone billions of years of evolution, making it unclear whether observed genomic activities represent the effects of selection or “noise”. We addressed this question by introducing a novel 101-kb locus into the genomes of S. cerevisiae and M. musculus, and characterizing genomic activity. The locus was designed by reversing but not complementing human HPRT1, including substantial flank-ing regions, retaining basic sequence features but ablating evolved coding or regulatory infor-mation. We observed widespread activity of both reversed and native HPRT1 loci in yeast, de-spite the lack of evolved yeast promoters. In contrast, the reversed locus displayed no activity at all in mouse embryonic stem cells, instead showing repressive chromatin signatures. The re-pressive signature was alleviated in a locus variant lacking CpG dinucleotides; nevertheless this variant too was transcriptionally inactive. These results show that novel genomic sequences lacking coding information are active in yeast, but inactive in mouse embryonic stem cells, con-sistent with a major difference in “default genomic states” between these two divergent eukary-otic cell types, with implications for understanding pervasive transcription, horizontal transfer of genetic information, and new gene birth.

Project description:Understanding default genome states would help interpret whether pervasive transcriptional activity has biological meaning. The genomes of extant organism have undergone billions of years of evolution, making it unclear whether observed genomic activities represent the effects of selection or “noise”. We addressed this question by introducing a novel 101-kb locus into the genomes of S. cerevisiae and M. musculus, and characterizing genomic activity. The locus was designed by reversing but not complementing human HPRT1, including substantial flank-ing regions, retaining basic sequence features but ablating evolved coding or regulatory infor-mation. We observed widespread activity of both reversed and native HPRT1 loci in yeast, de-spite the lack of evolved yeast promoters. In contrast, the reversed locus displayed no activity at all in mouse embryonic stem cells, instead showing repressive chromatin signatures. The re-pressive signature was alleviated in a locus variant lacking CpG dinucleotides; nevertheless this variant too was transcriptionally inactive. These results show that novel genomic sequences lacking coding information are active in yeast, but inactive in mouse embryonic stem cells, con-sistent with a major difference in “default genomic states” between these two divergent eukary-otic cell types, with implications for understanding pervasive transcription, horizontal transfer of genetic information, and new gene birth.

Project description:Post-transcriptional regulation of gene expression is often accomplished by proteins binding to specific sequence motifs in mRNA molecules, to affect their translation or stability. The motifs are often composed of a combination of sequence and structural constraints such that the overall structure is preserved even though much of the primary sequence is variable. While several methods exist to discover transcriptional regulatory sites in the DNA sequences of coregulated genes, the RNA motif discovery problem is much more difficult because of covariation in the positions. We describe the combined use of two approaches for RNA structure prediction, FOLDALIGN and COVE, that together can discover and model stem-loop RNA motifs in unaligned sequences, such as UTRs from post-transcriptionally coregulated genes. We evaluate the method on two datasets, one a section of rRNA genes with randomly truncated ends so that a global alignment is not possible, and the other a hyper-variable collection of IRE-like elements that were inserted into randomized UTR sequences. In both cases the combined method identified the motifs correctly, and in the rRNA example we show that it is capable of determining the structure, which includes bulge and internal loops as well as a variable length hairpin loop. Those automated results are quantitatively evaluated and found to agree closely with structures contained in curated databases, with correlation coefficients up to 0.9. A basic server, Stem-Loop Align SearcH (SLASH), which will perform stem-loop searches in unaligned RNA sequences, is available at http://www.bioinf.au.dk/slash/.