E2f2 Attenuates Apoptosis of Activated T Lymphocytes and Protects from Immune-Mediated Injury through Repression of Fas and FasL

Targeted disruption of E2f2 in mice causes T-cell hyperactivation and a disproportionate cell cycle entry upon stimulation. However, E2f2−/− mice do not develop a lymphoproliferative condition. We report that E2f2 plays a Fas-dependent anti-apoptotic function in vitro and in vivo. TCR-stimulated murine E2f2−/− T cells overexpress the proapoptotic genes Fas and FasL and exhibit enhanced apoptosis, which is prevented by treatment with neutralizing anti-FasL antibodies. p53 pathway is activated in TCR-stimulated E2f2−/− lymphocytes, but targeted disruption of p53 in E2f2−/− mice does not abrogate Fas/FasL expression or apoptosis, implying a p53-independent apoptotic mechanism. We show that E2f2 is recruited to Fas and FasL gene promoters to repress their expression. in vivo, E2f2−/− mice are prone to develop immune-mediated liver injury owing to an aberrant lymphoid Fas/FasL activation. Taken together, our results suggest that E2f2-dependent inhibition of Fas/FasL pathway may play a direct role in limiting the development of immune-mediated pathologies.

MSL3 promotes germline stem cell differentiation in female Drosophila

Gamete formation from germline stem cells (GSCs) is essential for sexual reproduction. However, the regulation of GSC differentiation are incompletely understood. Set2, which deposits H3K36me3 modifications, is required for GSC differentiation during Drosophila oogenesis. We discovered that the H3K36me3 reader Male-specific lethal 3 (MSL3) and histone acetyltransferase complex Ada2a-containing (ATAC) cooperate with Set2 to regulate GSC differentiation in female Drosophila. MSL3, acting independent from the rest of the male specific lethal complex, promotes transcription of genes including a germline enriched ribosomal protein S19 paralog, RpS19b. RpS19b upregulation is required for translation of RNA-binding Fox protein 1 (Rbfox1), a known meiotic cell cycle entry factor. Thus, MSL3 regulates GSC differentiation by modulating translation of a key factor that promotes transition to an oocyte fate.

Growth-dependent signals drive an increase in early G1 cyclin concentration to link cell cycle entry with cell growth

Entry into the cell cycle occurs only when sufficient growth has occurred. In budding yeast, the cyclin Cln3 is thought to initiate cell cycle entry by inactivating a transcriptional repressor called Whi5. Growth-dependent changes in the concentrations of Cln3 or Whi5 have been proposed to link cell cycle entry to cell growth. However, there are conflicting reports regarding the behavior and roles of Cln3 and Whi5. Here, we found no evidence that changes in the concentration of Whi5 play a major role in controlling cell cycle entry. Rather, the data suggest that cell growth triggers cell cycle entry by driving an increase in the concentration of Cln3. We further found that accumulation of Cln3 is dependent upon homologs of mammalian SGK kinases that control cell growth and size. Together, the data are consistent with models in which Cln3 is a crucial link between cell growth and the cell cycle.

Cell Cycle Entry Control in Naïve and Memory CD8+ T Cells

CD8+ T cells play important roles in immunity and immuno-oncology. Upon antigen recognition and co-stimulation, naïve CD8+ T cells escape from dormancy to engage in a complex programme of cellular growth, cell cycle entry and differentiation, resulting in rapid proliferation cycles that has the net effect of producing clonally expanded, antigen-specific cytotoxic T lymphocytes (CTLs). A fraction of activated T cells will re-enter dormancy by differentiating into memory T cells, which have essential roles in adaptive immunity. In this review, we discuss the current understanding of cell cycle entry control in CD8+ T cells and crosstalk between these mechanisms and pathways regulating immunological phenotypes.

Syndecan-2 expression enriches for hematopoietic stem cells and regulates stem cell repopulating capacity

The discovery of novel hematopoietic stem cell (HSC) surface markers can enhance understanding of HSC identity and function. We have discovered a population of primitive bone marrow (BM) HSCs distinguished by their expression of the heparan sulfate proteoglycan, Syndecan-2, which serves as both a marker and regulator of HSC function. Syndecan-2 expression was increased 10-fold in CD150+CD48-CD34-c-Kit+Sca-1+Lineage- cells (long-term - HSCs, LT-HSCs) compared to differentiated hematopoietic cells. Isolation of BM cells based solely on Syndecan-2 surface expression produced a 24-fold enrichment for LT-HSCs, 6-fold enrichment for alpha-catulin+c-kit+ HSCs, and yielded HSCs with superior in vivo repopulating capacity compared to CD150+ cells. Competitive repopulation assays revealed the HSC frequency to be 17-fold higher in Syndecan-2+CD34-KSL cells compared to Syndecan-2-CD34-KSL cells and indistinguishable from CD150+CD34-KSL cells. Syndecan-2 expression also identified nearly all repopulating HSCs within the CD150+CD34-KSL population. Mechanistically, Syndecan-2 regulates HSC repopulating capacity through control of expression of Cdkn1c (p57) and HSC quiescence. Loss of Syndecan-2 expression caused increased HSC cell cycle entry, downregulation of Cdkn1c and loss of HSC long-term - repopulating capacity. Syndecan-2 is a novel marker of HSCs which regulates HSC repopulating capacity via control of HSC quiescence.

Abstract MP213: Activation Of Biosynthetic Pathways Regulates Cardiomyocyte Cell Cycle Induction In Human Cardiomyocyte

Induction of cardiomyocyte proliferation is a promising therapeutic approach to treat heart failure. Several studies have identified metabolism as an important regulator of myocyte proliferation; however, the changes in metabolism during cardiomyocyte division remain unclear. Here, we use ectopic expression of cyclin B1, Cyclin D1, CDK1, and CDK4 (termed 4F) as a tool for understanding how metabolism influences cardiomyocyte proliferation. Mature hiPS-CMs stimulated to proliferate by 4F expression showed significant downregulation of oxidative phosphorylation genes, decreased glucose oxidation, and upregulation of genes that regulate biosynthetic pathways of glucose metabolism such as those involved in NAD(P) + synthesis ( NAMPT, NADK1, NNT ), the hexosamine biosynthetic pathway (HBP) and protein O-GlcNAcylation ( GFPT1 , OGT, OGA ), and the serine biosynthesis pathway (SBP; PHGDH , PSAT1 , SHMT2 ). In 4F-expressing hiPSC-CMs, stable isotope tracing indicated higher enrichment of glucose-derived 13 C in pentose phosphate intermediates, UDP-hexose, phospholipid precursors, NAD + , pyrimidines, UDP-HexNAc, and products of the serine biosynthesis pathway and one-carbon metabolism, suggesting that cell cycle induction activates biosynthetic pathways in cardiomyocytes. Knocking down nicotinamide phosphoribosyltransferase (NAMPT), a critical enzyme in the NAD + salvage pathway, 2 days before 4F overexpression significantly inhibited cell cycle progression in 4F-transduced hiPS-CMs. OGA overexpression, which catalyzes the hydrolytic cleavage of O-GlcNAc from post-transitionally modified proteins, completely abolished 4F-mediated cell cycle induction. Furthermore, NCT503, an inhibitor of the rate-limiting step in the serine biosynthesis pathway, abolished 4F-mediated increases in cell cycle markers. In a gain-of-function approach, we overexpressed phosphoenolpyruvate carboxykinase 2 (PCK2), which can drive carbon from the Krebs cycle to the glycolytic intermediate pool. PCK2 overexpression significantly augmented 4F-mediated cell cycle entry. These findings suggest that a metabolic shift from catabolic to anabolic activity is a critical step for cardiomyocyte cell cycle entry and is required to facilitate proliferation.