BackgroundOnco-proteogenomics aims to understand how changes in a cancer's genome influences its proteome. One challenge in integrating these molecular data is the identification of aberrant protein products from mass-spectrometry (MS) datasets, as traditional proteomic analyses only identify proteins from a reference sequence database.MethodsWe established proteomic workflows to detect peptide variants within MS datasets. We used a combination of publicly available population variants (dbSNP and UniProt) and somatic variations in cancer (COSMIC) along with sample-specific genomic and transcriptomic data to examine proteome variation within and across 59 cancer cell-lines.ResultsWe developed a set of recommendations for the detection of var...
The Clinical Proteomic Tumor Analysis Consortium (CPTAC) has provided some of the most in-depth anal...
Abstract Background Most of newly discovered cancer b...
Recent advances in high-throughput technologies, such as tandem mass spectrometry (MS/MS) and next g...
Abstract Background Onco-proteogenomics aims to understand how changes in a cancer’s genome influenc...
Cancer is driven by the acquisition of somatic DNA lesions. Distinguishing the early driver mutation...
The identification of genetically encoded variants at the proteome level is an important problem in ...
Improvements in mass spectrometry (MS)-based peptide sequencing provide a new opportunity to determi...
This thesis describes the efforts of integrating nucleotide sequencing results with mass spectrometr...
An important aim of cancer proteomics is to understand how the cancer proteome, with all its variati...
The practice of data sharing in the proteomics field took off and quickly spread in recent years as ...
In about 90 % of cancer cases, the development of the disease is caused by the accumulation of mutat...
[[abstract]]Secreted proteins encoded by mutated genes (mutant proteins) are a particularly rich sou...
One of the best-established area within multi-omics is proteogenomics, whereby the underpinning tech...
The practice of data sharing in the proteomics field took off and quickly spread in recent years as ...
Cancer genome deviates significantly from the reference human genome, and thus a search against stan...
The Clinical Proteomic Tumor Analysis Consortium (CPTAC) has provided some of the most in-depth anal...
Abstract Background Most of newly discovered cancer b...
Recent advances in high-throughput technologies, such as tandem mass spectrometry (MS/MS) and next g...
Abstract Background Onco-proteogenomics aims to understand how changes in a cancer’s genome influenc...
Cancer is driven by the acquisition of somatic DNA lesions. Distinguishing the early driver mutation...
The identification of genetically encoded variants at the proteome level is an important problem in ...
Improvements in mass spectrometry (MS)-based peptide sequencing provide a new opportunity to determi...
This thesis describes the efforts of integrating nucleotide sequencing results with mass spectrometr...
An important aim of cancer proteomics is to understand how the cancer proteome, with all its variati...
The practice of data sharing in the proteomics field took off and quickly spread in recent years as ...
In about 90 % of cancer cases, the development of the disease is caused by the accumulation of mutat...
[[abstract]]Secreted proteins encoded by mutated genes (mutant proteins) are a particularly rich sou...
One of the best-established area within multi-omics is proteogenomics, whereby the underpinning tech...
The practice of data sharing in the proteomics field took off and quickly spread in recent years as ...
Cancer genome deviates significantly from the reference human genome, and thus a search against stan...
The Clinical Proteomic Tumor Analysis Consortium (CPTAC) has provided some of the most in-depth anal...
Abstract Background Most of newly discovered cancer b...
Recent advances in high-throughput technologies, such as tandem mass spectrometry (MS/MS) and next g...