Identification of the goldfish 20S proteasome beta6 subunit bound to nuclear matrix

Mass spectrometric analysis of expression of ATPase subunits encoded by duplicated genes in the 19S regulatory particle of rice 26S proteasome

The 26S proteasome consisting of a 20S proteasome and a pair of 19S regulatory particles (RP) plays important roles in degradation of the ubiquitinated protein in eukaryotic cells. The RP consists of six different ATPase subunits and, at least, 11 non-ATPase subunits. In rice, we previously identified duplicated genes encoding four ATPase subunits, OsRpt1, OsRpt2, OsRpt4, and OsRpt5. In this study, the genomic sequences of all rice ATPase subunits were identified from the rice genome database and the genomic structure of ATPase subunit genes was determined. The rice RP was purified, and the ATPase subunit isoforms encoded by three pairs of duplicated genes, OsRpt2a/OsRpt2b, OsRpt4a/OsRpt4b, and OsRpt5a/OsRpt5b, were identified in RP by using electrospray ionization quadrupole time-of-flight mass spectrometry. The relative amounts and the expression patterns of these ATPase subunit isoforms in the bran were found to be different from those of the callus, suggesting the presence of multiform 19S regulatory particles engaged in the tissue-specific protein metabolism.

FRAP reveals that mobility of oestrogen receptor-alpha is ligand- and proteasome-dependent

Here we report the use of fluorescence recovery after photobleaching (FRAP) to examine the intranuclear dynamics of fluorescent oestrogen receptor-alpha (ER). After bleaching, unliganded ER exhibits high mobility (recovery t1/2 < 1 s). Agonist (oestradiol; E2) or partial antagonist (4-hydroxytamoxifen) slows ER recovery (t1/2 approximately 5-6 s), whereas the pure antagonist (ICI 182,780) and, surprisingly, proteasome inhibitors each immobilize ER to the nuclear matrix. Dual FRAP experiments show that fluorescent ER and SRC-1 exhibit similar dynamics only in the presence of E2. In contrast to reports that several nuclear proteins show uniform dynamics, ER exhibits differential mobility depending upon several factors that are linked to its transcription function.