Prefractionation techniques in proteome analysis: The mining tools of the third millennium

Righetti, Pier Giorgio; Castagna, Annalisa; Antonioli, Paolo; Boschetti, Egisto

doi:10.1002/elps.200406189

Cited by 263 publications

(182 citation statements)

References 151 publications

(113 reference statements)

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“…Membrane Versus Soluble Protein Abundance-Sample prefractionation has been extensively demonstrated to improve the resolution and detection of proteins (24). Here well characterized methods of separating the homogenized tissue into total membrane and soluble proteomes were tested for their applicability in the analysis of spinal cord segments (18).…”

Section: Discussionmentioning

confidence: 99%

“…size, density, and cellular localization), chemically (e.g. hydrophobicity, charge properties, and specific proteins), or otherwise defined fractions prior to resolving proteins in each of these separate fractions (24). Chief among the advantages of this approach is improved resolution and detection of low abundance proteins: many proteins that fall below detection sensitivity in separations of the total proteome are effectively concentrated by virtue of the sample prefractionation strategy and are thus detectable in an optimized separation of the defined fraction.…”

mentioning

confidence: 99%

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Enabling Coupled Quantitative Genomics and Proteomics Analyses from Rat Spinal Cord Samples

Butt

Pfeifer

Delaney

et al. 2007

Molecular & Cellular Proteomics

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Translational research is progressing toward combined genomics and proteomics analyses of small and precious samples. In our analyses of spinal cord material, we systematically evaluated disruption and extraction techniques to determine an optimum process for the coupled analysis of RNA and protein from a single 5-mm segment of tissue. Analyses of these distinct molecular species were performed using microarrays and high resolution two-dimensional gels, respectively. Comparison of standard homogenization with automated frozen disruption (AFD) identified negligible differences in the relative abundance of genes (44) with all genes identified by either process. Analysis on either the Affymetrix or Applied Biosystems Inc. gene array platforms provided good correlations between the extraction techniques. In contrast, the AFD technique enabled identification of more unique proteins from spinal cord tissue than did standard homogenization. Furthermore use of an optimized CHAPS/ urea extraction provided better protein recovery, as shown by quantitative two-dimensional gel analyses, than did solvent precipitation during TRIzol-based RNA extraction. Thus, AFD of tissue samples followed by protein and RNA isolation from separate aliquots of the frozen powdered sample is the most effective route to ensure full, quantitative analyses of both molecular entities.

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Enabling Coupled Quantitative Genomics and Proteomics Analyses from Rat Spinal Cord Samples

Butt

Pfeifer

Delaney

et al. 2007

Molecular & Cellular Proteomics

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“…[104]. The challenge is thus to reach the remaining proteome comprising only 1% of the plasma proteome [105]. Further complicating the study of the human plasma proteome are temporal and spatial dynamics.…”

Section: Searching Of Novel Cardiovascular Biomarkers In Plasma Proteomementioning

confidence: 99%

Vascular proteomics

Vivanco

Mas

Dardé

et al. 2007

Proteomics Clinical Apps

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The characterization of patients with acute coronary syndromes (ACS) at the molecular and cellular levels provides a novel vision for understanding the pathological and clinical expression of the disease. Recent advances in proteomic technologies permit the evaluation of systematic changes in protein expression in many biological systems and have been extensively applied to cardiovascular diseases (CVD). The cardiovascular system is in permanent intimate contact with blood, making blood-based biomarker discovery a particularly worthwhile approach. Thus, proteomics can potentially yield novel biomarkers reflecting CVD, establish earlier detection strategies, and monitor response to therapy. Here we review the different proteomic strategies used in the study of atherosclerosis and the novel proteins differentially expressed and secreted by atherosclerotic lesions which constitute novel potential biomarkers (HSP-27, Cathepsin D). Special attention is paid to MS-Imaging of atheroma plaque and the generation, for the first time, of 2-D images of lipids, showing the distribution of these molecules in the different areas of the atherosclerotic lesions. In addition new potential biomarkers have been identified in plasma (amyloid A1a, transtherytin), circulating cells (protein profile in monocytes from ACS patients) and individual cells constituents of atheroma plaques (endothelial, VSMC, macrophages) which provide novel insights into vascular pathophysiology.

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“…In combination with the visualization methods, sophisticated software is used for protein identification and quantification [14][15][16][17][18][19][20]. Separation is usually performed by 2-DE or multidimensional LC often following prefractionation of the original protein sample [21][22][23][24]. 2-DE comprises two steps (dimensions): separation of the proteins on the basis of differences in their net charge by IEF and separation of the focused proteins on the basis of differences in their molecular masses by SDS polyacrylamide gels [25][26][27][28].…”

Section: Proteomic Analysismentioning

confidence: 99%

Proteomics‐driven progress in neurodegeneration research

Fountoulakis

Κοσσίδα

2006

Electrophoresis

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Proteomics-driven progress in neurodegeneration researchProteomics technologies have been widely used in the investigation of neurodegenerative and psychiatric disorders, and in particular in the detection of differences between healthy individuals and patients suffering from such diseases. Thus, brain and cerebrospinal fluid (CSF) samples from patients with Alzheimer's disease, Down syndrome, Pick's disease, Parkinson's disease, schizophrenia, and other disorders as well as brain and CSF from animals serving as models of neurological disorders have been analyzed by proteomics. 2-DE followed by MALDI-TOF-MS has been mainly applied as this proteomics approach provides the possibility of convenient quantification of protein levels and detection of post-translational modifications. About 330 unique proteins with deranged levels and modifications have been detected by proteomics approaches to be related to neurodegeneration and psychiatric disorders. They are mainly involved in metabolism pathways, cytoskeleton formation, signal transduction, guidance, detoxification, transport, and conformational changes. In this article, we provide a summary of the major contributions of proteomics technologies in the study of neurodegenerative and psychiatric diseases, in particular, in the detection of changes in protein levels and modifications related to these disorders. IntroductionNeurodegeneration is a major hallmark of a series of genetic and acquired disorders of the central nervous system (CNS), like Alzheimer's disease (AD), Down syndrome (DS), Pick's disease, Creutzfeldt-Jakob disease (CJD), and Parkinson's disease, which result in severe cognitive and motor deficits. A common characteristic of these diseases is that they are multifactorial.Their molecular basis is unknown and individual biomarkers are not reliable. Genomics and proteomics approaches have been applied to obtain a better understanding of neurodegeneration and psychiatric disorders. Genomics has been used to map and identify genes that are mutated in a wide variety of such disorders, like presenilins in AD. Next to genomics, which only provides a partial view of the biological problem, proteomics is widely used in clinical diagnosis as well and many changes in protein levels associated with specific diseases have been identified [1,2].Proteomics is a technology-driven science that studies the proteins of the various biological systems, their structures, interactions, post-translational modifications, and in particular the changes in their levels and modifications, which are the result of specific diseases or are induced by external factors.

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Prefractionation techniques in proteome analysis: The mining tools of the third millennium

Cited by 263 publications

References 151 publications

Enabling Coupled Quantitative Genomics and Proteomics Analyses from Rat Spinal Cord Samples

Enabling Coupled Quantitative Genomics and Proteomics Analyses from Rat Spinal Cord Samples

Vascular proteomics

Proteomics‐driven progress in neurodegeneration research

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