MEF2C和SOCS2参与干性调控

C. Vitali, C. Tripodo, M. Colombo
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Recent evidences have demonstrated that SOCS2 is endowed with immunological functions in differentiated cells but no apparent functions were identified in HSC despite its expression in steady state condition. \n \nCombining analysis of human HSC malignancies and studies on murine HSC under steady state and stress conditions [1], we have recently identified a dual involvement of SOCS2 in the regulation of HSC functions in different contexts and demonstrated a novel regulatory mechanism for SOCS2 expression in HSC. \n \nIn mice under hematopoietic stress conditions, such as after 5-Fluorouracil-induced myeloablation, hematopoietic cytokines are rapidly produced to sustain bone marrow (BM) recovery. This event induces activation of the JAK-STAT5 pathway consequently upregulating SOCS2. Such negative feedback loop avoids excessive HSC proliferation and eventually the exhaustion of HSC functions. \n \nThis regulatory function of SOCS2 is completely novel, while the JAK-STAT dependency for its expression is common to the regulatory loop involving other SOCS proteins as well as SOCS2 in other contexts [2]. \n \nAlso, we uncovered SOCS2 involvement in hematopoietic malignancies. High SOCS2 expression characterized the BM of chronic myeloid leukemia (CML) patients and increased along clone progression toward blast crisis. The highest and widespread SOCS2 expression in BM hematopoietic populations was associated with aggressive acute leukemia subsets, namely acute myeloid (AML) and lymphoblastic leukemias (ALL) with MLL rearrangments and BCR/ABL abnormalities. In AML patients, high SOCS2 was significatively associated with poor prognosis. \n \nIn AML and ALL patients, high SOCS2 expression also positively correlated with a list of genes that significanly overlapped with leukemic stemness gene signatures [3], suggesting that SOCS2 and hematopoietic stemness can be associated in the context of hematopietic malignancies. Normal HSC and leukemic stem cells (LSC) share some common molecular programs and, conceivably, similar molecular mechanisms could regulate SOCS2 in these populations. \n \nOur analysis of public gene expression profiles of AML and ALL excluded that SOCS2 expression could be ascribed only to JAK-STAT pathways activation and suggests that alternative STAT-independent molecular programs should be involved. To our knowledge, this is the first indication of STAT-independent regulation of SOCS proteins, raising a question on whether similar regulation might occur for other SOCS family members. Such STAT-independent mechanism might explain the expression of SOCS2 in acute leukemia subsets with MLL rearrangements, which are not strictly associated to constitutive STATs activation. \n \nComputational analysis revealed a novel regulatory network for SOCS2 reliant on MEF2C, a transcriptional factor already associated to ALL with MLL rearrangement [4]. MEF2C-dependent SOCS2 regulation was confirmed in vitro in murine hematopoietic lineage-c-kit+Sca1+ (LSK) BM precursors upon transduction with Mef2c. Such Mef2c-requirement for Socs2 expression in steady state condition can be overcome by cytokine stimulation in case of hematopoietic stress. \n \nIn conclusion SOCS2 appears to take part into a stemness program that is MEF2C-dependent while STAT-independent, a condition than can be inverted in case of stress-induced hematopoiesis. Moreover, the program fronted by MEF2C confers stemness features to the leukemic clones of AML and of ALL with MLL rearrangement, and is detrimental for the patients. \n \n \n \nFigure 1 \n \nSchematic representation of SOC2 involvement in different hematopoietic settings: normal, steady-state hematopoiesis; myeloablation-induced stress hematopoiesis; malignant hematopoiesis","PeriodicalId":94164,"journal":{"name":"Oncoscience","volume":"31 1","pages":"936 - 937"},"PeriodicalIF":0.0000,"publicationDate":"2015-12-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"MEF2C and SOCS2 in stemness regulation\",\"authors\":\"C. Vitali, C. Tripodo, M. 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引用次数: 0

摘要

造血干细胞(HSC)的生理干性依赖于稳态下组成活性的机制,是维持终身造血干细胞库的基础。另一方面,由部分重叠的分子回路维持的类似的干细胞特征,最近成为人们关注的焦点,赋予白血病克隆具有侵略性。细胞因子信号传导2抑制因子(Suppressor of Cytokine signaling 2, SOCS2)属于SOCS家族,由8个具有相似结构的成员(SOCS1-7和CIS)组成,它们在JAK/STAT激活后被诱导,并发挥负调控作用。最近的研究表明,SOCS2在分化细胞中具有免疫功能,但在HSC中稳态表达,未发现明显的功能。结合对人类HSC恶性肿瘤的分析以及稳态和应激条件下小鼠HSC的研究[1],我们最近发现了SOCS2在不同环境下对HSC功能的双重调控,并证明了SOCS2在HSC中表达的一种新的调控机制。在造血应激条件下的小鼠,如5-氟尿嘧啶诱导的骨髓消融后,造血细胞因子迅速产生以维持骨髓(BM)恢复。这一事件诱导JAK-STAT5通路的激活,从而上调SOCS2。这种负反馈循环避免了造血干细胞过度增殖,最终耗尽造血干细胞的功能。SOCS2的这种调控功能是全新的,而其表达的JAK-STAT依赖性在涉及其他SOCS蛋白的调控环以及其他情况下的SOCS2中是共同的[2]。此外,我们发现SOCS2参与造血恶性肿瘤。SOCS2高表达是慢性髓系白血病(CML)患者BM的特征,并随着克隆向母细胞危象的进展而增加。在BM造血人群中,SOCS2的最高表达和广泛表达与侵袭性急性白血病亚群有关,即急性髓细胞白血病(AML)和淋巴细胞白血病(ALL),伴有MLL重排和BCR/ABL异常。在AML患者中,高SOCS2与不良预后显著相关。在AML和ALL患者中,SOCS2的高表达也与一系列与白血病干性基因特征显著重叠的基因呈正相关[3],这表明在造血恶性肿瘤的背景下,SOCS2和造血干性可能存在关联。正常HSC和白血病干细胞(LSC)具有一些共同的分子程序,可以想象,相似的分子机制可以调节这些人群中的SOCS2。我们对AML和ALL的公开基因表达谱的分析排除了SOCS2表达可能仅归因于JAK-STAT通路的激活,并提示可能涉及其他与stat无关的分子程序。据我们所知,这是SOCS蛋白独立于stat调控的第一个迹象,提出了一个问题,即是否类似的调控可能发生在其他SOCS家族成员身上。这种与stat无关的机制可能解释了SOCS2在MLL重排的急性白血病亚群中的表达,而MLL重排与组成型stat激活没有严格的关联。计算分析揭示了SOCS2依赖于MEF2C的一个新的调控网络,MEF2C是一个已经与ALL和MLL重排相关的转录因子[4]。Mef2c依赖性的SOCS2调节在体外被Mef2c转导的小鼠造血谱系-c-kit+Sca1+ (LSK) BM前体中证实。在稳态条件下,这种对Socs2表达的mef2c需求可以在造血应激情况下通过细胞因子刺激来克服。综上所述,SOCS2似乎参与了一个依赖mef2c而不依赖stat的干细胞程序,这种情况在应激诱导的造血中可以逆转。此外,MEF2C前端的程序赋予AML和ALL的MLL重排白血病克隆干细胞特征,对患者不利。图1不同造血环境下SOC2参与的示意图:正常、稳态造血;清髓诱导应激造血;恶性造血作用
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MEF2C and SOCS2 in stemness regulation
The physiologic stemness of hematopoietic stem cells (HSC) relies on mechanisms constitutively active under steady state and is fundamental to maintain a lifelong HSC reservoir. On the other side, similar stemness features sustained by partially overlapping molecular circuits, which have recently come into focus, confer aggressive aggressiveness in leukemia clones. Suppressor of Cytokine Signalling 2 (SOCS2) belongs to the SOCS family, comprising eight members (SOCS1–7 and CIS) with similar structures, which are induced upon JAK/STAT activation and function as negative regulators. Recent evidences have demonstrated that SOCS2 is endowed with immunological functions in differentiated cells but no apparent functions were identified in HSC despite its expression in steady state condition. Combining analysis of human HSC malignancies and studies on murine HSC under steady state and stress conditions [1], we have recently identified a dual involvement of SOCS2 in the regulation of HSC functions in different contexts and demonstrated a novel regulatory mechanism for SOCS2 expression in HSC. In mice under hematopoietic stress conditions, such as after 5-Fluorouracil-induced myeloablation, hematopoietic cytokines are rapidly produced to sustain bone marrow (BM) recovery. This event induces activation of the JAK-STAT5 pathway consequently upregulating SOCS2. Such negative feedback loop avoids excessive HSC proliferation and eventually the exhaustion of HSC functions. This regulatory function of SOCS2 is completely novel, while the JAK-STAT dependency for its expression is common to the regulatory loop involving other SOCS proteins as well as SOCS2 in other contexts [2]. Also, we uncovered SOCS2 involvement in hematopoietic malignancies. High SOCS2 expression characterized the BM of chronic myeloid leukemia (CML) patients and increased along clone progression toward blast crisis. The highest and widespread SOCS2 expression in BM hematopoietic populations was associated with aggressive acute leukemia subsets, namely acute myeloid (AML) and lymphoblastic leukemias (ALL) with MLL rearrangments and BCR/ABL abnormalities. In AML patients, high SOCS2 was significatively associated with poor prognosis. In AML and ALL patients, high SOCS2 expression also positively correlated with a list of genes that significanly overlapped with leukemic stemness gene signatures [3], suggesting that SOCS2 and hematopoietic stemness can be associated in the context of hematopietic malignancies. Normal HSC and leukemic stem cells (LSC) share some common molecular programs and, conceivably, similar molecular mechanisms could regulate SOCS2 in these populations. Our analysis of public gene expression profiles of AML and ALL excluded that SOCS2 expression could be ascribed only to JAK-STAT pathways activation and suggests that alternative STAT-independent molecular programs should be involved. To our knowledge, this is the first indication of STAT-independent regulation of SOCS proteins, raising a question on whether similar regulation might occur for other SOCS family members. Such STAT-independent mechanism might explain the expression of SOCS2 in acute leukemia subsets with MLL rearrangements, which are not strictly associated to constitutive STATs activation. Computational analysis revealed a novel regulatory network for SOCS2 reliant on MEF2C, a transcriptional factor already associated to ALL with MLL rearrangement [4]. MEF2C-dependent SOCS2 regulation was confirmed in vitro in murine hematopoietic lineage-c-kit+Sca1+ (LSK) BM precursors upon transduction with Mef2c. Such Mef2c-requirement for Socs2 expression in steady state condition can be overcome by cytokine stimulation in case of hematopoietic stress. In conclusion SOCS2 appears to take part into a stemness program that is MEF2C-dependent while STAT-independent, a condition than can be inverted in case of stress-induced hematopoiesis. Moreover, the program fronted by MEF2C confers stemness features to the leukemic clones of AML and of ALL with MLL rearrangement, and is detrimental for the patients. Figure 1 Schematic representation of SOC2 involvement in different hematopoietic settings: normal, steady-state hematopoiesis; myeloablation-induced stress hematopoiesis; malignant hematopoiesis
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