Inhibitors of isoprenylcysteine carboxylmethyltransferase (Icmt) are promising anti-cancer agents, as modification by Icmt is an essential component of the protein prenylation pathway for a group of proteins that includes Ras GTPases. Cysmethynil, a prototypical indole-based inhibitor of Icmt, effectively inhibits tumor cell growth. However, the physical properties of cysmethynil, such as its low aqueous solubility, make it a poor candidate for clinical development. A novel amino-derivative of cysmethynil with superior physical properties and marked improvement in efficacy, termed compound 8.12, has recently been reported. We report here that Icmt (-/-) mouse embryonic fibroblasts (MEFs) are much more resistant to compound 8.12-induced cell death than their wild-type counterparts, providing evidence that the anti-proliferative effects of this compound are mediated through an Icmt specific mechanism. Treatment of PC3 prostate and HepG2 liver cancer cells with compound 8.12 resulted in pre-lamin A accumulation and Ras delocalization from the plasma membrane, both expected outcomes from inhibition of the Icmt-catalyzed carboxylmethylation. Treatment with compound 8.12 induced cell cycle arrest, autophagy and cell death, and abolished anchorage-independent colony formation. Consistent with its greater in vitro efficacy, compound 8.12 inhibited tumor growth with greater potency than cysmethynil in a xenograft mouse model. Further, a drug combination study identified synergistic antitumor efficacy of compound 8.12 and the epithelial growth factor receptor (EGFR)-inhibitor gefitinib, possibly through enhancement of autophagy. This study establishes compound 8.12 as a pharmacological inhibitor of Icmt that is an attractive candidate for further preclinical and clinical development.
The process of autophagy is situated at the intersection of multiple cell signaling pathways, including cell metabolism, growth, and death, and hence is subject to multiple forms of regulation. We previously reported that inhibition of isoprenylcysteine carboxylmethyltransferase (Icmt), which catalyzes the final step in the post-translational prenylation of so-called CAAX proteins, results in the induction of autophagy which enhances cell death in some cancer cells. In this study, using siRNA-mediated knockdown of a group of small GTPases that are predicted Icmt substrates, we identify Rac3 GTPase as a negative regulator of the process of autophagy. Knockdown of Rac3, but not the closely related isoforms Rac1 and Rac2, results in induction of autophagy. Ectopic expression of Rac3, significantly rescues cells from autophagy and cell death induced by Icmt inhibition, strengthening the notion of an isoform-specific autophagy regulatory function of Rac3. This role of Rac3 was observed in multiple cell lines with varying Rac subtype expression profiles, suggesting its broad involvement in the process. The identification of this less-studied Rac member as a novel regulator provides new insight into autophagy and opens opportunities in identifying additional regulatory inputs of the process.
The immunosuppressive properties of mesenchymal stromal cells (MSCs) have been clinically proven to be effective in treating graft-versus-host disease (GVHD). However, MSC therapy is limited by the need for laborious and expensive manufacturing processes that are fraught with batch-to-batch variability. Substitution of MSC therapy with key MSC-mediated immunomodulatory factors could be an option for GVHD treatment. Using a simulated in vitro model of the immunosuppressive effects of MSC on allogeneic graft reactions, a synergistic 2-factor combination (2FC) of CXCL5 and anti-CCL24 was identified from a panel of over 100 immunomodulatory factors as being superior to MSCs in the modulation of mixed lymphocyte reactions. This 2FC was superior to cyclosporine in ameliorating both moderate and severe GVHD while being equivalent to MSCs in moderate GVHD and superior to MSCs in severe GVHD. Its immunosuppressive efficacy could be further improved by extended treatment. Mechanistic studies revealed that in vitro the 2FC could only reduce the proliferation of Th 1 and Th 17, whereas in vivo CXCL5 acts in concert with anti-CCL24 antibody to reduce not only transplanted Th 1 and Th 17 but also cytotoxic T lymphocytes and natural killer cells to increase mouse immunosuppressive neutrophils without affecting human hematopoietic stem cell reconstitution. Concurrently, it reduced circulating human proinflammatory cytokines IFN-γ, IL-6, IL-17A, IL-8, macrophage inflammatory protein-1β, and monocyte chemoattractant protein-1. Both in vitro and in vivo data suggest that CXCL5 and anti-CCL24 antibody act in concert to ameliorate GVHD via suppression of Th 1 and Th 17 responses. We propose that this novel 2FC could substitute for MSC therapy in GVHD treatment.
Human cord blood–derived γδ T cells (CB
γδ
) display a highly diverse TCR
γδ
repertoire and have a unique subtype composition different from fetal or adult peripheral blood counterparts. We expanded CB
γδ
in vitro using an irradiated Epstein-Barr virus–transformed feeder cell–based modified rapid expansion protocol (REP). Single-cell RNA sequencing tracked progressive differentiation of naïve CB
γδ
into cells expressing neoantigen-reactive tumor-infiltrating lymphocyte as well as tissue-resident memory precursor–like and antigen-presenting cell–like gene signatures. TCR
γδ
clonal tracing revealed a bias toward cytotoxic effector differentiation in a much larger proportion of V
δ
2
−
clones compared to V
δ
2
+
clones, resulting in the former being more cytotoxic at the population level. These clonotype-specific differentiation dynamics were not restricted to REP and were recapitulated upon secondary nonviral antigen stimulations. Thus, our data showed intrinsic cellular differences between major subtypes of human γδ T cells already in operation at early postnatal stage and highlighted key areas of consideration in optimizing cell manufacturing processes.
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