It is important for robot designers to know how to make robots that interact effectively with humans. One key dimension is robot appearance and in particular how humanlike the robot should be. Uncanny Valley theory suggests that robots look uncanny when their appearance approaches, but is not absolutely, human. An underlying mechanism may be that appearance affects users’ perceptions of the robot’s personality and mind. This study aimed to investigate how robot facial appearance affected perceptions of the robot’s mind, personality and eeriness. A repeated measures experiment was conducted. 30 participants (14 females and 16 males, mean age 22.5 years) interacted with a Peoplebot healthcare robot under three conditions in a randomized order: the robot had either a humanlike face, silver face, or no-face on its display screen. Each time, the robot assisted the participant to take his/her blood pressure. Participants rated the robot’s mind, personality, and eeriness in each condition. The robot with the humanlike face display was most preferred, rated as having most mind, being most humanlike, alive, sociable and amiable. The robot with the silver face display was least preferred, rated most eerie, moderate in mind, humanlikeness and amiability. The robot with the no-face display was rated least sociable and amiable. There was no difference in blood pressure readings between the robots with different face displays. Higher ratings of eeriness were related to impressions of the robot with the humanlike face display being less amiable, less sociable and less trustworthy. These results suggest that the more humanlike a healthcare robot’s face display is, the more people attribute mind and positive personality characteristics to it. Eeriness was related to negative impressions of the robot’s personality. Designers should be aware that the face on a robot’s display screen can affect both the perceived mind and personality of the robot.
The ubiquitin-proteasome system (UPS) and autophagy are two major intracellular degradative mechanisms that mediate the turnover of complementary repertoires of intracellular proteomes. Simultaneously activating both UPS and autophagy might provide a powerful strategy for the clearance of misfolded proteins. However, it is not clear whether UPS and autophagy can be controlled by a common regulatory mechanism. K48 deubiquitination by USP14 is known to inhibit UPS. Here we show that USP14 regulates autophagy by negatively controlling K63 ubiquitination of Beclin 1. Furthermore, we show that activation of USP14 by Akt-mediated phosphorylation provides a mechanism for Akt to negatively regulate autophagy by promoting K63 deubiquitination. Our study suggests that Akt-regulated USP14 activity modulates both proteasomal degradation and autophagy through controlling K48 and K63 ubiquitination, respectively. Therefore, regulation of USP14 provides a mechanism for Akt to control both proteasomal and autophagic degradation. We propose that inhibition of USP14 may provide a strategy to promote both UPS and autophagy for developing novel therapeutics targeting neurodegenerative diseases.[Keywords: USP14; autophagy; Beclin 1; Akt] Supplemental material is available for this article. Autophagy and the ubiquitin-proteasome system (UPS) are two major intracellular degradative mechanisms that function in a complementary manner. UPS mediates the degradation of short-lived proteins conjugated with K48 ubiquitin chains (Komander and Rape 2012). On the other hand, autophagy mediates the turnover of long-lived proteins and intracellular organelles encapsulated in autophagosomes that eventually fuse with lysosomes to allow degradation by lysosomal proteases. Ubiquitination is also involved as a signaling mechanism in targeting both protein substrates and organelles such as depolarized mitochondria for degradation by autophagy (Sarraf et al. 2013;Ordureau et al. 2014). Ubiquitination of protein substrates is a reversible process, as ubiquitin chains can be removed by deubiquitinating enzymes (DUBs). Deubiquitination is an important negative regulatory mechanism for reducing the levels of protein ubiquitination. Ubiquitin-specific protease-14 (USP14), a DUB reversibly associated with the proteasome, has been shown to negatively regulate the activity of proteasomes by trimming K48 ubiquitin chains on proteasome-bound substrates (Borodovsky et al. 2001;Koulich et al. 2008;Lee et al. 2010). USP14 can also be activated by Akt-mediated phosphorylation, which promotes its deubiquitinating activity for both K48 and K63 ubiquitin linkages (Xu et al. 2015a). The activity of USP14 in deubiquitinating K63 ubiquitin linkages is likely to be physiologically relevant, as inhibition of USP14 in vivo leads to increases in the levels of K63-linked ubiquitin conjugates in both spinal cords and neurons (Vaden et al. 2015). However, the mechanism by which USP14 regulates K63 ubiquitination in control of cellular processes and its functional significance are...
RIPK1 is a critical mediator of cell death and inflammation downstream of TNFR1 upon stimulation by TNFα, a potent proinflammatory cytokine involved in a multitude of human inflammatory and degenerative diseases. RIPK1 contains an N-terminal kinase domain, an intermediate domain, and a C-terminal death domain (DD). The kinase activity of RIPK1 promotes cell death and inflammation. Here, we investigated the involvement of RIPK1-DD in the regulation of RIPK1 kinase activity. We show that a charge-conserved mutation of a lysine located on the surface of DD (K599R in human RIPK1 or K584R in murine RIPK1) blocks RIPK1 activation in necroptosis and RIPK1-dependent apoptosis and the formation of complex II. knockin mutant cells are resistant to RIPK1 kinase-dependent apoptosis and necroptosis. The resistance of K584R cells, however, can be overcome by forced dimerization of RIPK1. Finally, we show that the K584R RIPK1 knockin mutation protects mice against TNFα-induced systematic inflammatory response syndrome. Our study demonstrates the role of RIPK1-DD in mediating RIPK1 dimerization and activation of its kinase activity during necroptosis and RIPK1-dependent apoptosis.
Apoptosis and necroptosis are two distinct cell death mechanisms that may be activated in cells on stimulation by TNFα. It is still unclear, however, how apoptosis and necroptosis may be differentially regulated. Here we screened for E3 ubiquitin ligases that could mediate necroptosis. We found that deficiency of Pellino 1 (PELI1), an E3 ubiquitin ligase, blocked necroptosis. We show that PELI1 mediates K63 ubiquitination on K115 of RIPK1 in a kinase-dependent manner during necroptosis. Ubiquitination of RIPK1 by PELI1 promotes the formation of necrosome and execution of necroptosis. Although PELI1 is not directly involved in mediating the activation of RIPK1, it is indispensable for promoting the binding of activated RIPK1 with its downstream mediator RIPK3 to promote the activation of RIPK3 and MLKL. Inhibition of RIPK1 kinase activity blocks PELI1-mediated ubiquitination of RIPK1 in necroptosis. However, we show that PELI1 deficiency sensitizes cells to both RIPK1-dependent and RIPK1-independent apoptosis as a result of down-regulated expression of c-FLIP, an inhibitor of caspase-8. Finally, we show that mice are sensitized to TNFα-induced apoptosis. Thus, PELI1 is a key modulator of RIPK1 that differentially controls the activation of necroptosis and apoptosis.
The term laminopathies defines a group of genetic disorders caused by defects in the nuclear envelope, mostly the lamins. Lamins are the main constituents of the nuclear lamina, a filamentous meshwork associated with the inner nuclear membrane that provides mechanical stability and plays important roles in processes such as transcription, DNA replication and chromatin organization. More than 300 mutations in lamin A/C have been associated with diverse clinical phenotypes, understanding the molecular basis of these diseases may provide a rationale for treating them. Here we describe the generation of induced pluripotent stem cells (iPSCs) from a patient with inherited dilated cardiomiopathy and 2 patients with distinct accelerated forms of aging, atypical Werner syndrome and Hutchinson Gilford progeria, all of which are caused by mutations in lamin A/C. These cell lines were pluripotent and displayed normal nuclear membrane morphology compared to donor fibroblasts. Their differentiated progeny reproduced the disease phenotype, reinforcing the idea that they represent excellent tools for understanding the role of lamin A/C in normal physiology and the clinical diversity associated with these diseases.
Many human diseases share a developmental origin that manifests during childhood or maturity. Aneuploid syndromes are caused by supernumerary or reduced number of chromosomes and represent an extreme example of developmental disease, as they have devastating consequences before and after birth. Investigating how alterations in gene dosage drive these conditions is relevant because it might help treat some clinical aspects. It may also provide explanations as to how quantitative differences in gene expression determine phenotypic diversity and disease susceptibility among natural populations. Here, we aimed to produce induced pluripotent stem cell (iPSC) lines that can be used to improve our understanding of aneuploid syndromes. We have generated iPSCs from monosomy X [Turner syndrome (TS)], trisomy 8 (Warkany syndrome 2), trisomy 13 (Patau syndrome) and partial trisomy 11;22 (Emanuel syndrome), using either skin fibroblasts from affected individuals or amniocytes from antenatal diagnostic tests. These cell lines stably maintain the karyotype of the donors and behave like embryonic stem cells in all tested assays. TS iPSCs were used for further studies including global gene expression analysis and tissue-specific directed differentiation. Multiple clones displayed lower levels of the pseudoautosomal genes ASMTL and PPP2R3B than the controls. Moreover, they could be transformed into neural-like, hepatocyte-like and heart-like cells, but displayed insufficient up-regulation of the pseudoautosomal placental gene CSF2RA during embryoid body formation. These data support that abnormal organogenesis and early lethality in TS are not caused by a tissue-specific differentiation blockade, but rather involves other abnormalities including impaired placentation.
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