Li J, Gao X, Joss L, Rechsteiner M
Department of Biochemistry, University of Utah School of Medicine, Salt Lake City, UT, 84132, USA.
J Mol Biol. 2000 Jun 9;299(3):641-54. doi: 10.1006/jmbi.2000.3800.
The REG homologs, alpha, beta and gamma, activate mammalian proteasomes in distinct ways. REGalpha and REGbeta activate the trypsin-like, chymotrypsin-like and peptidylglutamyl-preferring active sites, whereas REGgamma only activates the proteasome's trypsin-like subunit. The three REG homologs differ in carboxyl-terminal sequences that are located next to activation loops on their proteasome binding surface. To assess the importance of these carboxyl-terminal sequences in the activation of specific proteasome beta catalytic subunits, we characterized chimeras in which 8 or 12 residues were exchanged among the three proteins. Like the wild-type molecule, REGalpha chimeras activated all three proteasome catalytic subunits regardless of the carboxyl-terminal sequence. However, REGalpha-beta chimeras activated the proteasome at lower concentrations than wild-type REGalpha and higher levels of REGalpha-gamma chimeras were needed for maximal activation because exchanged carboxyl-terminal sequences can stabilize (REGalpha-beta) or destabilize (REGalpha-gamma) the REGalpha heptamer. REGgamma chimeras were equivalent to REGgamma in their activation properties, but they bound the proteasome less tightly than the wild-type molecule. REGbeta chimeras also bound the proteasome more weakly than wild-type REGbeta and were virtually unable to activate it. Our findings demonstrate that the carboxyl-terminal sequences of REG subunits can affect heptamer stability and proteasome affinity, but they do not determine which proteasome beta subunits become activated.
REG 同源物α、β和γ以不同方式激活哺乳动物蛋白酶体。REGα和REGβ激活胰蛋白酶样、糜蛋白酶样和肽基谷氨酰胺偏好性活性位点,而REGγ仅激活蛋白酶体的胰蛋白酶样亚基。这三种REG同源物在其蛋白酶体结合表面上靠近激活环的羧基末端序列存在差异。为了评估这些羧基末端序列在特定蛋白酶体β催化亚基激活中的重要性,我们对三种蛋白质之间交换了8个或12个残基的嵌合体进行了表征。与野生型分子一样,REGα嵌合体无论羧基末端序列如何,均可激活所有三种蛋白酶体催化亚基。然而,REGα-β嵌合体在比野生型REGα更低的浓度下激活蛋白酶体,并且需要更高水平的REGα-γ嵌合体才能实现最大激活,因为交换的羧基末端序列可稳定(REGα-β)或破坏(REGα-γ)REGα七聚体。REGγ嵌合体在激活特性上与REGγ相当,但它们与蛋白酶体的结合比野生型分子更弱。REGβ嵌合体与蛋白酶体的结合也比野生型REGβ更弱,并且几乎无法激活它。我们的研究结果表明,REG亚基的羧基末端序列可影响七聚体稳定性和蛋白酶体亲和力,但它们并不能决定哪些蛋白酶体β亚基被激活。
