In plasma membrane proteome research, contamination of the isolated plasma membrane fraction with proteins from other organelles is still a problem. Even if highly specific isolation methods are used, such as density gradient centrifugation combined with selective extraction, contaminating proteins cannot be completely removed. To solve this problem, a protocol for the isolation of highly pure plasma membrane fractions from rat liver and two different hepatocellular carcinoma cell lines was developed. Magnetic beads with immobilized mAb's against highly expressed membrane proteins were used for specific binding of membrane vesicles and their separation from other organelles. Isolated plasma membranes were further selectively solubilized with different reagents and analyzed by use of different methods, such as Western blotting, 1- and 2-DE, and MS. Purification and further selective solubilization was validated by use of mAb's against the marker integral plasma membrane protein carcinoembryonic antigen cell adhesion molecule 1, and identification of isolated proteins by MS. The method presented here minimizes contamination with other organelles and enables further identification of membrane proteins.
Inter-alpha inhibitor proteins (IaIp) are a family of structurally related serine protease inhibitors found in relatively high concentrations in human plasma. Recent studies have implicated a role for IaIp in sepsis, and have demonstrated their potential as biomarkers in sepsis and cancer. For characterization of isolated IaI proteins and contaminating proteins during the last steps of the purification process, SELDI-TOF MS and HPLC-ESI-MS/MS were used. After separation by SDS-PAGE or 2-DE, polypeptide bands of 80, 125 and 250 kDa were excised from gels and digested by trypsin. The tryptic peptides were analyzed by both MS methods. The main contamination during the purification process, a band of 80 kDa, contains mainly IaIp heavy chain (HC) H3. HC H1 and H2 were also found in this band. In addition, some vitamin K-dependent clotting factors and inhibitors and other plasma proteins were identified. The 125-kDa band, representing the pre-alpha inhibitor, was found to contain both bikunin and HC H3. The presence of other HC H1, H2 and the recently described HC H4 was also detected by SELDI-TOF MS. The presence of HC H1, H2, and H3 in the 125-kDa band was confirmed by ESI-MS/MS, but not the presence of the H4. Three polypeptides, H1 and H2 together with bikunin, were identified in the 250-kDa band, representing the ITI, by both MS techniques. Once again, the presence of H4 was detected in this band only by SELDI-TOF MS, but the number of corresponding peptides was still not sufficient for final identification of this polypeptide. The importance of the application of proteomic methods for the proper evaluation of therapeutic drugs based on human plasma is discussed.
Mitosis is a highly regulated process in which errors can lead to genomic instability, a hallmark of cancer. During this phase of the cell cycle, transcription is silent and RNA translation is inhibited. Thus, mitosis is largely driven by posttranslational modification of proteins, including phosphorylation, methylation, ubiquitination and sumoylation. Here, we show that protein acetylation is prevalent during mitosis. To identify proteins that are acetylated, we synchronized HeLa cells in early prometaphase and immunoprecipitated lysine-acetylated proteins with antiacetyl-lysine antibody. The immunoprecipitated proteins were identified by LC-ESI-MS/MS analysis. These include proteins involved in RNA translation, RNA processing, cell cycle regulation, transcription, chaperone function, DNA damage repair, metabolism, immune response and cell structure. Immunoprecipitation followed by Western blot analyses confirmed that two RNA processing proteins, eIF4G and RNA helicase A, and several cell cycle proteins, including APC1, anillin and NudC, were acetylated in mitosis. We further showed that acetylation of APC1 and NudC was enhanced by apicidin treatment, suggesting that their acetylation was regulated by histone deacetylase. Moreover, treating mitotic cells with apicidin or trichostatin A induced spindle abnormalities and cytokinesis failure. These studies suggest that protein acetylation/ deacetylation is likely an important regulatory mechanism in mitosis.
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