Human liver regeneration is characterized by the coordinated expression of distinct microRNA governing cell cycle fate.

In the absence of adequate compensatory regeneration, overwhelming liver damage can cause acute liver failure (ALF) and death without emergent liver transplantation (LT). Auxiliary LT produces satisfactory outcomes in this setting, with the prospect of native liver regeneration sustaining long-term survival. Since animal models only partially recapitulate human liver regeneration, we investigated the molecular mechanisms controlling it in this unique LT setting, as an exemplar of human liver regeneration. We demonstrate coordinated changes in expression of microRNA (miRNA) during regeneration that drive proliferation, innate immunity and angiogenesis. In contrast, failed regeneration in a similar cohort is associated with distinct miRNA enforcing cell cycle inhibition and DNA methylation. The miRNA expression associated with successful or failed regeneration when recapitulated in vitro, triggered expression of cardinal regeneration-linked genes promoting cell cycle entry or inhibition, respectively. Furthermore, inhibition of miRNA 150, 663 and 503, whose downregulation is associated with successful regeneration, induced cell proliferation which a key determinant of successful regeneration. Our data indicate that human liver regeneration may be orchestrated by distinct miRNA controlling key regeneration-linked processes including hepatocyte proliferation. To our knowledge this is the first characterization of molecular processes associated with human liver regeneration.

Microenvironment produced by acute myeloid leukemia cells prevents T cell activation and proliferation by inhibition of NF-kappaB, c-Myc, and pRb pathways.

Tumors produce a variety of immunosuppressive factors which can prevent the proliferation and maturation of a number of normal hemopoietic cell types. We have investigated whether primary acute myeloid leukemia (AML) cells have an effect on normal T cell function and signaling. Tumor cell supernatant (TSN) from AML cells inhibited T cell activation and Th1 cytokine production and also prevented activated T cells from entering the cell cycle. These effects occurred in the absence of AML cell-T cell contact. We have demonstrated that AML TSN contained none of the immunosuppressors described to date, namely gangliosides, nitric oxide, TGF-beta, IL-10, vascular endothelial growth factor, or PGs. Furthermore, IL-2 did not overcome the block, despite normal IL-2R expression. However, the effect was overcome by preincubation with inhibitors of protein secretion and abolished by trypsinization, indicating that the active substance includes one or more proteins. To determine the mechanism of inhibition, we have studied many of the major pathways involved in T cell activation and proliferation. We show that nuclear translocation of NFATc and NF-kappaB are markedly reduced in T cells activated in the presence of primary AML cells. In contrast, calcium mobilization and activation of other signal transduction pathways, namely extracellular signal-regulated kinase1/2, p38, and STAT5 were unaffected, but activation of c-Jun N-terminal kinase 1/2 was delayed. Phosphorylation of pRb by cyclin-dependent kinase 6/4-cyclin D and of p130 did not occur and c-Myc, cyclin D3, and p107 were not induced, consistent with cell cycle inhibition early during the transition from G(0) to G(1). Our data indicate that TSN generated by AML cells induces T cell immunosuppression and provides a mechanism by which the leukemic clone could evade T cell-mediated killing.