Blue Native Polyacrylamide Gel Electrophoresis (blue + native_polyacrylamide_gel_electrophoresis)

Distribution by Scientific Domains
Life Sciences83%

Selected Abstracts

Low mutant load of mitochondrial DNA G13513A mutation can cause Leigh's disease

ANNALS OF NEUROLOGY, Issue 4 2003
Denise M. Kirby BSc(Hons)
Respiratory chain complex I deficiency is a common cause of Leigh's disease (LD) and can be caused by mutations in genes encoded by either nuclear or mitochondrial DNA (mtDNA). Most pathogenic mtDNA mutations act recessively and only cause disease when present at high mutant loads (typically >90%) in tissues such as muscle and brain. Two mitochondrial DNA mutations in complex I subunit genes, G14459A in ND6, and T12706C in ND5, have been associated with complex I deficiency and LD. We report another ND5 mutation, G13513A, in three unrelated patients with complex I deficiency and LD. The G13513A mutation was present at mutant loads of approximately 50% or less in all tissues tested, including multiple brain regions. The threshold mutant load for causing a complex I defect in cultured cells was approximately 30%. Blue Native polyacrylamide gel electrophoresis showed that fibroblasts with 45% G13513A mutant load had approximately 50% of the normal amount of fully assembled complex I. Fibroblasts with greater than 97% of the ND6 G14459A mutation had only 20% fully assembled complex I, suggesting that both mutations disrupt complex I assembly or turnover. We conclude that the G13513A mutation causes a complex I defect when present at unusually low mutant load and may act dominantly. [source]

Cover Picture: Electrophoresis 14'09

ELECTROPHORESIS, Issue 14 2009
Article first published online: 28 JUL 200
Issue no. 14 is an Emphasis Issue with 9 articles on various aspects of "Proteins and Proteomics" while the remaining 14 articles are arranged into 4 different parts including "Microfluidics and Miniaturization", "Genotyping and Transcriptomics", "Enantioseparations", and "Nanoparticles and Abused Drugs Analyses". Selected articles are: Effective elimination of nucleic acids from bacterial protein samples for optimized blue native polyacrylamide gel electrophoresis ((10.1002/elps.200900026)) 2-D difference in gel electrophoresis combined with Pro-Q Diamond staining: A successful approach for the identification of kinase/phosphatase targets ((10.1002/elps.200800780)) Microvalves actuated sandwich immunoassay on an integrated microfluidic system ((10.1002/elps.200800818)) Chemical gradient-mediated melting curve analysis for genotyping of SNPs ((10.1002/elps.200800729)) [source]

Effective elimination of nucleic acids from bacterial protein samples for optimized blue native polyacrylamide gel electrophoresis

ELECTROPHORESIS, Issue 14 2009
Jingdan Liang
Abstract Nucleic acids remaining within bacterial protein samples from Streptomyces lividans and Escherichia coli were found to interfere significantly with blue native polyacrylamide gel electrophoresis (BN-PAGE), a technique used frequently for analyzing bacterial protein complexes in proteomics studies. We have used ultracentrifugation and/or precipitation of cell lysates with streptomycin sulfate to eliminate nucleic acids from total and/or membrane protein samples. Nucleic acid-binding proteins were first enriched by precipitation with streptomycin sulfate, and contaminating nucleic acids were then eliminated by precipitation by adding polyethyleneimine. The performance of BN-PAGE was found to be dramatically improved by these sample preparation steps. [source]

Separation of nuclear protein complexes by blue native polyacrylamide gel electrophoresis

ELECTROPHORESIS, Issue 7 2006
Zora Nováková
Abstract The nucleus is a highly structured organelle with distinct compartmentalization of specific functions. To understand the functions of these nuclear compartments, detailed description of protein complexes which form these structures is of crucial importance. We explored therefore the potential of blue native PAGE (BN-PAGE) method for the separation of nuclear protein complexes. We focused on (i),solubility and stability of nuclear complexes under conditions prerequisite for the separation by BN-PAGE, (ii),improved separation of native nuclear protein complexes using 2-D colorless native/blue native PAGE (CN-/BN-PAGE), and (iii),mass spectrometric analysis of protein complexes which were isolated directly from native 1-D or from 2-D CN/BN-PAGE gels. The suitability of BN-PAGE for nuclear proteomic research is demonstrated by the successful separation of polymerase,I and polymerase,II complexes, and by mass spectrometric determination of U1 small nuclear ribonucleoprotein particle composition. Moreover, practical advice for sample preparation is provided. [source]

Low complex I content explains the low hydrogen peroxide production rate of heart mitochondria from the long-lived pigeon, Columba livia

AGING CELL, Issue 1 2010
Adrian J. Lambert
Summary Across a range of vertebrate species, it is known that there is a negative association between maximum lifespan and mitochondrial hydrogen peroxide production. In this report, we investigate the underlying biochemical basis of the low hydrogen peroxide production rate of heart mitochondria from a long-lived species (pigeon) compared with a short-lived species with similar body mass (rat). The difference in hydrogen peroxide efflux rate was not explained by differences in either superoxide dismutase activity or hydrogen peroxide removal capacity. During succinate oxidation, the difference in hydrogen peroxide production rate between the species was localized to the ,pH-sensitive superoxide producing site within complex I. Mitochondrial ,pH was significantly lower in pigeon mitochondria compared with rat, but this difference in ,pH was not great enough to explain the lower hydrogen peroxide production rate. As judged by mitochondrial flavin mononucleotide content and blue native polyacrylamide gel electrophoresis, pigeon mitochondria contained less complex I than rat mitochondria. Recalculation revealed that the rates of hydrogen peroxide production per molecule of complex I were the same in rat and pigeon. We conclude that mitochondria from the long-lived pigeon display low rates of hydrogen peroxide production because they have low levels of complex I. [source]