Proteome analysis of a rat liver nuclear insoluble protein fraction and localization of a novel protein, ISP36, to compartments in the interchromatin space

Antibody-based analysis reveals "filamentous vs. non-filamentous" and "cytoplasmic vs. nuclear" crosstalk of cytoskeletal proteins

To uncover the molecular composition and dynamics of the functional scaffold for the nucleus, three fractions of biochemically-stable nuclear protein complexes were extracted and used as immunogens to produce a variety of monoclonal antibodies. Many helix-based cytoskeletal proteins were identified as antigens, suggesting their dynamic contribution to nuclear architecture and function. Interestingly, sets of antibodies distinguished distinct subcellular localization of a single isoform of certain cytoskeletal proteins; distinct molecular forms of keratin and actinin were found in the nucleus. Their nuclear shuttling properties were verified by the apparent nuclear accumulations under inhibition of CRM1-dependent nuclear export. Nuclear keratins do not take an obvious filamentous structure, as was revealed by non-filamentous cytoplasmic keratin-specific monoclonal antibody. These results suggest the distinct roles of the helix-based cytoskeletal proteins in the nucleus.

Proteomic and targeted analytical identification of BXDC1 and EBNA1BP2 as dynamic scaffold proteins in the nucleolus

The nuclear matrix has classically been assumed to be a solid structure coherently aligning nuclear components, but its real nature remains obscure. We separated the proteins in a ribonucleoprotein-containing nuclear matrix fraction of HeLa cells by reversed-phase HPLC followed by SDS-PAGE, and identified 83 proteins through peptide mass fingerprint (PMF) analysis. Many nucleolar proteins, classical nuclear matrix proteins, RNA binding proteins, cytoskeletal proteins and five uncharacterized proteins were identified in this fraction. Four of the latter proteins were localized to the cell nucleus, BXDC1 and EBNA1BP2 being especially localized to the nucleolus. Fluorescence recovery after photobleaching and RNAi knockdown analyses suggested that BXDC1 and EBNA1BP2 function in a dynamic scaffold for ribosome biogenesis.

Purification and proteomic analysis of a nuclear-insoluble protein fraction

We describe here a method for analyzing a rat liver nuclear-insoluble protein fraction to determine candidate proteins participating in nuclear architecture formation. Rat liver nuclei are purified by sucrose density gradient centrifugation. The purified nuclei are treated with DNase and RNase and then washed with high salt and detergent solutions. The residual nuclear-insoluble protein fraction is separated by reversed-phase high-performance liquid chromatography (HPLC) in 60% formic acid on a polystyrene resin column. This system allows good resolution and high recovery of most insoluble proteins, including intrinsic membrane proteins and even proteins larger than 140 kDa, with more than 70% recovery. The LC-fractionated proteins are further separated by sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE). Protein bands are excised, in-gel digested with trypsin, and then analyzed with a protein sequencer or mass spectrometer. Using this protocol, 138 were separated, 29 were identified, among which one appears as a novel nuclear constituent localized in the interchromatin space.