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Project description:Here we investigated the degradation of mRNA and protein in 68 pairs of adjacent prostate tissue samples using RNA-seq and pressure cycling technology (PCT) coupled with SWATH mass spectrometry and developed a score, the Proteome Integrity Number (PIN), to quantify the extent of protein degradation in the samples.

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Project description:The control of mRNA stability plays a central role in regulating gene expression. In metazoans, the earliest stages of development are driven by maternally supplied mRNAs. The degradation of these maternal mRNAs is critical for promoting the maternal-to-zygotic transition of developmental programs, although the underlying mechanisms are poorly understood in vertebrates. Here, we characterized maternal mRNA degradation pathways in zebrafish using a transcriptome analysis and systematic reporter assays. Our data demonstrate that ORFs enriched with uncommon codons promote deadenylation by the CCR4-NOT complex in a translation-dependent manner. This codon-mediated mRNA decay is conditional on the context of the 3′ UTR, with long 3′ UTRs conferring resistance to deadenylation. These results indicate that the combined effect of codon usage and 3′ UTR length determines the stability of maternal mRNAs in zebrafish embryos. Our study thus highlights the codon-mediated mRNA decay as a conserved regulatory mechanism in eukaryotes. zebrafish embryonic mRNA profile at 2 different stages (2 hpf and 6 hpf) in wildtype and 3 additional conditions (miR-430 inhibition, RNApol II inhibition and CNOT7 inhibition) at 6 hpf. All experiments are performed as triplicates

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Project description:mRNA degradation is a critical aspect of gene expression which dictates mRNA steady-state levels in conjunction with transcription rate. Previous studies in other model organisms have demonstrated that enrichment of specific codons within the open reading frame (ORF) can influence mRNA stability, primarily by modulating translation elongation speed. Despite advancements in our understanding of mRNA stability regulation by microRNAs and 3'UTR-based factors in mammalian systems, the importance of other mRNA regions such as the ORF sequence on dictating cellular mRNA levels are incompletely understood. To characterize the effects of the coding sequence on mRNA decay in mammals, we analyzed mRNA stability in human and Chinese Hamster Ovary (Cricetulus griseus) cells by both global metabolic labeling and single-gene mRNA reporter transcription shutoffs. In agreement with previous studies, we observed that synonymous codon usage impacts mRNA stability in mammalian cells. Unexpectedly, we also found that amino acid content is a potent determinant of mRNA stability in humans and other mammalian species. Codon and amino acid effects on decay correlate with tRNA levels measured by tRNA-Seq or intracellular amino acid levels measured by HPLC, respectively. These results suggest that both tRNA and amino acid levels have complementary effects on regulation of mRNA stability in mammals, hinting at the possibility of dynamic control of mRNA levels via altered tRNA or amino acid levels.

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