Project description:The high throughput characterization of protein N-termini is becoming an emerging challenge in the proteomics and proteogenomics fields. The present study describes the N-terminal oriented analysis of human mitochondria enriched samples by the trimethoxyphenyl phosphonium (TMPP) labeling approach (N-TOP and dN-TOP approaches (Gallien et al, 2009, Bertaccini et al. 2013)). The dN-TOP strategy based on a double light/heavy TMPP labeling has been optimized in order to improve and automate the workflow for efficient, fast and reliable high throughput N-terminome analysis.

Project description:The high throughput characterization of protein N-termini is becoming an emerging challenge in the proteomics and proteogenomics fields. The present study describes the N-terminal oriented analysis of human mitochondria enriched samples by the trimethoxyphenyl phosphonium (TMPP) labeling approach (N-TOP and dN-TOP approaches (Gallien et al, 2009, Bertaccini et al. 2013)). The dN-TOP strategy based on a double light/heavy TMPP labeling has been optimized in order to improve and automate the workflow for efficient, fast and reliable high throughput N-terminome analysis.

Project description:The high throughput characterization of protein N-termini is becoming an emerging challenge in the proteomics and proteogenomics fields. The present study describes the N-terminal oriented analysis of human mitochondria enriched samples by the trimethoxyphenyl phosphonium (TMPP) labeling approach (N-TOP and dN-TOP approaches (Gallien et al, 2009, Bertaccini et al. 2013)). The dN-TOP strategy based on a double light/heavy TMPP labeling has been optimized in order to improve and automate the workflow for efficient, fast and reliable high throughput N-terminome analysis.

Project description:Proteogenomic analysis of Methylobacterium extorquens DM4 using the dN-TOP strategy with heavy and light TMPP labelling

Project description:This study aims investigating the impact of rapamycin and zinc at subtoxic doses on the human mitochondrial proteome. Experiments were performed on U397 monocytic cells. A dN-TOP strategy, combining shotgun proteomics and N-terminomics, was applied to study both internal and N-terminal peptides of the mitochondrial proteins.

Project description:454 dataset for Hosia, et al. Torstensson et al. Dinasquet et al.

Project description:Finn Et al.

Project description:RNA-seq was performed using RNA extracted from blasted CD4+ T cells from individuals with TCF3 (haploinsufficiency [HI], null, or dominant negative [DN] mutations and healthy controls for the following study groups: healthy controls (HC, n=4) and patients with TCF3 mutations (HI=4, null=1, DN=1 ). Libraries were prepared using the AmpliSeq for Illumina Transcriptome Human Gene Expression panel. RNA-seq was performed on the Illumina HiSeq 2500 (Illumina; AmpliSeq for Illumina/HiSeq 2500). Demultiplexed reads were mapped to the hg19 genome using the splice-aware aligner Tophat (Trapnell et al., 2009). Gene-level counts data were generated using the Rsubread feature counts a read summarization program that counts mapped reads for genomic features such as genes (Liao et al., 2019). Differential expression analysis was performed using R (v.3.5.3) and DESeq2 (v.1.22.2)(Love et al., 2014).

Project description:The SELEX-seq platform was used to generate DNA-binding affinity predictions for the human Max transcription factor. This experiment was performed as part of a cross-validation study comparing the accuracy of DNA shape-augmented TF binding specificity models across two different platforms (SELEX-seq and gcPBM) Two rounds of SELEX were performed on Max protein as described in Slattery et al, Cell, 2011 (PMID 22153072). Briefly, His-tagged Max was incubated with a randomized 16mer oligonucleotide library (GTTCAGAGTTCTACAGTCCGACGATCTGG[ACGT]{16}CCAGAACTCGTATGCCGTCTTCTGCTTG). Max bound DNA was amplified and sequenced as described (Slattery et al, 2011).

Project description:Srikant et al. 2022