22 research outputs found
Determinants of amyloid fibril degradation by the PDZ protease HTRA1
Excessive aggregation of proteins has a major impact on cell fate and is a hallmark of amyloid diseases in humans. To resolve insoluble deposits and to maintain protein homeostasis, all cells use dedicated protein disaggregation, protein folding and protein degradation factors. Despite intense recent research, the underlying mechanisms controlling this key metabolic event are not well understood. Here, we analyzed how a single factor, the highly conserved serine protease HTRA1, degrades amyloid fibrils in an ATP-independent manner. This PDZ protease solubilizes protein fibrils and disintegrates the fibrillar core structure, allowing productive interaction of aggregated polypeptides with the active site for rapid degradation. The aggregate burden in a cellular model of cytoplasmic tau aggregation is thus reduced. Mechanistic aspects of ATP-independent proteolysis and its implications in amyloid diseases are discussed
Targeting the MYC interaction network in B-cell lymphoma via histone deacetylase 6 inhibition
Overexpression of MYC is a genuine cancer driver in lymphomas and related to poor prognosis. However, therapeutic targeting of the transcription factor MYC remains challenging. Here, we show that inhibition of the histone deacetylase 6 (HDAC6) using the HDAC6 inhibitor Marbostat-100 (M-100) reduces oncogenic MYC levels and prevents lymphomagenesis in a mouse model of MYC-induced aggressive B-cell lymphoma. M-100 specifically alters protein-protein interactions by switching the acetylation state of HDAC6 substrates, such as tubulin. Tubulin facilitates nuclear import of MYC, and MYC-dependent B-cell lymphoma cells rely on continuous import of MYC due to its high turn-over. Acetylation of tubulin impairs this mechanism and enables proteasomal degradation of MYC. M-100 targets almost exclusively B-cell lymphoma cells with high levels of MYC whereas non-tumor cells are not affected. M-100 induces massive apoptosis in human and murine MYC-overexpressing B-cell lymphoma cells. We identified the heat-shock protein DNAJA3 as an interactor of tubulin in an acetylation-dependent manner and overexpression of DNAJA3 resulted in a pronounced degradation of MYC. We propose a mechanism by which DNAJA3 associates with hyperacetylated tubulin in the cytoplasm to control MYC turnover. Taken together, our data demonstrate a beneficial role of HDAC6 inhibition in MYC-dependent B-cell lymphoma
Thank God for My Successes (Not My Failures): Feeling God’s Presence Explains a God Attribution Bias
Little research has investigated attributional biases to God for positive and negative personal events. Consistent with past work, we predicted that people who believe in God will attribute successes more to God than failures, particularly for highly religious people. We also predicted that believing that God is a part of the self would increase how much people felt God’s presence which would result in giving God more credit for successes. Our study (N = 133) was a two-factor, between-subject experimental design in which participants either won or lost a game and were asked to attribute the cause of this outcome to themselves, God, or other factors. Furthermore, participants either completed the game before or after responding to questions about their religious beliefs. Overall, there was support for our predictions. Our results have important implications for attribution research and the practical psychological experiences for religious people making attributions for their successes and failures
Determinants of structural and functional plasticity of a widely conserved protease chaperone complex
Channeling of misfolded proteins into repair, assembly or degradation pathways is often mediated by complex and multifunctional cellular factors. Despite detailed structural information, the underlying regulatory mechanisms governing these factors are not well understood. The extracytoplasmic heat-shock factor DegP (HtrA) is a well-suited model for addressing mechanistic issues, as it is regulated by the common mechanisms of allostery and activation by oligomerization. Site-directed mutagenesis combined with refolding and oligomerization studies of chemically denatured DegP revealed how substrates trigger the conversion of the resting conformation into the active conformation. Binding of specific peptides to PDZ domain-1 causes a local rearrangement that is allosterically transmitted to the substrate-binding pocket of the protease domain. This activated state readily assembles into larger oligomeric particles, thus stabilizing the catalytically active form and providing a degradation cavity for protein substrates. The implications of these data for the mechanism of protein quality control are discussed