Unraveling proteins at the single molecule level using nanopores

Laura Restrepo Perez

doi:10.4233/uuid:a431659a-da38-42a5-be17-05b8c241e355

Unraveling proteins at the single molecule level using nanopores

Laura Restrepo Perez

BN/Chirlmin Joo Lab

Research output: Thesis › Dissertation (TU Delft)

182 Downloads (Pure)

Abstract

The function and phenotype of a cell is determined by a complex network of interactions between DNA, RNA, proteins and metabolites. Therefore, a comprehensive approach that integrates genomics, transcriptomics, proteomics, and metabolomics is necessary to achieve full understanding of biological processes and disease. Recent technological developments have mostly focused on the study of genomes. DNA sequencing has become fast, cheap, and ubiquitous. The study of other -omes, especially the proteome, remains expensive and time-consuming...

Original language	English
Awarding Institution	Delft University of Technology
Supervisors/Advisors	Dekker, C., Supervisor Joo, C., Supervisor
Award date	10 May 2019
Print ISBNs	978.90.8593.395.3
DOIs	https://doi.org/10.4233/uuid:a431659a-da38-42a5-be17-05b8c241e355
Publication status	Published - 2019

Keywords

Single-molecule protein
sequencing
protein fingerprinting
proteins
nanopores
post-translational modifications

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10.4233/uuid:a431659a-da38-42a5-be17-05b8c241e355

Thesis_LRPFinal published version, 16.3 MB

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title = "Unraveling proteins at the single molecule level using nanopores",

abstract = "The function and phenotype of a cell is determined by a complex network of interactions between DNA, RNA, proteins and metabolites. Therefore, a comprehensive approach that integrates genomics, transcriptomics, proteomics, and metabolomics is necessary to achieve full understanding of biological processes and disease. Recent technological developments have mostly focused on the study of genomes. DNA sequencing has become fast, cheap, and ubiquitous. The study of other -omes, especially the proteome, remains expensive and time-consuming...",

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AB - The function and phenotype of a cell is determined by a complex network of interactions between DNA, RNA, proteins and metabolites. Therefore, a comprehensive approach that integrates genomics, transcriptomics, proteomics, and metabolomics is necessary to achieve full understanding of biological processes and disease. Recent technological developments have mostly focused on the study of genomes. DNA sequencing has become fast, cheap, and ubiquitous. The study of other -omes, especially the proteome, remains expensive and time-consuming...

KW - Single-molecule protein

KW - sequencing

KW - protein fingerprinting

KW - proteins

KW - nanopores

KW - post-translational modifications

U2 - 10.4233/uuid:a431659a-da38-42a5-be17-05b8c241e355

DO - 10.4233/uuid:a431659a-da38-42a5-be17-05b8c241e355

M3 - Dissertation (TU Delft)

SN - 978.90.8593.395.3

ER -

Unraveling proteins at the single molecule level using nanopores

Abstract

Keywords

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