Prolonged proteasome inhibition cyclically upregulates Oct3/4 and Nanog gene expression, but reduces induced pluripotent stem cell colony formation.

There is ample evidence that the ubiquitin-proteasome system is an important regulator of transcription and its activity is necessary for maintaining pluripotency and promoting cellular reprogramming. Moreover, proteasome activity contributes to maintaining the open chromatin structure found in pluripotent stem cells, acting as a transcriptional inhibitor at specific gene loci generally associated with differentiation. The current study was designed to understand further the role of proteasome inhibition in reprogramming and its ability to modulate endogenous expression of pluripotency-related genes and induced pluripotent stem cells (iPSCs) colony formation. Herein, we demonstrate that acute combinatorial treatment with the proteasome inhibitors MG101 or MG132 and the histone deacetylase (HDAC) inhibitor valproic acid (VPA) increases gene expression of the pluripotency marker Oct3/4, and that MG101 alone is as effective as VPA in the induction of Oct3/4 mRNA expression in fibroblasts. Prolonged proteasome inhibition cyclically upregulates gene expression of Oct3/4 and Nanog, but reduces colony formation in the presence of the iPSC induction cocktail. In conclusion, our results demonstrate that the 26S proteasome is an essential modulator in the reprogramming process. Its inhibition enhances expression of pluripotency-related genes; however, efficient colony formation requires proteasome activity. Therefore, discovery of small molecules that increase proteasome activity might lead to more efficient cell reprogramming and generation of pluripotent cells.

Silencing histone deacetylase-specific isoforms enhances expression of pluripotency genes in bovine fibroblasts.

Histone deacetylases (HDACs) catalyze deacetylation of histones that results in altered transcriptional activity. Inhibitors of HDACs have been shown to induce transcriptional changes that contribute positively to reprogramming somatic cells either by nuclear transfer or inducing a pluripotent state. However, the exact molecular mechanisms whereby HDAC inhibitors function and the specificity of the HDAC isoforms in cell reprogramming are not yet fully understood. Herein, we report the ability of individual isoform-specific HDACs to modulate endogenous expression of pluripotency-associated genes in bovine somatic cells. This in vitro study showed that a transient selective depletion of HDACs resulted in elevated mRNA levels of Oct-4, Sox2, and Nanog. In particular, we found that inhibition of specific HDAC isoforms using small interfering (si) RNA significantly increased expression of Nanog, a key factor required for totipotency induced by somatic cell nuclear transfer and for maintaining pluripotency in embryonic and induced pluripotent stem cells. Our study suggests that this gene might be the most susceptible to HDAC activity inhibition. Moreover, a regulatory role of the class III HDAC, SIRT3, on an Oct4-Sox2-Nanog transcriptional network was revealed. We observed the upregulation of pluripotency-related genes by depletion of SIRT3. SIRT3 is localized to mitochondria and is associated with energy metabolism processes, suggesting metabolic changes may be linked to reprogramming in bovine fibroblasts. In conclusion, we show that targeting selective HDACs can potentially be useful to enhance reprogramming and that sirtuins may play a pivotal role in somatic cell reprogramming by upregulating an Oct4-Sox2-Nanog transcriptional network. Dedifferentiating donor somatic cells by upregulating developmentally important genes through specific knockdown of epigenetic targets, in particular HDACs, may provide a path to improving livestock cloning and the in vitro production of pluripotent cells.

Screening for epigenetic target genes that enhance reprogramming using lentiviral-delivered shRNA.

Small molecules will need to be identified and/or developed that target protein classes limiting reprogramming efficiency. A specific class of proteins includes epigenetic regulators that silence, or minimize expression, of pluripotency genes in differentiated cells. To better understand the role of specific epigenetic modulators in reprogramming, we have used shRNA delivered by lentivirus to assess the significance of individual epi-proteins in reprogramming pluripotent gene expression.