Proteasome in action: substrate degradation by the 26S proteasome

Ubiquitination is the major criteria for the recognition of a substrate-protein by the 26S proteasome. Additionally, a disordered segment on the substrate — either intrinsic or induced — is critical for proteasome engagement. The proteasome is geared to interact with both of these substrate features and prepare it for degradation. To facilitate substrate accessibility, resting proteasomes are characterised by a peripheral distribution of ubiquitin receptors on the 19S regulatory particle (RP) and a wide-open lateral surface on the ATPase ring. In this substrate accepting state, the internal channel through the ATPase ring is discontinuous, thereby obstructing translocation of potential substrates. The binding of the conjugated ubiquitin to the ubiquitin receptors leads to contraction of the 19S RP. Next, the ATPases engage the substrate at a disordered segment, energetically unravel the polypeptide and translocate it towards the 20S catalytic core (CP). In this substrate engaged state, Rpn11 is repositioned at the pore of the ATPase channel to remove remaining ubiquitin modifications and accelerate translocation. C-termini of five of the six ATPases insert into corresponding lysine-pockets on the 20S α-ring to complete 20S CP gate opening. In the resulting substrate processing state, the ATPase channel is fully contiguous with the translocation channel into the 20S CP, where the substrate is proteolyzed. Complete degradation of a typical ubiquitin-conjugate takes place over a few tens of seconds while hydrolysing tens of ATP molecules in the process (50 kDa/∼50 s/∼80ATP). This article reviews recent insight into biochemical and structural features that underlie substrate recognition and processing by the 26S proteasome.

Exposure of Mesenchymal Stem Cells to an Alzheimer’s Disease Environment Enhances Therapeutic Effects

Mesenchymal stem cells (MSCs) have emerged as a promising tool for the treatment of Alzheimer’s disease (AD). Previous studies suggested that the coculture of human MSCs with AD in an in vitro model reduced the expression of amyloid-beta 42 (Aβ42) in the medium as well as the overexpression of amyloid-beta- (Aβ-) degrading enzymes such as neprilysin (NEP). We focused on the role of primed MSCs (human Wharton’s jelly-derived mesenchymal stem cells (WJ-MSCs) exposed to an AD cell line via a coculture system) in reducing the levels of Aβ and inhibiting cell death. We demonstrated that mouse groups treated with naïve MSCs and primed MSCs showed significant reductions in cell death, ubiquitin conjugate levels, and Aβ levels, but the effects were greater in primed MSCs. Also, mRNA sequencing data analysis indicated that high levels of TGF-β induced primed-MSCs. Furthermore, treatment with TGF-β reduced Aβ expression in an AD transgenic mouse model. These results highlighted AD environmental preconditioning is a promising strategy to reduce cell death and ubiquitin conjugate levels and maintain the stemness of MSCs. Further, these data suggest that human WJ-MSCs exposed to an AD environment may represent a promising and novel therapy for AD.

Exposure of Mesenchymal Stem Cells to an Alzheimer’s Disease Environment Enhances Therapeutic Effects

BackgroundMesenchymal stem cells (MSCs) have emerged as a promising tool for the treatment of Alzheimer’s disease (AD). Previous studies suggested that the co-culture of human MSCs with AD in an in vitro model reduced the expression of amyloid-beta 42 (Aβ42) in the medium as well as the overexpression of amyloid-beta (Aβ )-degrading enzymes such as neprilysin (NEP).MethodsIn this study, we focused on the role of primed MSCs (human Wharton's jelly-derived mesenchymal stem cells (WJ-MSCs) exposed to an AD cell line via a co-culture system) in reducing the levels of Aβ and inhibiting cell death. ResultsWe demonstrated that mouse groups treated with naïve MSCs and primed MSCs showed significant reductions in cell death, ubiquitin conjugate levels, and Aβ levels, but the effects were greater in primed MSCs. Also, mRNA sequencing data analysis indicated that high levels of TGF-β induced primed-MSCs. Furthermore, treatment with TGF-β reduced Aβ expression in an AD transgenic mouse model. ConclusionAD environmental preconditioning is a promising strategy to reduce cell death and ubiquitin conjugate levels and maintain the stemness of MSCs. Further, these data suggest that human WJ-MSCs exposed to an AD environment may represent a promising and novel therapy for AD.

UBL domain of Usp14 and other proteins stimulates proteasome activities and protein degradation in cells

The best-known function of ubiquitin-like (UBL) domains in proteins is to enable their binding to 26S proteasomes. The proteasome-associated deubiquitinating enzyme Usp14/UBP6 contains an N-terminal UBL domain and is an important regulator of proteasomal activity. Usp14 by itself represses multiple proteasomal activities but, upon binding a ubiquitin chain, Usp14 stimulates these activities and promotes ubiquitin-conjugate degradation. Here, we demonstrate that Usp14’s UBL domain alone mimics this activation of proteasomes by ubiquitin chains. Addition of this UBL domain to purified 26S proteasomes stimulated the same activities inhibited by Usp14: peptide entry and hydrolysis, protein-dependent ATP hydrolysis, deubiquitination by Rpn11, and the degradation of ubiquitinated and nonubiquitinated proteins. Thus, the binding of Usp14’s UBL (apparently to Rpn1’s T2 site) seems to mediate the activation of proteasomes by ubiquitinated substrates. However, the stimulation of these various activities was greater in proteasomes lacking Usp14 than in wild-type particles and thus is a general response that does not involve some displacement of Usp14. Furthermore, the UBL domains from hHR23 and hPLIC1/UBQLN1 also stimulated peptide hydrolysis, and the expression of hHR23A’s UBL domain in HeLa cells stimulated overall protein degradation. Therefore, many UBL-containing proteins that bind to proteasomes may also enhance allosterically its proteolytic activity.