Disruption of the polyubiquitin gene Ubb reduces the self-renewal capacity of neural stem cells.

Ubiquitin (Ub) is a highly conserved eukaryotic protein that plays pivotal roles in cellular signal transduction, differentiation, and proteolysis. Although we have previously reported that disruption of the polyubiquitin gene Ubb is associated with the dysregulated differentiation of neural stem cells (NSCs) into neurons, it is unclear how gene expression patterns are altered in Ubb knockout (KO) NSCs, and whether this altered gene expression contributes to Ubb KO neural phenotypes. To answer these questions, we used RNA-Seq to compare the transcriptomes of Ubb KO NSCs and Ubb heterozygous (HT) controls. We found that the expression levels of most proliferation markers were decreased in Ubb KO NSCs. To determine whether the reduced levels of proliferation markers were due to reduced self-renewal of NSCs, such as radial glia, we measured the levels of the radial glia marker, Pax6, in mouse embryonic brains at 14.5 dpc. We found that Pax6 levels were decreased and the ventricular zone was thinner in the embryonic brains of Ubb KO mice compared to those of wild-type (WT) control mice. To determine whether the decreased self-renewal of Ubb KO NSCs was caused by cell-autonomous defects and not due to their microenvironment, we transplanted NSCs into WT mouse brains using a cannula system. In mouse brain sections, immunoreactivity of the NSC marker, nestin, was much lower in Ubb KO NSCs than in Ubb HT controls. Therefore, our data suggest that cell-autonomous defects, due to the disruption of Ubb, lead to a decrease in the self-renewal capacity of NSCs and may contribute to their dysregulated differentiation into neurons.

Reversible Regulation of Polyubiquitin Gene UBC via Modified Inducible CRISPR/Cas9 System.

Ubiquitin is required under both normal and stress conditions. Under stress conditions, upregulation of the polyubiquitin gene UBC is essential to meet the requirement of increased ubiquitin levels to confer stress resistance. However, UBC upregulation is usually observed only under stress conditions and not under normal conditions. Therefore, it has not been possible to upregulate UBC under normal conditions to study the effect of excess ubiquitin on cellular machinery. Recently, the CRISPR/Cas9 system has been widely used in biological research as a useful tool to study gene disruption effects. In this study, using an inducible CRISPR/Cas9 variant, a dCas9-VP64 fusion protein, combined with a single guide RNA (sgRNA) containing MS2 aptamer loops and MS2-p65-HSF1, we developed a system to increase the ubiquitin pool via upregulation of UBC. Although it is challenging to upregulate the expression of a gene that is already expressed at high levels, the significance of our system is that UBC upregulation can be induced in an efficient, reversible manner that is compatible with cellular processes, even under normal conditions. This system can be used to study ubiquitin pool dynamics and it will be a useful tool in identifying the role of ubiquitin under normal and stress conditions.

Effect of cellular ubiquitin levels on the regulation of oxidative stress response and proteasome function via Nrf1.

The polyubiquitin genes Ubb and Ubc are upregulated under oxidative stress induced by arsenite [As(III)]. However, the role of ubiquitin (Ub) under As(III) exposure is not known in detail. In a previous study, we showed that the reduced viability observed in Ubc-/- mouse embryonic fibroblasts under As(III) exposure was not due to dysregulation of the Nrf2-Keap1 pathway, which prompted us to investigate another NFE2 family protein, nuclear factor erythroid 2-related factor 1 (Nrf1). In this study, we found that Ub deficiency due to Ubc knockdown in N2a cells reduced cell viability and proteasome activity under As(III) exposure. Furthermore, mRNA levels of the proteasome subunit Psma1 were also reduced. In addition, Ub deficiency led to the nuclear accumulation of the p65 isoform of Nrf1 under As(III) exposure. Interestingly, the overexpression of p65-Nrf1 recapitulated the phenotypes of Ub-deficient N2a cells under As(III) exposure. On the other hand, Nrf1 knockdown suppressed the death of Ub-deficient N2a cells upon exposure to As(III). Therefore, the levels of p65-Nrf1 may play an important role in the maintenance of cell viability under oxidative stress induced by As(III).

Regulation of REST levels overcomes dysregulation of neural stem cell differentiation caused by disruption of polyubiquitin gene Ubb.

Reduced levels of cellular ubiquitin (Ub) caused by disruption of the polyubiquitin gene Ubb lead to dysregulated differentiation of neural stem/progenitor cells (NSCs) and apoptosis in cells cultured in vitro. However, the underlying mechanisms responsible for these phenotypes in Ub-deficient cells have not been studied extensively. In the present study, we found that levels of repressor element-1 silencing transcription factor (REST) are elevated in Ubb-/- cells. To determine whether dysregulation of NSC differentiation is caused by the increased REST levels, we investigated the effect of reduced REST levels in Ubb-/- cells. Rest knockdown was found to increase the expression of the neuronal marker ßIII-tubulin (TUJ1) and restore the expression pattern of the early neuronal marker α-internexin (α-INX) in Ubb-/- cells. Furthermore, Rest knockdown reduced Ub deficiency-induced apoptosis in cells cultured in vitro. Therefore, our study validates that cellular Ub levels are crucial for precise control of the levels of regulatory proteins such as REST during neurogenesis. We propose that regulation of Rest levels is a promising approach to overcome dysregulation of NSC differentiation caused by disruption of the polyubiquitin gene Ubb.

Restoration of cellular ubiquitin reverses impairments in neuronal development caused by disruption of the polyubiquitin gene Ubb.

Disruption of the polyubiquitin gene Ubb leads to hypothalamic neurodegeneration and metabolic disorders, including obesity and sleep abnormalities, in mice. However, it has yet to be determined whether or not these neural phenotypes in Ubb(-/-) mice are directly caused by cell autonomous defects in maintaining proper levels of ubiquitin (Ub). To directly demonstrate that reduced levels of Ub are sufficient to cause neuronal abnormalities, we investigated the characteristics of cultured neurons isolated from Ubb(-/-) mouse embryonic brains. We found that neuronal morphology, neurite outgrowth, and synaptic development were significantly impaired in Ubb(-/-) neurons. Furthermore, we observed the growth of astrocytes in Ubb(-/-) cell cultures despite the fact that cells were cultured under conditions promoting neuronal growth. When the reduced levels of free Ub, but not Ub conjugates, in Ubb(-/-) cells were restored to those of wild-type cells by providing exogenous Ub via lentivirus-mediated delivery, the increased apoptosis observed in Ubb(-/-) cells was almost completely abolished. Ectopic expression of Ub also improved neuronal and glial phenotypes observed in Ubb(-/-) cells. Therefore, our study suggests that Ub homeostasis, or the maintenance of cellular free Ub above certain threshold levels, is essential for proper neuronal development and survival.

ECPUB5 Polyubiquitin Gene in Euphorbia characias: Molecular Characterization and Seasonal Expression Analysis.

The spurge Euphorbia characias is known for its latex, which is rich in antioxidant enzymes and anti-phytopathogen molecules. In this study, we identified a novel polyubiquitin protein in the latex and leaves, leading to the first molecular characterization of its coding gene and expressed protein in E. characias. Using consensus-degenerate hybrid oligonucleotide primers (CODEHOP) and rapid amplification of cDNA ends (5'/3'-RACE), we reconstructed the entire open reading frame (ORF) and noncoding regions. Our analysis revealed that the polyubiquitin gene encodes five tandemly repeated sequences, each coding for a ubiquitin monomer with amino acid variations in four of the five repeats. In silico studies have suggested functional differences among monomers. Gene expression peaked during the summer, correlating with high temperatures and suggesting a role in heat stress response. Western blotting confirmed the presence of polyubiquitin in the latex and leaf tissues, indicating active ubiquitination processes. These findings enhance our understanding of polyubiquitin's regulatory mechanisms and functions in E. characias, highlighting its unique structural and functional features.

Simultaneous Disruption of Both Polyubiquitin Genes Affects Proteasome Function and Decreases Cellular Proliferation.

The ubiquitin (Ub) proteasome system is important for maintaining protein homeostasis and has various roles in cell signaling, proliferation, and cell cycle regulation. In mammals, Ub is encoded by two monoubiquitin and two polyubiquitin genes. Although reduced levels of Ub due to the disruption of one polyubiquitin gene are known to decrease cell proliferation, the effect of disrupting both polyubiquitin genes remains elusive. Polyubiquitin gene Ubc knockout mice are embryonically lethal and polyubiquitin gene Ubb knockout mice are infertile. Thus, it is difficult to study the effects of double knockouts (DKOs). In the present study, the CRISPR/Cas9 system was used to simultaneously knockout both polyubiquitin genes, UBB and UBC, in HEK293T and HeLa cells. In DKO cells, growth decreased significantly compared to the control cells. We observed reduced proteasome function and reduced levels of free Ub in DKO cells. However, the levels of purified proteasome were not different between control and DKO cells, although the mRNA levels of proteasomal subunits were significantly increased in latter. We propose that the reduction of Ub levels, by disruption of both polyubiquitin genes, resulted in an altered proteasomal status, leading to the reduced proteasome activity, and decreased cellular proliferation.

Transcription Terminator-Mediated Enhancement in Transgene Expression in Maize: Preponderance of the AUGAAU Motif Overlapping With Poly(A) Signals.

The selection of transcription terminators (TTs) for pairing with high expressing constitutive promoters in chimeric constructs is crucial to deliver optimal transgene expression in plants. In this study, the use of the native combinations of four polyubiquitin gene promoters and corresponding TTs resulted in up to >3-fold increase in transgene expression in maize. Of the eight polyubiquitin promoter and TT regulatory elements utilized, seven were novel and identified from the polyubiquitin genes of Brachypodium distachyon, Setaria italica, and Zea mays. Furthermore, gene expression driven by the Cassava mosaic virus promoter was studied by pairing the promoter with distinct TTs derived from the high expressing genes of Arabidopsis. Of the three TTs studied, the polyubiquitin10 gene TT produced the highest transgene expression in maize. Polyadenylation patterns and mRNA abundance from eight distinct TTs were analyzed using 3'-RACE and next-generation sequencing. The results exhibited one to three unique polyadenylation sites in the TTs. The poly(A) site patterns for the StPinII TT were consistent when the same TT was deployed in chimeric constructs irrespective of the reporter gene and promoter used. Distal to the poly(A) sites, putative polyadenylation signals were identified in the near-upstream regions of the TTs based on previously reported mutagenesis and bioinformatics studies in rice and Arabidopsis. The putative polyadenylation signals were 9 to 11 nucleotides in length. Six of the eight TTs contained the putative polyadenylation signals that were overlaps of either canonical AAUAAA or AAUAAA-like polyadenylation signals and AUGAAU, a top-ranking-hexamer of rice and Arabidopsis gene near-upstream regions. Three of the polyubiquitin gene TTs contained the identical 9-nucleotide overlap, AUGAAUAAG, underscoring the functional significance of such overlaps in mRNA 3' end processing. In addition to identifying new combinations of regulatory elements for high constitutive trait gene expression in maize, this study demonstrated the importance of TTs for optimizing gene expression in plants. Learning from this study could be applied to other dicotyledonous and monocotyledonous plant species for transgene expression. Research on TTs is not limited to transgene expression but could be extended to the introduction of appropriate mutations into TTs via genome editing, paving the way for expression modulation of endogenous genes.