Assurance of mitochondrial integrity and mammalian longevity by the p62-Keap1-Nrf2-Nqo1 cascade

Sqstm1/p62 functions in the non-canonical activation of nuclear factor (erythroid-derived 2)-like 2 (Nrf2). However, its physiological relevance is not certain. Here, we show that p62(-/-) mice exhibited an accelerated presentation of ageing phenotypes, and tissues from these mice created a pro-oxidative environment owing to compromised mitochondrial electron transport. Accordingly, mitochondrial function rapidly declined with age in p62(-/-) mice. In addition, p62 enhanced basal Nrf2 activity, conferring a higher steady-state expression of NAD(P)H dehydrogenase, quinone 1 (Nqo1) to maintain mitochondrial membrane potential and, thereby, restrict excess oxidant generation. Together, the p62-Nrf2-Nqo1 cascade functions to assure mammalian longevity by stabilizing mitochondrial integrity.     

Parkin promotes proteasomal degradation of p62: implication of selective vulnerability of neuronal cells in the pathogenesis of Parkinson’s disease

Mutations or inactivation of parkin, an E3 ubiquitin ligase, are associated with familial form or sporadic Parkinson’s disease (PD), respectively, which manifested with the selective vulnerability of neuronal cells in substantia nigra (SN) and striatum (STR) regions. However, the underlying molecular mechanism linking parkin with the etiology of PD remains elusive. Here we report that p62, a critical regulator for protein quality control, inclusion body formation, selective autophagy and diverse signaling pathways, is a new substrate of parkin. P62 levels were increased in the SN and STR regions, but not in other brain regions in parkin knockout mice. Parkin directly interacts with and ubiquitinates p62 at the K13 to promote proteasomal degradation of p62 even in the absence of ATG5. Pathogenic mutations, knockdown of parkin or mutation of p62 at K13 prevented the degradation of p62. We further showed that parkin deficiency mice have pronounced loss of tyrosine hydroxylase positive neurons and have worse performance in motor test when treated with 6-hydroxydopamine hydrochloride in aged mice. These results suggest that, in addition to their critical role in regulating autophagy, p62 are subjected to parkin mediated proteasomal degradation and implicate that the dysregulation of parkin/p62 axis may involve in the selective vulnerability of neuronal cells during the onset of PD pathogenesis.     

Heterogeneity of dendritic cells in rat apical periodontitis

Dendritic cells are important for the induction of T-lymphocyte-mediated immunity by acting as antigen-presenting cells. We have previously reported that dendritic cells are prevalent in the chronic non-expanding phase of rat apical periodontitis. To characterize these cells further, immunoelectron microscopy with three dendritic cell markers (CD11c, OX6, OX62) was conducted for samples from rat models of apical periodontitis. Dendritic cells were divided into two types (type I or type II). Most of the type I dendritic cells expressed CD11c, showed an irregular large profile, had typical cytoplasmic processes, and were recognized as the major dendritic cell population. Most of the type II dendritic cells expressed OX62, showed oval small profiles with a few thin short processes, and were sometimes observed infiltrating from blood vessels. Cell-to-cell contacts between type I dendritic cells and lymphocytes were the most frequently observed associations. These results suggest that dendritic cells are composed of heterogeneous populations that exhibit different phenotypes, morphologies, and maturation/differentiation/activation. This study was supported by Grants-in-Aid for Scientific Research (no. 11470402 to T.O., and nos. 15791091 and 18791393 to T.K.) from the Japan Society for the Promotion of Sciences.     

Autophagy substrate SQSTM1/p62 regulates chromatin ubiquitination during the DNA damage response

The importance of autophagy in the DNA damage repair process is clear; however, the detailed molecular mechanism is still largely unknown. Here we found that DNA damage-induced histone H2A ubiquitination is suppressed in autophagy-deficient cells in a SQSTM1/p62 dependent manner. SQSTM1 binds and inhibits E3 ligase RNF168s activity, which is essential for H2A ubiquitination. As a result, several important factors for DNA repair cannot be recruited to the sites of DNA double-strand breaks (DSBs) in autophagy-deficient cells, leading to diminished DNA repair and increased sensitivity of cells to radiation.     

Autophagy regulates DNA repair through SQSTM1/p62

Macroautophagy/autophagy is primarily a degradative pathway that clears malfunctioning cellular components in response to various types of stress. Recent studies have indicated that autophagy also plays an important role in maintaining genome stability. Loss of autophagy is associated with increased damage to DNA, inappropriate amplification of genomic regions and abnormal chromosome number. In a recent paper by Wang et al. the authors uncover a mechanism through which autophagy regulates the ubiquitination of chromatin. In particular, the autophagy receptor and substrate SQSTM1/p62 inhibits the E3 ligase RNF168-dependent ubiquitination of histone in response to DNA double-strand breaks. Dysregulation of this process leads to a reduced ability to repair DNA and a corresponding increase in the sensitivity of cells to radiation-induced damage.     

Stress-induced polyubiquitination of proteasomal ubiquitin receptors targets the proteolytic complex for autophagic degradation

Ubiquitin (Ub) is a small protein (8 kDa) found in all eukaryotic cells, which is conjugated covalently to numerous proteins, tagging them for recognition by a downstream effector. One of the best characterized functions of Ub is targeting proteins for either selective degradation by the proteasome, or for bulk degradation by the autophagy-lysosome system. The executing arm of the UPS is the 26S proteasome, a large multicatalytic complex. While much is known about the synthesis and assembly of the proteasome's subunits, the mechanism(s) underlying its removal has remained obscure, similar to that of many other components of the ubiquitin-proteasome system. Our recent study identified autophagy as the degrading mechanism for the mammalian proteasome, mostly under stress conditions. Amino acid starvation induces specific ubiquitination of certain 19S proteasomal subunits that is essential for its binding to SQSTM1/p62, the protein that shuttles the ubiquitinated proteasome to the autophagic machinery. SQSTM1 delivers ubiquitinated substrates for proteasomal degradation via interaction of its PB1 domain with the 19S proteasomal subunit PSMD4/Rpn10, in situations where the proteasome serves as a “predator." In contrast, we found that the UBA domain of SQSTM1 is essential for its interaction with the ubiquitinated proteasome and its delivery to the autophagosome, rendering the proteasome a “prey.”     

Ferritin 2 domain-containing protein found in lacquer tree (Toxicodendron vernicifluum) sap has negative effects on laccase and peroxidase reactions

Lacquer tree sap, a raw material of traditional paints in East Asia, is hardened through laccase-catalyzed oxidation and the following polymerization of phenolic compound urushiol. In the sap’s water-insoluble fraction, we found two plantacyanins and a ferritin 2 domain-containing protein (TvFe2D, a homolog of Arabidopsis AT1G47980 and AT3G62730). The recombinant TvFe2D protein suppressed the accumulation of laccase-catalyzed oxidation products of a model substrate syringaldazine without decreasing oxygen consumption, the second substrate of laccase. The suppression was also observed when another substrate guaiacol or another oxidizing enzyme peroxidase was used. The functional domain of the suppression was the C-terminal half, downstream of the ferritin 2 domain. The results suggest that this protein may be involved in regulating the sap polymerization/hardening. We also discuss the possibility that homologous proteins of TvFe2D in other plants might be involved in the laccase- or peroxidase-mediated polymerization of phenolic compounds, such as lignin and flavonoids.     

mTORC1通路中氨基酸信号转导相关机制研究进展

雷帕霉素靶点蛋白（target of rapamycin,TOR）作为细胞内重要的生长和代谢调节中枢,主要通过形成两种复合物TORC1与TORC2发挥其功能。其中TORC1接收广泛的细胞内信号,如氨基酸水平、生长因子、能量以及缺氧状态等,通过调控蛋白质合成来促进细胞的增殖与生长。在这些信号当中,氨基酸不仅能够激活TORC1通路,还同时作为其他信号激活TORC1的必需条件。目前,对于生长因子和能量水平激活TORC1过程的分子机制已有较深入的认识,而对于氨基酸信号如何转导至TORC1的分子机制直到近年来才有了新的突破。该文通过梳理已发表的哺乳动物细胞中氨基酸信号调控mTORC1分子机制的相关实验结论,对该领域的研究方向进行了总结和展望。