Project description:Nrf/NFE2L family transcription factors regulate redox balance, metabolism, proteostasis, and aging. Nrf1/NFE2L1 is responsible for stress-responsive upregulation of proteasome subunit genes and is essential for adaptation to proteotoxic stress. The closely related Nrf2/NFE2L2 is responsible for activation of oxidative stress responses and xenobiotic detoxification. Although regulated by different mechanisms, Nrf1 and Nrf2 contain very similar DNA binding domains and can drive similar transcriptional responses. However, the extent to which functions of Nrf1/2 are distinct or overlapping has been unclear. In C. elegans, a single gene, skn-1, encodes distinct protein isoforms, SKN-1A and SKN-1C, that function analogously to mammalian Nrf1 and Nrf2, respectively. We previously showed that regulation of the proteasome by SKN-1A/Nrf1 requires post-translational conversion of N-glycosylated asparagine residues to aspartate by the PNG-1/NGLY1 peptide:N-glycanase, a process we term ‘sequence editing’. Here, we reveal the consequences of sequence editing for the transcriptomic output of activated SKN-1A. We show that whilst activation of proteasome subunit genes is strictly dependent on sequence editing, sequence edited SKN-1A also activate genes linked to redox homeostasis and xenobiotic detoxification that are also activated by non-sequence edited forms of SKN-1. Using mutant alleles that selectively inactivate either SKN-1A or SKN-1C, we show that SKN-1A/Nrf1 and SKN-1C/Nrf2 function coordinately to promote optimal oxidative stress resistance and confirm that they are regulated by discrete genetic pathways. This work demonstrates that sequence editing plays a critical role in tailoring SKN-1/Nrf functions by tuning the SKN-1A/Nrf1 regulated transcriptome.

Project description:To investigate the sequence editing-specific effects on Nrf1 functions, we utilized glycan-less Nrf1 mutants, 9NA and 9ND, in which all nine of the putative N-glycosylation sites (N-X-S/T; asparagine (N) serine (S), threonine (T), and X is any amino acid except proline) were replaced with alanine (A) and aspartic acid (D), respectively. To comprehensively understand the effects of Nrf1 sequence editing on the transcriptome, microarray analysis was performed on NGLY1-KO HeLa cells stably expressing 9NA and 9ND.

Project description:We examined ubiquitin-linkages on Nrf1 purified from cell lysates of NGLY1-KO cells overexpressing Nrf1-FLAG with HA-FBS2. The ubiquitin linkage types were quantified using the LC-MS/MS-based absolute quantification method, ubiquitin parallel reaction monitoring (Ub-AQUA/PRM).

Project description:We report using a single-cell transcriptomic study of cerebral organiods (COs) developed from WA09 hESCs with gene editing-induced NGLY1 mutations and from NGLY1-deficient patient's hiPSCs at 40 or 80 days of development. WA09 hESC-derived COs with and without mutant NGLY1 and patient's hiPSC-derived COs with and without the ectopic expression NGLY1 were analyzed.

Project description:NGLY1-dependent conversion of N-glycosylated N to D is essential for transcription of proteasome genes

Project description:The Ddi1/DDI2 proteins are classified as ubiquitin shuttling factors and are implicated in a wide range of cellular functions. In addition to ubiquitin-binding and ubiquitin-like domains, these proteins contain a conserved region with similarity to retroviral proteases, but whether and how they function as proteases has remained unknown. Here we show that human DDI2 knock-out cells are sensitive to proteasome inhibition and accumulate high-molecular weight, ubiquitylated proteins that are poorly degraded by the proteasome. These proteins are targets for the protease activity of purified DDI2. Thus far, no evidence for DDI2 acting as a de-ubiquitylating enzyme has been uncovered, suggesting that it might cleave the ubiquitylated protein itself. In support of this idea, cleavage of transcription factor NRF1 is known to require DDI2 activity in vivo. We show that DDI2 is capable of cleaving NRF1 in vitro, but only when NRF1 protein is poly-ubiquitylated. Together, these data suggest that DDI2 represents the first example of a ubiquitin-directed endo-protease.

Project description:Bortezomib is a proteasome inhibitor used in severel different hematological malignancies. Resistance to this drug is still poorly understood. In order get more insight in the resistance mechanism, we developed several bortezomib resistant subclones of the CCRF-CEM T-ALL cell line. On these subclones comparative Genome hybridization (arrayCGH) for DNA copy number analysis gene expression and micro-RNA expression arrays were performed. We performed micro-RNA on two different bortezomib resistant subclones of the CCRF-CEM cell line. The resistant subclones were compared to the parental CCRF-CEM wildtype cell line.

Project description:Bortezomib is a proteasome inhibitor used in severel different hematological malignancies. Resistance to this drug is still poorly understood. In order get more insight in the resistance mechanism, we developed several bortezomib resistant subclones of the THP-1 monocytic/macrophage cell line. On these subclones expression arrays were performed. We performed expression array three different bortezomib resistant subclones of the THP-1 cell line. The resistant subclones were spotted against the parental THP-1 wildtype cell line.

Project description:The maintenance of protein homeostasis is an essential characteristic of life. Transcription factor NRF1 (NFE2L1) has been reported to be activated by proteasome dysfunction, although the genome-wide target genes are poorly understood. Using ChIP-seq analysis, we found a potential association between NRF1 and autophagy. Our findings highlight the new activation mechanism of autophagy through gene regulation under proteasome dysfunction.

Project description:Bortezomib is a proteasome inhibitor used in severel different hematological malignancies. Resistance to this drug is still poorly understood. In order get more insight in the resistance mechanism, we developed several bortezomib resistant subclones of the CCRF-CEM T-ALL cell line. On these subclones comparative Genome hybridization (arrayCGH) for DNA copy number analysis gene expression and micro-RNA expression arrays were performed. We performed gene expression microarray analysis on four different bortezomib resistant subclones of the CCRF-CEM cell line. The resistant subclones were compaired to treated and untreated the parental CCRF-CEM wildtype cell line.