IL15 Agonists Overcome the Immunosuppressive Effects of MEK Inhibitors.

Many signal transduction inhibitors are being developed for cancer therapy target pathways that are also important for the proper function of antitumor lymphocytes, possibly weakening their therapeutic effects. Here we show that most inhibitors targeting multiple signaling pathways have especially strong negative effects on T-cell activation at their active doses on cancer cells. In particular, we found that recently approved MEK inhibitors displayed potent suppressive effects on T cells in vitro However, these effects could be attenuated by certain cytokines that can be administered to cancer patients. Among them, clinically available IL15 superagonists, which can activate PI3K selectively in T lymphocytes, synergized with MEK inhibitors in vivo to elicit potent and durable antitumor responses, including by a vaccine-like effect that generated resistance to tumor rechallenge. Our work identifies a clinically actionable approach to overcome the T-cell-suppressive effects of MEK inhibitors and illustrates how to reconcile the deficiencies of signal transduction inhibitors, which impede desired immunologic effects in vivo Cancer Res; 76(9); 2561-72. ©2016 AACR.

The ribosomal basis of Diamond-Blackfan Anemia: mutation and database update.

Diamond-Blackfan Anemia (DBA) is characterized by a defect of erythroid progenitors and, clinically, by anemia and malformations. DBA exhibits an autosomal dominant pattern of inheritance with incomplete penetrance. Currently nine genes, all encoding ribosomal proteins (RP), have been found mutated in approximately 50% of patients. Experimental evidence supports the hypothesis that DBA is primarily the result of defective ribosome synthesis. By means of a large collaboration among six centers, we report here a mutation update that includes nine genes and 220 distinct mutations, 56 of which are new. The DBA Mutation Database now includes data from 355 patients. Of those where inheritance has been examined, 125 patients carry a de novo mutation and 72 an inherited mutation. Mutagenesis may be ascribed to slippage in 65.5% of indels, whereas CpG dinucleotides are involved in 23% of transitions. Using bioinformatic tools we show that gene conversion mechanism is not common in RP genes mutagenesis, notwithstanding the abundance of RP pseudogenes. Genotype-phenotype analysis reveals that malformations are more frequently associated with mutations in RPL5 and RPL11 than in the other genes. All currently reported DBA mutations together with their functional and clinical data are included in the DBA Mutation Database.

Interstitial tonicity controls TonEBP expression in the renal medulla.

Cells in the hyperosmotic kidney medulla, express a transcriptional activator termed tonicity responsive enhancer binding protein (TonEBP). Genes targeted by TonEBP protect kidney cells from the deleterious effects of hyperosmolality by inducing the expression of organic osmolytes and molecular chaperones, and other genes that mediate urine concentration such as aquaporin-2 and urea transporters. We tested here the effect of hypertonicity and hyperosmotic salt in the renal medullary interstitium on the expression TonEBP. When massive water diuresis was induced in rats the medullary sodium concentrations did not change, neither did TonEBP expression. In these animals the medullary tonicity was unchanged despite the production of dilute urine. On the other hand, treatment with the loop diurectic furosemide resulted in a dose-dependent decrease in the medullary sodium concentration causing a reduction in interstitial tonicity. Here, TonEBP expression was blunted in the outer and inner medulla which was due, in part, to decreased mRNA abundance. As expected, the expression of TonEBP target genes in the renal medulla also decreased in response to furosemide. Hence TonEBP expression in the renal medulla is stimulated by interstitial hypertonicity.

TonEBP is inhibited by RNA helicase A via interaction involving the E'F loop.

TonEBP [TonE (tonicity-responsive enhancer)-binding protein] is a transcriptional activator of the Rel family like NF-kappaB (nuclear factor kappaB) and NFAT (nuclear factor of activated T-cells). TonEBP plays a key role in the protection of cells in the kidney medulla from the deleterious effects of hyperosmolality. This is achieved by enhancing expression of HSP70 (heat-shock protein 70) and other genes whose products drive cellular accumulation of organic osmolytes. TonEBP is stimulated by ambient hypertonicity via multiple pathways that regulate nuclear translocation and transactivation. In the present paper, we report that TonEBP is associated in vivo with RHA (RNA helicase A). The N- and C-termini of RHA bound the E'F loop of the DNA-binding domain of TonEBP. The interaction was not affected by DNA binding or dimerization of TonEBP. Overexpression of RHA inhibited the activity of TonEBP; however, catalytic activity of RHA was dispensable for the inhibition. When the ambient tonicity was raised, the TonEBP-RHA interaction decreased, suggesting that dissociation of RHA is a pathway to stimulate TonEBP. We conclude that the E'F loop of TonEBP interacts with RHA like NFAT and NF-kappaB interact with AP1 (activator protein 1) and the high-mobility group protein HMG-I(Y) respectively. While RHA interacts with and stimulates other transcription factors such as CREB (cAMP-response-element-binding protein), NF-kappaB and mineralocorticoid receptor, it inhibits TonEBP.