2015
DOI: 10.3390/ijms16023537
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Proteomic Challenges: Sample Preparation Techniques for Microgram-Quantity Protein Analysis from Biological Samples

Abstract: Proteins regulate many cellular functions and analyzing the presence and abundance of proteins in biological samples are central focuses in proteomics. The discovery and validation of biomarkers, pathways, and drug targets for various diseases can be accomplished using mass spectrometry-based proteomics. However, with mass-limited samples like tumor biopsies, it can be challenging to obtain sufficient amounts of proteins to generate high-quality mass spectrometric data. Techniques developed for macroscale quan… Show more

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Cited by 246 publications
(200 citation statements)
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References 164 publications
(170 reference statements)
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“…In fact, sample losses become crippling with precipitation procedures from mass‐limited samples, as they make it challenging to obtain sufficient amounts of proteins to generate high‐quality MS data. To overcome this challenge, a microscale technique, that is, filter aided sample preparation (FASP), was applied to protocols A, B, and C, as it is particularly suited for low sample sizes (100 µg or lower) and still enables an excellent proteome coverage . We tested two FASP devices with different molecular weight cutoffs (10 and 30 kDa); however, both clogged due to the presence of “carbonaceous aerosols” that remain in solution after centrifugation; therefore, no data were obtained by the FASP method variations and no further modifications were tested on protocols A, B, and C.…”
Section: Resultsmentioning
confidence: 99%
“…In fact, sample losses become crippling with precipitation procedures from mass‐limited samples, as they make it challenging to obtain sufficient amounts of proteins to generate high‐quality MS data. To overcome this challenge, a microscale technique, that is, filter aided sample preparation (FASP), was applied to protocols A, B, and C, as it is particularly suited for low sample sizes (100 µg or lower) and still enables an excellent proteome coverage . We tested two FASP devices with different molecular weight cutoffs (10 and 30 kDa); however, both clogged due to the presence of “carbonaceous aerosols” that remain in solution after centrifugation; therefore, no data were obtained by the FASP method variations and no further modifications were tested on protocols A, B, and C.…”
Section: Resultsmentioning
confidence: 99%
“…Hence, in most LC-MS experiments, the proteins of interest are enzymatically digested, typically with trypsin, to produce smaller peptides to aid chromatographic separation prior to mass spectrometry and additionally the mass spectrometer is more sensitive to peptides than proteins. For a recent review of sample preparation for protein analysis in LC-MS see Feist and Hummon [12]. The sensitivity for a specific peptide, natural or derived from a protein by enzymatic digestion with an enzyme such as trypsin, or protein will vary.…”
Section: Liquid Chromatography-mass Spectrometry (Lc-ms)mentioning
confidence: 99%
“…The proteins in biological samples (e.g. biopsies, tissue extracts, body fluids) must be made accessible by lysis and extraction from the cells . Frequently detergent lysis (e.g.…”
Section: Sample Preparationmentioning
confidence: 99%
“…by Triton X‐100, Nonidet P‐40, Tween 20, Tween 80, octyl glycoside etc.) in combination with some mechanical stimulus that physically breaks the cells is applied . Once isolated, proteins in their native state are often insoluble.…”
Section: Sample Preparationmentioning
confidence: 99%
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