Project description:A fundamental goal of genomics is to identify the complete set of expressed proteins. Automated annotation strategies rely on assumptions about protein-coding sequences (CDSs), e.g., they are conserved, do not overlap, and exceed a minimum length. However, an increasing number of newly discovered proteins violate these rules. Here we present an experimental and analytical framework, based on ribosome profiling and linear regression, for systematic identification and quantification of translation. Application of this approach to lipopolysaccharide-stimulated mouse dendritic cells and HCMV-infected human fibroblasts identifies thousands of novel CDSs, including micropeptides and variants of known proteins, that bear the hallmarks of canonical translation and exhibit comparable translation levels and dynamics to annotated CDSs. Remarkably, many translation events are identified in both mouse and human cells even when the peptide sequence is not conserved. Our work thus reveals an unexpected complexity to mammalian translation suited to provide both conserved regulatory or protein-based functions. 37 ribosome footprint samples from mouse BMDCs across a time course of LPS stimulation and in the presence or absence of translation inhibitors cycloheximide, harringtonine, or lactimidomycin. A mock (non-LPS stimulated) time course is also included, collected in the presence of cycloheximide. Two replicates are available for the LPS timecourse under CHX treatment.

Project description:A fundamental goal of genomics is to identify the complete set of expressed proteins. Automated annotation strategies rely on assumptions about protein-coding sequences (CDSs), e.g., they are conserved, do not overlap, and exceed a minimum length. However, an increasing number of newly discovered proteins violate these rules. Here we present an experimental and analytical framework, based on ribosome profiling and linear regression, for systematic identification and quantification of translation. Application of this approach to lipopolysaccharide-stimulated mouse dendritic cells and HCMV-infected human fibroblasts identifies thousands of novel CDSs, including micropeptides and variants of known proteins, that bear the hallmarks of canonical translation and exhibit comparable translation levels and dynamics to annotated CDSs. Remarkably, many translation events are identified in both mouse and human cells even when the peptide sequence is not conserved. Our work thus reveals an unexpected complexity to mammalian translation suited to provide both conserved regulatory or protein-based functions.

Project description:A regression-based analysis of ribosome-profiling data reveals a conserved complexity to mammalian translation

Project description:Brian Protein Deamidation Associated with Amyloidosis Revealed by Soluble and Amyloidal Brian Proteome Profiling

Project description:Jovanovic M,Rooney M, Mertins P, Przybylski D, Chevrier N, Satija R, Rodriguez EH, Fields AP, Schwartz S, Raychowdhury R, Mumbach M, Eisenhaure T, Rabani M, Gennert D, Lu D, Delorey T, Weissman JS, Carr SA, Hacohen N, Regev A, submitted 2015. Protein expression is regulated by production and degradation of mRNAs and proteins, but their specific relationships remain unknown. We combine measurements of protein production and degradation and mRNA dynamics to build a quantitative genomic model of the differential regulation of gene expression in LPS stimulated mouse dendritic cells. Changes in mRNA abundance play a dominant role in determining most dynamic fold changes in protein levels. Conversely, the preexisting proteome of proteins performing basic cellular functions is remodeled primarily through changes in protein production or degradation, accounting for over half of the absolute change in protein molecules in the cell. Thus, the proteome is regulated by transcriptional induction of novel cellular functions and remodeling of preexisting functions through the protein life cycle.

Project description:Elavl1/HuR is a ubiquitous and conserved RNA-binding protein that binds to a U-rich RNA motif that shuttles between nucleus and cytoplasm. In epithelia, the elevated expression of HuR assumingly promotes degeneration and cancer suggesting that its generic suppression may provide clinical benefits. In this study we focused on biological and clinical functions of HuR in intestinal epithelial cells and we presented evidence that changes in HuR levels induce polarized distortions in these cells to support different pathologic outcomes. For translation profiling cytoplasmic fractions of CMT93 sublines, containing monosomes and polysomes were separated as in (Katsanou et al., 2009). Fractions containing monosomes and polysomes were collected using a retriever 500 fraction collector (Teledyne Isco). Monosomal and polysomal fractions were pooled and total RNA was extracted from each fraction using Trizol reagent (Invitrogen). For micorarrays, RNAs were further purified via columns (Qiagen). Biotinylated complementary RNAs,(cRNAs) were hybridized onto Affymetrix Gene Mo-Gene-1.0 Chip in accordance to the protocols of the Genomics Unit of BSRC “Alexander Fleming”. (http://www.fleming.gr/facilities/genomics).

Project description:Gene expression analysis was performed in mouse models with Alexander disease associated GFAP mutations

Project description:HEK293T cells transduced with shRNA from MISSION library TRCN0000000185 using lentiviral delivery system. HEK293T cells transduced with scrambled shRNA, gifted from Dr. Mauricio Reginato. Tara L Davis, S. RaElle Jackson, Beth Adams, Anh Trinh, Jonathan Amora, Peter Naranjo, Gueil Wong-Shing, and Nii Martey performed primary experimental contributions to cell lines, RNA/cDNA preparation, and validation, all Drexel University College of Medicine, Philadelphia, PA. Hetty Rodriguez and John Tobias performed Bioanalyzer and microarray expreriments, and initial data processing. Affiliation: Molecular Profiling Facility and Genomic Analysis Core Bioinformatics Group, University of Pennsylvania, Philadelphia, PA. Human PPIL3 is a cyclophilin, an enzyme that interconverts cis and trans isomers of proline. PPIL3 associates with the human spliceosome, the complex and dynamic machinery that removes intronic sequence from pre-messenger RNA (pre-mRNA). Nothing is known about the function of PPIL3 in the nucleus. To understand the function of PPIL3, we knocked down PPIL3 in human cells. We characterized a set of alternative splicing and transcriptional events that are PPIL3-responsive. We used these splicing and transcriptional bioassays to show that PPIL3-responsive events are largely specific, even within the cyclophilin family.

Project description:This dataset represents woody plants recorded in 16 1-ha forest plots in an elevational gradient in Madidi National Park, Bolivia, ranging from lowland Amazonian moist forest and lowland dry forest to the treeline of the Andean Altiplano. This work was carried out by David Henderson and Jonathan Myers (Washington University in St. Louis), Sebastian Tello (Missouri Botanical Garden and University of Missouri, St. Louis), and Brian Sedio (University of Texas at Austin and Smithsonian Tropical Research Institute).

Project description:Olfactory bulb transcript levels for GFAP transgenic mice compared to wildtype at 3wks and 4mos Keywords = GFAP Keywords = Rosenthal fibers Keywords = Alexander disease Keywords: other