Circulating Proteasomes Are Functional and Have a Subtype Pattern Distinct from 20S Proteasomes in Major Blood Cells

doi:10.1373/clinchem.2006.072496

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Circulating Proteasomes Are Functional and Have a Subtype Pattern Distinct from 20S Proteasomes in Major Blood Cells

Annette Zoeger ¹, Michael Blau ¹, Karl Egerer ², Eugen Feist ², Burkhardt Dahlmann ¹^*

¹ Institut für Biochemie, Charité-Universitätsmedizin-Berlin, Berlin, Germany
² Klinik für Rheumatologie und Klinische Immunologie, Charité-Universitätsmedizin-Berlin, Berlin, Germany

^* To whom correspondence should be addressed. E-mail: burkhardt.dahlmann{at}charite.de.

Background: 20S proteasomes, the proteolytic core particlesof the major intracellular protein degradative pathway, arepotential disease markers because they are detectable in humanplasma as circulating proteasomes and their concentrations areincreased in patients suffering from various diseases. To investigatethe origin of circulating proteasomes, we compared some of theirfeatures with those of proteasomes isolated from major bloodcells.

Methods:We isolated circulating proteasomes from theplasma of 2 patients with rheumatoid arthritis and 2 with systemiclupus erythematosus and from human plasma from healthy donors.We purified the proteasomes to apparent homogeneity and thenused electron microscopy for imaging and chromatography forsubtype spectrum analysis. We compared subtype results withthose from 20S proteasomes purified from 4 major blood cellpopulations. We also tested proteasomes for enzymatic activityand immunosubunit content.

Results: Circulating proteasomesfrom plasma of healthy donors and from patients with autoimmunedisease were found to have the same size and shape as erythrocyteproteasomes, be proteolytically active, and contain standard-and immunosubunits. Chromatography revealed 6 circulating proteasomesubtype peaks in healthy donor plasma and 7 in patient donorplasma. Proteasomes from erythrocytes had 3 subtype peaks andthose of monocytes, T-lymphocytes, and thrombocytes each had5 different subtype peaks.

Conclusion: Circulating proteasomeswere intact and enzymatically active in plasma from healthydonors and from patients with autoimmune disease. Because thesubtype patterns of circulating proteasomes clearly differ fromthose of proteasomes from blood cells, these cells cannot beregarded as a major source of circulating proteasomes.

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General Clinical Chemistry

Circulating Proteasomes Are Functional and Have a Subtype Pattern Distinct from 20S Proteasomes in Major Blood Cells