Project description:Synaptic function crucially depends on uninterrupted synthesis and degradation of synaptic proteins. While much has been learned on synaptic protein synthesis, little is known on the routes by which synaptic proteins are degraded. Here we systematically studied how inhibition of the ubiquitin-proteasomal system (UPS) affects the degradation rates of thousands of neuronal and synaptic proteins. We identified a number of proteins, including several proteins related to glutamate receptor trafficking, whose degradation rates were significantly slowed by UPS inhibition. Unexpectedly, however, degradation rates of most synaptic proteins were not significantly affected. Interestingly, many of the differential effects of UPS inhibition were readily explained by a quantitative framework that considered known metabolic turnover rates for the same proteins. In contrast to the limited effects on protein degradation, UPS inhibition profoundly and preferentially suppressed the synthesis of a large number of synaptic proteins. Our findings point to the importance of the UPS in the degradation of certain synaptic proteins, yet indicate that under basal conditions most synaptic proteins might be degraded through alternative pathways.

Project description:Synaptic function crucially depends on uninterrupted synthesis and degradation of synaptic proteins. While much has been learned on synaptic protein synthesis, little is known on the routes by which synaptic proteins are degraded. Here we systematically studied how inhibition of the ubiquitin-proteasomal system (UPS) affects the degradation rates of thousands of neuronal and synaptic proteins. We identified a number of proteins, including several proteins related to glutamate receptor trafficking, whose degradation rates were significantly slowed by UPS inhibition. Unexpectedly, however, degradation rates of most synaptic proteins were not significantly affected. Interestingly, many of the differential effects of UPS inhibition were readily explained by a quantitative framework that considered known metabolic turnover rates for the same proteins. In contrast to the limited effects on protein degradation, UPS inhibition profoundly and preferentially suppressed the synthesis of a large number of synaptic proteins. Our findings point to the importance of the UPS in the degradation of certain synaptic proteins, yet indicate that under basal conditions most synaptic proteins might be degraded through alternative pathways.

Project description:Homeostatic scaling adjusts synaptic strength in response to persistent changes in neuronal network activity. This compensatory mechanism requires proteome remodeling accomplished via regulation of protein synthesis as well as degradation, but the global patterns of proteome remodeling and the underlying dynamics of individual proteins remain elusive. Here we used dynamic SILAC labeling in cultured hippocampal cells to identify proteins involved in homeostatic up- or down-scaling and to quantify their changes in synthesis and degradation as well as resulting changes in protein abundance or turnover. Our data demonstrate that a large fraction of the neuronal proteome is remodeled during homeostatic scaling. Most proteins were down-regulated by decreased synthesis or up-regulated by decreased degradation. Comparably fewer proteins showed increased synthesis or degradation rates. More than half of the quantified synaptic proteins were regulated, including pre- as well as postsynaptic proteins with diverse molecular functions.

Project description:During the maternal-to-zygotic transition (MZT), maternal mRNAs and proteins are degraded, and zygotic genes are activated. We have previously shown that the ubiquitin-proteasome system (UPS) after fertilization plays a role in onset of zygotic transcription. However, the maternal proteins, which are degraded by UPS and can contribute to the zygotic transcription, have not been identified. Here, we identified PIASy (Protein inhibitor of activated STAT y), which is an E3 SUMO ligase, as the maternal proteins that were degraded via UPS after fertilization and by examining the overexpression of PIASy. We observed developmental arrest at the mouse 2-cell stage. Therefore, we examined the effect of PIASy overexpression on zygotic gene expression by using the RNA-sequencing analysis.

Project description:Steady-state RNA levels are a result of RNA synthesis and degradation. The importance of transcription-factor mediated induction or repression of mRNA synthesis is well established, but the role and mechanisms of RNA degradation are less well understood. We globally evaluated the RNA decay rates in proliferating and differentiated mouse myoblasts on whole-genome Affymetrix exon arrays, allowing for the assessment of directionality of RNA degradation and the detection of splice variant-specific differences in RNA decay rates. We found large differences in decay rates. mRNAs coding for proteins involved in signal transduction and transcriptional regulation have shortest half lives, whereas mRNAs coding for DNA replication enzymes and muscle contraction proteins are among the most stable. Many genes differentially expressed between proliferating and differentiated myoblasts demonstrate major differences in RNA decay rates. Quantitative PCR experiments confirmed the higher stability of transcripts with increased expression levels. RNA degradation has no apparent preferential directionality. RNA degradation appears to affect the ratio of different splice variants. For example, Itga7 isoforms with higher abundance in differentiated than in proliferating cells are more stable in differentiated cells, despite the sharing of a common 3’ untranslated region. Thus, where it was previously thought that the abundance of different splice isoforms was mainly controlled by tissue-specific splicing factors, we now demonstrate that isoforms may be produced at comparable levels but degraded with different efficiencies, depending on the differentiation status of the cells. Our results indicate that control of RNA degradation rates contributes significantly to the differentiation stage-dependent differences in abundance of transcripts and splice variants. Keywords: total RNA expression profiling; cultured cells We analyzed proliferating C2C12 cells and C2C12 cells differentiated into myotubes by serum starvation (8 days after induction of differentiation). We analyzed 7 time points after addition of actionmycin D (0, 10, 20, 30, 60, 150, 480 minutes). There were two biological replicates per condition.

Project description:Steady-state RNA levels are a result of RNA synthesis and degradation. The importance of transcription-factor mediated induction or repression of mRNA synthesis is well established, but the role and mechanisms of RNA degradation are less well understood. We globally evaluated the RNA decay rates in proliferating and differentiated mouse myoblasts on whole-genome Affymetrix exon arrays, allowing for the assessment of directionality of RNA degradation and the detection of splice variant-specific differences in RNA decay rates. We found large differences in decay rates. mRNAs coding for proteins involved in signal transduction and transcriptional regulation have shortest half lives, whereas mRNAs coding for DNA replication enzymes and muscle contraction proteins are among the most stable. Many genes differentially expressed between proliferating and differentiated myoblasts demonstrate major differences in RNA decay rates. Quantitative PCR experiments confirmed the higher stability of transcripts with increased expression levels. RNA degradation has no apparent preferential directionality. RNA degradation appears to affect the ratio of different splice variants. For example, Itga7 isoforms with higher abundance in differentiated than in proliferating cells are more stable in differentiated cells, despite the sharing of a common 3’ untranslated region. Thus, where it was previously thought that the abundance of different splice isoforms was mainly controlled by tissue-specific splicing factors, we now demonstrate that isoforms may be produced at comparable levels but degraded with different efficiencies, depending on the differentiation status of the cells. Our results indicate that control of RNA degradation rates contributes significantly to the differentiation stage-dependent differences in abundance of transcripts and splice variants. Keywords: total RNA expression profiling; cultured cells

Project description:Ubiquitin-proteasome system (UPS) protein degradation regulates protein abundance and eliminates misfolded and damaged proteins from eukaryotic cells. Variation in UPS activity influences numerous cellular and organismal phenotypes. However, to what extent such variation results from individual genetic differences is almost entirely unknown. Here, we developed a statistically powerful mapping approach to characterize the genetic basis of variation in UPS activity. Using the yeast Saccharomyces cerevisiae, we systematically mapped genetic influences on the N-end rule, a UPS pathway that recognizes N-degrons, degradation-promoting signals in protein N-termini. We identified 149 genomic loci that influence UPS activity across the complete set of N-degrons. Resolving four loci to individual causal nucleotides identified regulatory and missense variants in ubiquitin system genes whose products process (NTA1), recognize (UBR1 and DOA10), and ubiquitinate (UBC6) cellular proteins. Each of these genes contained multiple causal variants and several individual variants had substrate-specific effects on UPS activity. A cis-acting promoter variant that modulates UPS activity by altering UBR1 expression also alters the abundance of 36 proteins without affecting levels of the corresponding mRNAs. Our results demonstrate that natural genetic variation shapes the full sequence of molecular events in protein ubiquitination and implicate genetic influences on the UPS as a prominent source of post-translational variation in gene expression.

Project description:We have used dietary administration of stable isotope labelled lysine to assess protein turnover rates for proteins from four tissues in the bank vole, Myodes glareolus. The annotated genome for this species is not available, so protein identification was attained through cross-species matching to the mouse. For proteins for which confident identifications were derived, the pattern of lysine incorporation over 40d was used to define the rate of synthesis of individual proteins in the four tissues. The data were heavily filtered to retain a very high quality data-set of turnover rates for 1088 proteins. Comparative analysis of the four tissues revealed different median rates of degradation (kidney: 0.099 per day; liver 0.136 per day; heart, 0.054 per day and skeletal muscle, 0.035 per day). These data were compared with protein degradation rates from other studies on intact animals or from cells in culture.

Project description:Mutations mimicking growth factor-induced proliferation and motility characterize aggressive subtypes of mammary tumors. To unravel novel players, we applied phosphoproteomics on untransformed mammary cells, which were pre-stimulated with the epidermal growth factor (EGF). This analysis identified ladinin-1 (LAD1), a hitherto poorly characterized protein, as a phosphor-effector of the EGF-to-ERK pathway. We report that LAD1 is essential for mammary cell proliferation and migration. LAD1 is transcriptionally induced, undergoes phosphorylation by EGF and partly co-localizes with actin stress fibers. Yeast 2-hybrids, proximity ligation and co-immunoprecipitation assays revealed that LAD1 binds with filamins, actin cross-linking proteins. Co-sedimentation analyses attribute to LAD1 a role in actin treadmilling, probably in collaboration with SFN/14-3-3sigma. Depletion of LAD1 led to a decrease in transcripts relevant to cell survival, and inhibited growth of mammary xenografts in an animal model. Furthermore, LAD1 is highly expressed in two aggressive subtypes of breast cancer, as well as predicts poor patient prognosis. This study identifies a new cytoskeletal component essential for cell migration and for the acquisition of oncogenic attributes by human mammary tumors.

Project description:Dissecting the myriad regulatory mechanisms controlling eukaryotic transcripts from production to degradation requires quantitative measurements of mRNA flow across the cell. We developed subcellular TimeLapse-seq to measure the rates at which RNAs are released from chromatin, exported from the nucleus, loaded onto polysomes, and degraded within the nucleus and cytoplasm. These rates varied substantially, yet transcripts from genes with related functions or targeted by the same transcription factors and RNA binding proteins flowed across subcellular compartments with similar kinetics. Verifying these associations uncovered roles for DDX3X and PABPC4 in nuclear export. For hundreds of genes, most transcripts were degraded within the nucleus, while the remaining molecules were exported and persisted with stable lifespans. Transcripts residing on chromatin for longer had extended poly(A) tails, whereas the reverse was observed for cytoplasmic mRNAs. Finally, a machine learning model identified additional molecular features that underlie the diverse life cycles of mammalian mRNAs.