TFIIH mutations can impact on translational fidelity of the ribosome

TFIIH is a complex essential for transcription of protein-coding genes by RNA polymerase II, DNA repair of UV-lesions and transcription of rRNA by RNA polymerase I. Mutations in TFIIH cause the cancer prone DNA-repair disorder xeroderma pigmentosum (XP) and the developmental and premature aging disorders trichothiodystrophy (TTD) and Cockayne syndrome (CS). 50% of TTD cases are caused by TFIIH mutations. Using TFIIH mutant patient cells from TTD and XP subjects we can show that the stress-sensitivity of the proteome is reduced in TTD, but not in XP. Using three different methods to investigate the accuracy of protein synthesis by the ribosome, we demonstrate that translational fidelity of the ribosomes of TTD, but not XP cells, is decreased. The process of ribosomal synthesis and maturation is affected in TTD cells and can lead to instable ribosomes. Isolated ribosomes from TTD patients show an elevated error rate when challenged with oxidized mRNA, explaining the oxidative hypersensitivity of TTD cells. Treatment of TTD cells with N-acetyl cysteine normalized the increased translational error-rate and restored translational fidelity. Here we describe a pathomechanism that might be relevant for our understanding of impaired development and aging-associated neurodegeneration

Loss of Proteostasis Is a Pathomechanism in Cockayne Syndrome

Retarded growth and neurodegeneration are hallmarks of the premature aging disease Cockayne syndrome (CS). Cockayne syndrome proteins take part in the key step of ribosomal biogenesis, transcription of RNA polymerase I. Here, we identify a mechanism originating from a disturbed RNA polymerase I transcription that impacts translational fidelity of the ribosomes and consequently produces misfolded proteins. In cells from CS patients, the misfolded proteins are oxidized by the elevated reactive oxygen species (ROS) and provoke an unfolded protein response that represses RNA polymerase I transcription. This pathomechanism can be disrupted by the addition of pharmacological chaperones, suggesting a treatment strategy for CS. Additionally, this loss of proteostasis was not observed in mouse models of CS. Cockayne syndrome is a devastating childhood progeria. Here, Alupei et al. show that cells from CS patients have reduced translation accuracy and elevated ROS, leading to generation of unstable proteins and activation of ER stress. Reducing ER stress by chemical chaperones in these cells rescues RNA polymerase I activity and protein synthesis

2A-DUB/Mysm1 Regulates Epidermal Development in Part by Suppressing p53-Mediated Programs

Development and homeostasis of the epidermis are governed by a complex network of sequence-specific transcription factors and epigenetic modifiers cooperatively regulating the subtle balance of progenitor cell self-renewal and terminal differentiation. To investigate the role of histone H2A deubiquitinase 2A-DUB/Mysm1 in the skin, we systematically analyzed expression, developmental functions, and potential interactions of this epigenetic regulator using Mysm1-deficient mice and skin-derived epidermal cells. Morphologically, skin of newborn and young adult Mysm1-deficient mice was atrophic with reduced thickness and cellularity of epidermis, dermis, and subcutis, in context with altered barrier function. Skin atrophy correlated with reduced proliferation rates in Mysm1−/− epidermis and hair follicles, and increased apoptosis compared with wild-type controls, along with increases in DNA-damage marker γH2AX. In accordance with diminished α6-Integrinhigh+CD34+ epidermal stem cells, reduced colony formation of Mysm1−/− epidermal progenitors was detectable in vitro. On the molecular level, we identified p53 as potential mediator of the defective Mysm1-deficient epidermal compartment, resulting in increased pro-apoptotic and anti-proliferative gene expression. In Mysm1−/−p53−/− double-deficient mice, significant recovery of skin atrophy was observed. Functional properties of Mysm1−/− developing epidermis were assessed by quantifying the transepidermal water loss. In summary, this investigation uncovers a role for 2A-DUB/Mysm1 in suppression of p53-mediated inhibitory programs during epidermal development

Cellular sensitivity to UV-irradiation is mediated by RNA polymerase I transcription - Fig 1

<p>UVC-irradiation repressed the expression of full length transcripts (A) but stimulated Pol I transcription initiation (B). Young foreskin fibroblasts (FF95) with a cumulative population density under 25 were irradiated with 10J/m² UVC and isolated RNA after the indicated time points was used for northern blot analysis (A) as well as qPCR amplifying the initiation (5`ETS) and elongation (5.8 ITS) sites of the pre-rRNA (B). (C) Whole cell lysates of irradiated (10J/m²) FF95 have been analysed for p53 stabilisation by western blot. Values are mean ± SD of three independent experiments (* = ρ<0.05, ** = ρ<0.01, *** = ρ<0.001). Blots are representatives of at least three independent experiments.</p

Loss of Proteostasis Is a Pathomechanism in Cockayne Syndrome

Summary: Retarded growth and neurodegeneration are hallmarks of the premature aging disease Cockayne syndrome (CS). Cockayne syndrome proteins take part in the key step of ribosomal biogenesis, transcription of RNA polymerase I. Here, we identify a mechanism originating from a disturbed RNA polymerase I transcription that impacts translational fidelity of the ribosomes and consequently produces misfolded proteins. In cells from CS patients, the misfolded proteins are oxidized by the elevated reactive oxygen species (ROS) and provoke an unfolded protein response that represses RNA polymerase I transcription. This pathomechanism can be disrupted by the addition of pharmacological chaperones, suggesting a treatment strategy for CS. Additionally, this loss of proteostasis was not observed in mouse models of CS. : Cockayne syndrome is a devastating childhood progeria. Here, Alupei et al. show that cells from CS patients have reduced translation accuracy and elevated ROS, leading to generation of unstable proteins and activation of ER stress. Reducing ER stress by chemical chaperones in these cells rescues RNA polymerase I activity and protein synthesis. Keywords: Cockayne syndrome, RNA polymerase I, translation fidelity, ER stress, unfolded protein respons