Project description:To investigate how organisms mitigate the deleterious effects of mistranslation during evolution, a mutant tRNA was expressed in S. cerevisiae. The expression of Candida Ser-tRNACAG from a low copy plasmid in S. cerevisiae promoted mistranslation events by random incorporation of both serine and leucine at CUG codons. As mistranslation causes an overload of the protein quality pathways, it disrupts cellular protein homeostasis leading to a major fall in fitness. Laboratory evolutionary experiments were performed to study whether the fitness cost of mistranslation can be lowered. We also wanted to identify the cost-reduction strategy: reducing the frequencies of errors (mitigation), or increasing tolerance to errors (robustness), either by global or local activities.

Project description:Osteopontin vs empty vector

Project description:The leucine CUG codon was reassigned to serine in the fungal pathogen Candida albicans. To clarify the biological role of this tuneable codon ambiguity on drug resistance, we evolved C. albicans strains that were engineered to mistranslate the CUG codon at constitutively elevated levels, in the presence and absence of the antifungal drug fluconazole. Elevated levels of mistranslation resulted in the rapid acquisition of resistance to fluconazole.

Project description:We assessed the off-target effects of M2 expression on the leaf proteome of Nicotiana benthamiana infiltrated with the bacterial gene vector Agrobacterium tumefaciens. A iTRAQ quantitative proteomics procedure was followed to compare the leaf proteomes of plants agroinfiltrated with either an ‘empty’ vector or an M2-encoding vector. Leaves infiltrated with the empty vector had a low soluble protein content compared to non-infiltrated control leaves, associated with increased levels of stress-related proteins but decreased levels of photosynthesis-associated proteins. M2 expression partly compromised these effects of agroinfiltration to restore soluble protein content in leaf tissue, associated with restored levels of photosynthesis-associated proteins and reduced levels of stress-related proteins in the apoplast. These data illustrate the cell-wide influence of Golgi lumen pH homeostasis on the leaf proteome of N. benthamiana responding to microbial challenge.

Project description:Analysis of gene expression in mammary epithelial cells transduced with either hTERT, empty LXSN vector or empty BABE vector. Keywords: other

Project description:These data accompany our publication "RIT1 oncoproteins escape LZTR1-mediated proteolysis" (Castel P., et al. Science, 2019). Experiment 1: Identification of LZTR1 as an interacting partner of RIT1 Q Exactive Plus P20161208-02 FLAG GFP P20161208-03 FLAG RIT1 LTQ Orbitrap Velos V20170407-01 GST empty vector V20170407-03 GST RIT1 V20170407-06 HA empty vector V20170407-07 HA RIT1 Experiment 2: Identification of K135 and K187 ubiquitination sites in RIT1 Q Exactive Plus P20180408-01 FLAG-RIT1 / empty vector / empty vector (replicate 1) P20180408-02 FLAG-RIT1 / LZTR1 / empty vector (replicate 1) P20180408-03 FLAG-RIT1 / empty vector / TUBE (replicate 1) P20180408-04 FLAG-RIT1 / LZTR1 / TUBE (replicate 1) P20180408-06 GST-RIT1 / empty vector / empty vector (replicate 1) P20180408-07 GST-RIT1 / LZTR1 / empty vector (replicate 1) P20180408-08 GST-RIT1 / empty vector / TUBE (replicate 1) P20180408-09 GST-RIT1 / LZTR1 / TUBE (replicate 1) P20180408-11 GST-RIT1 / empty vector / empty vector (replicate 2) P20180408-12 GST-RIT1 / LZTR1 / empty vector (replicate 2) P20180408-13 GST-RIT1 / empty vector / TUBE (replicate 2) P20180408-14 GST-RIT1 / LZTR1 / TUBE (replicate 2) P20180408-16 FLAG-RIT1 / empty vector / empty vector (replicate 2) P20180408-17 FLAG-RIT1 / LZTR1 / empty vector (replicate 2) P20180408-18 FLAG-RIT1 / empty vector / TUBE (replicate 2) P20180408-32 FLAG-RIT1 / LZTR1 / TUBE (replicate 2)

Project description:Transfer RNAs (tRNAs) are the adaptor molecules required for reading of the genetic code and the accurate production of proteins. tRNA variants can lead to genome-wide mistranslation, the misincorporation of amino acids not specified by the standard genetic code, into nascent proteins. While genome sequencing has identified putative mistranslating tRNA variants in human populations, little is known regarding how mistranslation affects multicellular organisms. Here, we create a Drosophila melanogaster model for mistranslation by integrating a serine tRNA variant that mistranslates serine for proline (tRNA(Ser)[UGG, G26A]) into the fly genome. Using mass spectrometry, we find that tRNA(Ser)[UGG, G26A] misincorporates serine for proline at a frequency of ~ 0.6% per codon. This model will enable studies into the synergistic effects of mistranslating tRNA variants and disease-causing alleles.

Project description:5′ tRNA-fMet1 half (5′- CGCGGGGTGGAGCAGTCTGGTAGCTCGTCGGGCTC-3′) was cloned into the arabinose-inducible expression vector pMQ70. PA14 was transformed with the tRNA-fMet1 half expression vector or empty vector via electroporation. Characterization of the sRNA content of OMVs secreted by 5' tRNA-fMet1 half over-expression clone and empty vector control clone.

Project description:We sequenced mRNA from 6 human cell lines stably over-expressed specific gene or empty vector, and searched for differently expressed genes after gene over-expression as compared to empty vector.

Project description:SUM52PE cells were lentivirally transduced with PKLO empty vector control (Sigma SHC001 MISSION PLKO.1-PURO CONTROL VECTOR) or shRNA specific for C11orf67 (Sigma Clone ID: NM_024684.2-280s21c1 SHCLND-NM_024684 TRCN0000263814) in biological triplicates. Differentially regulated targets by the shRNA relative to empty vector control were determined.