Abstract
The proteasome selectively degrades proteins. It consists of a core particle (CP), which contains proteolytic active sites that can associate with different regulators to form various complexes. How these different complexes are regulated and affected by changing physiological conditions, however, remains poorly understood. In this study, we focused on the activator Blm10 and the regulatory particle (RP). In yeast, increased expression of Blm10 outcompeted RP for CP binding, which suggests that controlling the cellular levels of Blm10 can affect the relative amounts of RP-bound CP. While strong overexpression of BLM10 almost eliminated the presence of RP-CP complexes, the phenotypes this should induce were not observed. Our results show this was due to the induction of Blm10-CP autophagy under prolonged growth in YPD. Similarly, under conditions of endogenous BLM10 expression, Blm10 was degraded through autophagy as well. This suggests that reducing the levels of Blm10 allows for more CP-binding surfaces and the formation of RP-CP complexes under nutrient stress. This work provides important insights into maintaining the proteasome landscape and how protein expression levels affect proteasome function.
Highlights
Most protein degradation in eukaryotic cells is performed by a large complex known as the proteasome
Besides regulatory particle (RP), several other complexes can associate with the same surface of core particle (CP) that is occupied by RP, namely the 11S activator (REGα-β and REGγ, a.k.a. as PA28αβ and PA28γ; not found in yeast), Pba1-Pba2/PAC1-PAC2, Blm10/PA200, and Fub1/PI31 [11, 13,14,15]
The ability to degrade ubiquitinated and folded proteins is dependent upon the interaction of CP with RP
Summary
Most protein degradation in eukaryotic cells is performed by a large complex known as the proteasome. The faster migrating species we observed at the bottom of the native gel in Figure 2C is not Blm10 bound to immature CP, but likely represents a small amount of free GFP derived from low levels of autophagy.
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