Abstract
SummaryProteasomes are multi-subunit protease complexes found in all domains of life. The maturation of the core particle (CP), which harbors the active sites, involves dimerization of two half CPs (HPs) and an autocatalytic cleavage that removes β propeptides. How these steps are regulated remains poorly understood. Here, we used the Rhodococcus erythropolis CP to dissect this process in vitro. Our data show that propeptides regulate the dimerization of HPs through flexible loops we identified. Furthermore, N-terminal truncations of the propeptides accelerated HP dimerization and decelerated CP auto-activation. We identified cooperativity in autocatalysis and found that the propeptide can be partially cleaved by adjacent active sites, potentially aiding an otherwise strictly autocatalytic mechanism. We propose that cross-processing during bacterial CP maturation is the underlying mechanism leading to the observed cooperativity of activation. Our work suggests that the bacterial β propeptide plays an unexpected and complex role in regulating dimerization and autocatalytic activation.
Highlights
Protein degradation is an essential cellular process required to maintain homeostasis and to allow the cell to react efficiently to changing environmental conditions
Our data show that propeptides regulate the dimerization of half CPs (HPs) through flexible loops we identified
We identified cooperativity in autocatalysis and found that the propeptide can be partially cleaved by adjacent active sites, potentially aiding an otherwise strictly autocatalytic mechanism
Summary
Protein degradation is an essential cellular process required to maintain homeostasis and to allow the cell to react efficiently to changing environmental conditions. The formation of CP involves the dimerization of two half CPs (the a7 b7 ‘‘Half Proteasome", here referred to as HP), and two distinct assembly pathways for the HP have been described. Common in eukaryotes and archaea, starts with the formation of an a subunit ring. The second, found mainly in bacteria, starts with dimerization of a and b subunits, which rapidly combine to form HP (Zuhl et al, 1997a, 1997b). Dimerization of the HP coincides with a proteolytic processing of some (eukaryotes) or all (archaea and bacteria) of the b subunits to form a proteolytically active CP (Becker and Darwin, 2017; Budenholzer et al, 2017; Kunjappu and Hochstrasser, 2014; Sharon et al, 2007)
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