Inhibition of ubiquitin-specific protease 13-mediated degradation of Raf1 kinase by Spautin-1 has opposing effects in naïve and primed pluripotent stem cells

Optimizing Human Cell-Free System for Efficient Protein Production

We present a highly efficient human HEK293-based cell-free protein synthesis (CFPS) system capable of producing up to 300 μg/ml reporter protein. One of the limitations of the CFPS systems with respect to protein yield has been the decline of the protein-synthesizing activity of the system upon prolonged incubation. Though factors contributing to this decline in activity have been investigated in yeast, little is known about the factors in mammalian systems. We find that a rapid depletion of the components of the energy-regeneration system is a major factor behind the decreasing protein-synthesis activity in the HEK293-derived system. In addition, we demonstrate that a functional CFPS system can be prepared from other mammalian cell lines as evidenced by our use of a human neuroblastoma SH-SY5Y-derived CFPS system. We also find that exogenous creatine kinase (CK) is dispensable for the functionality of the energy-regeneration system in HEK293 due to the presence of a sufficiently high endogenous CK activity in an HEK293 cell-free extract.

The USP10/13 inhibitor, spautin-1, attenuates the progression of glioblastoma by independently regulating RAF-ERK mediated glycolysis and SKP2

Glioblastoma is a malignant brain tumor with poor prognosis. Though several dysregulated pathways were found to mediate the tumor progression, hyperactivation of RAS-RAF-ERK pathway, enhanced glycolysis and SKP2 are associated with several glioblastomas. Recent findings on the role of USP10 in the transition from pro-neural to mesenchymal subtype of glioblastoma and, USP13 in the stabilization of RAF1 in mouse embryonic stem cells prompted us to examine their role in the mechanisms mediating the progression of glioblastoma. In the present study, we have examined the role of spautin-1, a pharmacological inhibitor of USP10 and USP13 in the mechanisms mediating glioblastoma. Our results indicate that spautin-1 as well as knockdown of its downstream targets, USP10 and USP13, reduced the proliferation and migration of glioblastoma cells. Also, spautin-1 mediated inhibition of RAF-ERK pathway or inhibition of RAF1 and MEK1 per se reduced the glycolytic function via PKM2/Glut-1 and inhibited the progression of glioblastoma. Further, the protooncogene, SKP2, which was shown to be a direct target of USP10 /USP13 was also reduced by spautin-1. While inhibition of SKP2 enhanced its downstream target p21, no apparent changes in the RAF-ERK levels or glycolytic function were evident. Also, inhibition of MEK1 did not affect SKP2 levels, indicating that these two pathways act independent of each other. Overall, our findings indicate that spautin-1 by virtue of its inhibitory effects on USP10/13 counteracts RAS-RAF-ERK mediated glycolysis and SKP2 that are critical in the progression of glioblastoma. Hence, further preclinical validation is warranted for taking the present observations forward.

Dynamic Roles of Signaling Pathways in Maintaining Pluripotency of Mouse and Human Embryonic Stem Cells

Culturing of mouse and human embryonic stem cells (ESCs) in vitro was a major breakthrough in the field of stem cell biology. These models gained popularity very soon mainly due to their pluripotency. Evidently, the ESCs of mouse and human origin share typical phenotypic responses due to their pluripotent nature, such as self-renewal capacity and potency. The conserved network of core transcription factors regulates these responses. However, significantly different signaling pathways and upstream transcriptional networks regulate expression and activity of these core pluripotency factors in ESCs of both the species. In fact, ample evidence shows that a pathway, which maintains pluripotency in mouse ESCs, promotes differentiation in human ESCs. In this review, we discuss the role of canonical signaling pathways implicated in regulation of pluripotency and differentiation particularly in mouse and human ESCs. We believe that understanding these distinct and at times-opposite mechanisms-is critical for the progress in the field of stem cell biology and regenerative medicine.

Targeting autophagy drug discovery: Targets, indications and development trends

Autophagy plays a vital role in sustaining cellular homeostasis and its alterations have been implicated in the etiology of many diseases. Drugs development targeting autophagy began decades ago and hundreds of agents were developed, some of which are licensed for the clinical usage. However, no existing intervention specifically aimed at modulating autophagy is available. The obstacles that prevent drug developments come from the complexity of the actual impact of autophagy regulators in disease scenarios. With the development and application of new technologies, several promising categories of compounds for autophagy-based therapy have emerged in recent years. In this paper, the autophagy-targeted drugs based on their targets at various hierarchical sites of the autophagic signaling network, e.g., the upstream and downstream of the autophagosome and the autophagic components with enzyme activities are reviewed and analyzed respectively, with special attention paid to those at preclinical or clinical trials. The drugs tailored to specific autophagy alone and combination with drugs/adjuvant therapies widely used in clinical for various diseases treatments are also emphasized. The emerging drug design and development targeting selective autophagy receptors (SARs) and their related proteins, which would be expected to arrest or reverse the progression of disease in various cancers, inflammation, neurodegeneration, and metabolic disorders, are critically reviewed. And the challenges and perspective in clinically developing autophagy-targeted drugs and possible combinations with other medicine are considered in the review.

Targeting CRAF kinase in anti-cancer therapy: progress and opportunities

The RAS/mitogen-activated protein kinase (MAPK) signaling cascade is commonly dysregulated in human malignancies by processes driven by RAS or RAF oncogenes. Among the members of the RAF kinase family, CRAF plays an important role in the RAS-MAPK signaling pathway, as well as in the progression of cancer. Recent research has provided evidence implicating the role of CRAF in the physiological regulation and the resistance to BRAF inhibitors through MAPK-dependent and MAPK-independent mechanisms. Nevertheless, the effectiveness of solely targeting CRAF kinase activity remains controversial. Moreover, the kinase-independent function of CRAF may be essential for lung cancers with KRAS mutations. It is imperative to develop strategies to enhance efficacy and minimize toxicity in tumors driven by RAS or RAF oncogenes. The review investigates CRAF alterations observed in cancers and unravels the distinct roles of CRAF in cancers propelled by diverse oncogenes. This review also seeks to summarize CRAF-interacting proteins and delineate CRAF's regulation across various cancer hallmarks. Additionally, we discuss recent advances in pan-RAF inhibitors and their combination with other therapeutic approaches to improve treatment outcomes and minimize adverse effects in patients with RAF/RAS-mutant tumors. By providing a comprehensive understanding of the multifaceted role of CRAF in cancers and highlighting the latest developments in RAF inhibitor therapies, we endeavor to identify synergistic targets and elucidate resistance pathways, setting the stage for more robust and safer combination strategies for cancer treatment.

Characterization of a Distinct State in the Continuum of Pluripotency Facilitated by Inhibition of PKCζ in Mouse Embryonic Stem Cells

Inhibition of PKC (PKCi) signaling maintains pluripotency of embryonic stem cells (ESCs) across different mammalian species. However, the position of PKCi maintained ESCs in the pluripotency continuum is largely unknown. Here we demonstrate that mouse ESCs when cultured continuously, with PKCi, for 75 days are retained in naïve state of pluripotency. Gene expression analysis and proteomics studies demonstrated enhanced naïve character of PKCi maintained ESCs in comparison to classical serum/LIF (S/L) supported ESCs. Molecular analysis revealed that activation of PKCζ isoform associate with primed state of pluripotency, present in epiblast-like stem cells generated in vitro while inhibition of PKCζ phosphorylation associated with naïve state of pluripotency in vitro and in vivo. Phosphoproteomics and chromatin modification enzyme array based studies showed loss in DNA methyl transferase 3B (DNMT3B) and its phosphorylation level upon functional inhibition of PKCζ as one of the crucial components of this regulatory pathway. Unlike ground state of pluripotency maintained by MEK/GSK3 inhibitor in addition to LIF (2i/LIF), loss in DNMT3B is a reversible phenomenon in PKCi maintained ESCs. Absence of phosphorylation of c-MYC, RAF1, SPRY4 while presence of ERF, DUSP6, CIC and YAP1 phosphorylation underlined the phosphoproteomics signature of PKCi mediated maintenance of naïve pluripotency. States of pluripotency represent the developmental continuum and the existence of PKCi mediated mouse ESCs in a distinct state in the continuum of pluripotency (DiSCo) might contribute to the establishment of stages of murine embryonic development that were non-permissible till date.