Project description:Integral membrane proteins display two major types of transmembrane structure, helical bundles and beta barrels. The main functional roles of transmembrane proteins are the transport of small molecules and cell signaling, and sometimes these two roles are coupled. For cytosolic, water-soluble proteins, signaling and regulatory functions are often carried out by intrinsically disordered regions. Our long range goal is to determine whether integral membrane proteins likewise use disordered regions for signaling and regulation. Here we carried out a systematic bioinformatics investigation of intrinsically disordered regions obtained from integral membrane proteins for which crystal structures have been determined, and for which the intrinsic disorder was identified as missing electron density. We found 120 disorder-containing integral membrane proteins having a total of 33675 residues, with 3209 of the residues distributed among 240 different disordered regions. These disordered regions were compared with those obtained from water-soluble proteins with regards to their amino acid compositional biases, and to the accuracies of various disorder predictors. The results of these analyses show that the disordered regions from helical bundle integral membrane proteins, those from beta barrel integral membrane proteins, and those from water soluble proteins all exhibit statistically distinct amino acid compositional biases. Despite these differences in composition, current algorithms make reasonably accurate predictions of disorder for these membrane proteins. Although the small size of the current data sets are limiting, these results suggest that developing new predictors that make use of data from disordered regions in helical bundles and beta barrels, especially as these datasets increase in size, will likely lead to significantly more accurate disorder predictions for these two classes of integral membrane proteins.

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:Growing recognition of the numerous, diverse and important roles played by non-coding RNA in all organisms motivates better elucidation of these cellular components. Comparative genomics is a powerful tool for this task and is arguably preferable to any high-throughput experimental technology currently available, because evolutionary conservation highlights functionally important regions. Conserved secondary structure, rather than primary sequence, is the hallmark of many functionally important RNAs, because compensatory substitutions in base-paired regions preserve structure. Unfortunately, such substitutions also obscure sequence identity and confound alignment algorithms, which complicates analysis greatly. This paper surveys recent computational advances in this difficult arena, which have enabled genome-scale prediction of cross-species conserved RNA elements. These predictions suggest that a wealth of these elements indeed exist.

Project description:Intracellular membraneless organelles and their myriad cellular functions have garnered tremendous recent interest. It is becoming well accepted that they form via liquid-liquid phase separation (LLPS) of protein mixtures (often including RNA), where the organelles correspond to a protein-rich droplet phase coexisting with a protein-poor bulk phase. The major protein components contain disordered regions and often also RNA-binding domains, and the disordered fragments on their own easily undergo LLPS. By contrast, LLPS for structured proteins has been observed infrequently. The contrasting phase behaviors can be explained by modeling disordered and structured proteins, respectively, as polymers and colloids. These physical models also provide a better understanding of the regulation of droplet formation by cellular signals and its dysregulation leading to diseases.

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: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.