RNA结合蛋白MSI2与肿瘤北大核心CSCD

Musashi家族是一类进化保守的RNA结合蛋白,Musashi2(MSI2)属于其中一员。MSI2能维持多种组织干细胞功能状态,发挥重要生理作用。新近研究证实,MSI2不仅参与多种恶性肿瘤的发生,其表达水平还能预测肿瘤患者的预后。因而,MSI2在肿瘤中扮演着癌基因的角色,是一些相关肿瘤的潜在治疗靶点。本文就MSI2在肿瘤中的最新研究进行综述。     

兔VX2肝癌模型微波消融后磁共振灌注成像的可行性与应用价值

目的通过兔VX2模型探讨肿瘤消融治疗后动态变化过程中,磁共振灌注成像动态量化研究的可行性及其价值。方法16只新西兰大白兔分为实验组12只,对照组4只。实验组在兔肝脏种植VX2肿瘤后,观察肿瘤直径超过2.0 cm时行微波消融治疗。对比术后当天7、d、14 d及28 d实验组与对照组磁共振灌注成像量化指标—最大增强斜率（MSI）的动态变化差异,并与病理结果对照分析。结果对照组兔及实验组兔术后当天肝实质灌注MSI差异无显著性;实验组兔术前肿瘤与术后当天残留肿瘤的平均MSI差异无显著性;实验组兔残留肿瘤与良性强化组织的MSI差异有显著性。残留肿瘤的时间-信号强度曲线表现为快速上升型;良性强化组织的时间-信号强度曲线表现为缓慢上升型。结论磁共振灌注成像的动态量化研究是可行的,量化指标MSI与消融治疗后各种组织的病理结果相吻合,可更为准确地量化表达病变组织的病理状态的改变。     

miR-145靶向调控DAB2对前列腺癌PC3细胞迁移和侵袭能力的影响

已有研究表明, miR-145在多种肿瘤中低表达, 并与细胞增殖和转移相关。文章通过生物信息学分析并结合体外实验鉴定, 发现DAB2(Disabled homolog 2)为miR-145在肿瘤转移过程中累及的新靶点。DAB2一直被认为是一个重要的抑癌基因, 在多种肿瘤标本中表达低下。然而, 研究发现, 在具高侵袭能力的前列腺癌细胞株PC3中DAB2基因却呈较高水平表达。另外, 外源表达miR-145能显著下调 DAB2表达水平, 并抑制PC3细胞的迁移和侵袭能力, 且这种miR-145诱导的PC3细胞功能缺陷能被DAB2过表达修复。上述结果表明, miR-145能通过靶向调控DAB2而影响高侵袭前列腺癌细胞的迁移和侵袭能力。     

核糖体蛋白参与调控p53诱导活化的分子机制

核转录因子p53是重要的肿瘤抑制因子,具有DNA损伤修复、促细胞凋亡、促细胞分化及增殖抑制等功能,并通过调控细胞周期行进和促进细胞凋亡发挥肿瘤抑制功能。原癌蛋白MDM2为p53的E3泛素化连接酶,MDM2－p53信号轴的功能异常与多种恶性肿瘤的发生发展相关。核糖体蛋白（RP）是蛋白质合成反应的关键调节蛋白,其功能失常与多种疾病相关。近年来的研究发现,RP能通过调节MDM2－p53信号轴在p53相关性肿瘤调控中发挥重要作用。我们根据目前的研究进展,对RP－MDM2－D53信号轴进行简要综述。     

膜联蛋白A2在肿瘤生长调节与细胞骨架活动中的作用

膜联蛋白A2(annexin A2,ANXA2)是一种钙/磷脂结合的多功能蛋白,参与包括信号转导、DNA合成、细胞增殖和凋亡、黏附、迁移等多种生物学行为。近来大量研究表明,ANXA2在多种肿瘤中表达失调,且其表达水平与肿瘤的发生、侵润、转移、临床分期和预后密切相关。本文主要就ANXA2的生物学活性调节及其与肿瘤生长和细胞骨架活动的关系进行综述。     

EZH2作为抗肿瘤免疫治疗靶点研究进展

多梳蛋白复合体(PcG)的核心亚基zeste基因增强子同源物2(Enhancer of zeste homolog2,EZH2)是一种组蛋白甲基转移酶,参与维持细胞密度、干细胞多能性、细胞周期调节等重要的生理作用。研究发现,EZH2在多种肿瘤组织中高表达,是促进肿瘤发生和发展的致癌因子。由于EZH2在正常组织中低表达或者不表达,使其新近被鉴定为一种肿瘤相关抗原。已经在EZH2蛋白分子中鉴定出多条特异性抗原肽,这些抗原肽能激发机体免疫细胞对EZH2表达异常增高肿瘤细胞的杀伤活性。上述研究提示,EZH2可能是一种新的抗肿瘤治疗分子靶点,并在肿瘤免疫治疗中具有潜在的应用价值。就该领域的最新研究进展作一简要综述。     

Numb在肿瘤发生中的研究进展

Numb是重要的细胞命运决定因子,通过选择性剪接和不对称分裂方式来控制细胞的命运。Numb参与肿瘤信号通路,上游有Musashi2、HMGA1途径调控,下游调控Notch、p53、Hedgehog途径,涉及Wnt、TLR等途径,在致癌信号中影响较大。Numb也是Notch信号的负调控因子,通过参与肿瘤抑制,调控血管生成,以及增加癌症的放射敏感性等生理过程来抑制肿瘤的形成。总之,Numb作为重要的调节因子,为肿瘤的治疗提供了新的治疗靶点,具有很大的潜在治疗前景。本文对Numb在肿瘤发病中作用的近期研究予以简要概述。     

MALDI MSI技术在缺血性卒中研究中的应用

基质辅助激光解吸/电离质谱成像(MALDI MSI)技术是新兴的分子成像技术,具有免标记、高空间分辨、高检测特异性等优势,在捕捉、分辨和鉴定各种疾病相关代谢物的组织分布与变化方面具有明显的优势,为揭示多种目标分子在生理/病理条件下的组织空间分布特征及其时空动态变化提供了便利和直观的研究手段。综述了近年来MALDI MSI技术在缺血性卒中研究中的应用,重点阐述了运用MALDI MSI技术研究缺血性卒中发生发展过程中,多种结构与功能各异的内源性小分子在脑中的时空动态变化规律,以期为揭示缺血性卒中发病的分子机制提供科学依据。     

蕉肥间作下微喷灌对蕉园土壤水氮动态及香蕉产量的影响

为研究香蕉—粮肥兼用绿豆间作模式(简称蕉肥间作)下微喷灌对蕉园土壤水氮动态及香蕉产量的影响,试验设置4种不同灌溉定额处理:MSI2(900 m~3·hm~(-2))、MSI3(1 350 m~3·hm~(-2))、MSI4(1 800 m~3·hm~(-2))、MSI5(2 250 m~3·hm~(-2)),以不灌溉和清耕栽培为对照。结果表明:蕉肥间作下绿豆生长期间各灌溉处理土壤棵间蒸发量均呈不同程度的下降,香蕉清耕栽培MSI0土壤棵间蒸发量呈上升趋势。随着灌水量的增加,香蕉棵间蒸发量逐渐增高,MSI5棵间累积蒸发量最高达385.6 mm,分别比MSI2、MSI3、MSI4高12.2%、7.6%、4.9%,导致灌溉水利用效率降低。微喷灌处理提高表层土壤含水量,MSI2、MSI3、MSI4和MSI5处理0～30 cm土层含水量显著高于MSI0和MSI1,在30 cm以下,土壤含水量开始递减。微喷灌还可改善土壤耕层结构,提高土壤有效氮含量。以MSI2处理土壤三相比(2∶1∶1)较为理想,MSI3处理表土层有效氮含量最高。MSI4处理产量高达48 218 kg·hm~(-2),MSI3处理蕉果含糖量高达25.67%。因此,蕉肥间作下通过微喷灌方式,适量灌溉有利于提高香蕉产量和改善品质。     

MSI2通过下调circRNA_001214促进急性髓系白血病细胞HL60生长

Musashi-2（MSI2）是一种RNA结合蛋白质,对维持造血干细胞功能具有重要作用。研究表明,MSI2高表达能促进急性髓系白血病（acute myelocytic leukemia, AML）进展,但其作用机制尚不明确。本研究稳定沉默HL60细胞MSI2后,第1、2、3、4 d对照组的相对细胞生长率分别为1.931 ± 0.027、3.070 ± 0.073、4.017 ± 0.092和4.215 ± 0.246;敲减组分别为1.927 ± 0.035、2.564 ± 0.090、2.825 ± 0.097和3.223 ± 0.182,两组相比具有统计学差异,P<0.001;细胞凋亡明显增加(7.967% ± 0.698% vs 3.400% ± 0.322%., P<0.01);G₀/G₁期细胞比例明显增高（67.430% ± 4.390% vs. 50.360% ± 2.160%, P<0.01）;NUMB蛋白明显上调,LEF1明显下降。环状RNA（circular RNA, circRNA）芯片筛选和荧光定量PCR验证显示,MSI2沉默组circRNA_001214表达水平是对照组3.48倍。这一结果也在NALM6细胞得到证实。进一步用生物信息学分析,显示circRNA_001214最可能与miR-1273a、miR-1273e和miR 5095结合,进而影响参与细胞凋亡相关基因（CYCS、AKT1、BAX、TNFRSF10A、TNFRSF10D）、Wnt信号基因（WNT4、WNT2B、WNT7B、 DKK2、SFRP1、CSNKE1和LEF1）以及参与细胞代谢相关基因（RPE, PGAM4, PGAM1, TAT, CBS、RPE、SUCLG2、PGAM4、PGAM1和 IDNK）。总而言之,MSI2可能通过干扰circRNA_001214生成,减少靶miRNA对凋亡、Wnt信号及细胞代谢相关基因表达的影响,促进细胞生长。     

The RNA binding protein Musashi1 regulates apoptosis,gene expression and stress granule formation in urothelial carcinoma cells

The RNA‐binding protein Musashi1 (MSI1) is a marker of progenitor cells in the nervous system functioning as a translational repressor. We detected MSI1 mRNA in several bladder carcinoma cell lines, but not in cultured normal uroepithelial cells, whereas the paralogous MSI2 gene was broadly expressed. Knockdown of MSI1 expression by siRNA induced apoptosis and a severe decline in cell numbers in 5637 bladder carcinoma cells. Microarray analysis of gene expression changes after MSI1 knockdown significantly up‐regulated 735 genes, but down‐regulated only 31. Up‐regulated mRNAs contained a highly significantly greater number and density of Musashi binding sites. Therefore, a much larger set of mRNAs may be regulated by Musashi1, which may affect not only their translation, but also their turnover. The study confirmed p21^CIP1 and Numb proteins as targets of Musashi1, suggesting additionally p27^KIP1 in cell‐cycle regulation and Jagged‐1 in Notch signalling. A significant number of up‐regulated genes encoded components of stress granules (SGs), an organelle involved in translational regulation and mRNA turnover, and impacting on apoptosis. Accordingly, heat shock induced SG formation was augmented by Musashi1 down‐regulation. Our data show that ectopic MSI1 expression may contribute to tumorigenesis in selected bladder cancers through multiple mechanisms and reveal a previously unrecognized function of Musashi1 in the regulation of SG formation.     

Novel double-negative feedback loop between adenomatous polyposis coli and Musashi1 in colon epithelia

Loss of tumor suppressor adenomatous polyposis coli (APC) is thought to initiate the majority of all colorectal cancers. The predominant theory of colorectal carcinogenesis implicates stem cells as the initiating cells. However, relatively little is known about the function of APC in governing the homeostasis of normal intestinal stem cells. Here, we identify a novel double-negative feedback loop between APC and a translation inhibitor protein, Musashi1 (MSI1), in cultured human colonocytes. We show APC as a key factor in MSI1 regulation through Wnt signaling and identify APC mRNA as a novel target of translational inhibition by MSI1. We propose that APC/MSI1 interactions maintain homeostatic balance in the intestinal epithelium.     

Interplay between the RNA binding‐protein Musashi and developmental signaling pathways

Musashi comprises an evolutionarily conserved family of RNA‐binding proteins (RBP) that regulate cell fate decisions during embryonic development and play key roles in the maintenance of self‐renewal and differentiation of stem cells and adult tissues. More recently, several studies have shown that any dysregulation of MSI1 and MSI2 can lead to cellular dysfunctions promoting tissue instability and tumorigenesis. Moreover, several reports have characterized many molecular interactions between members of the Musashi family with ligands and receptors of the signaling pathways responsible for controlling normal embryonic development: Notch, Transforming Growth Factor Beta (TGF‐β), Wingless (Wnt) and Hedgehog Signaling (Hh); all of which, when altered, are strongly associated with cancer onset and progression, especially in pediatric tumors. In this context, the present review aims to compile possible cross‐talks between Musashi proteins and members of the above cited molecular pathways for which dysregulation plays important roles during carcinogenesis and may be modulated by these RBP.     

Tau oligomers mediate aggregation of RNA‐binding proteins Musashi1 and Musashi2 inducing Lamin alteration

The exact mechanisms leading to neurodegeneration in Alzheimer's disease (AD) and other tauopathies are not yet entirely understood. However, it is known that several RNA‐binding proteins (RBPs) form toxic aggregates and also interact with tau in such granules in tauopathies, including AD. The Musashi (MSI) family of RBPs, consisting of two homologues: Musashi1 and Musashi2, have not been extensively investigated in neurodegenerative diseases. Here, using a tau inducible HEK (iHEK) model we investigate whether MSI proteins contribute to the aggregation of toxic tau oligomers (TauO). Wild‐type and mutant P301L tau iHEK cells are used to study the effect of different tau variants on the cellular localization of MSI proteins. Interestingly, we observe that tau co‐localizes with MSI in the cytoplasm and nuclei, altering the nuclear transport of MSI. Furthermore, incremental changes in the size and density of nuclear MSI/tau foci are observed. We also report here that TauO interact with MSI to cause the formation of distinct nuclear aggregates. Moreover, tau/MSI aggregates induce structural changes to LaminB1, leading to nuclear instability. These results illustrate a possible mechanism of neurodegeneration mediated by the aggregation of MSI proteins and TauO, suggesting that MSI plays a critical role in cellular dysfunction.     

Musashi expression in ��-cells coordinates insulin expression, apoptosis and proliferation in response to endoplasmic reticulum stress in diabetes

Diabetes is associated with the death and dysfunction of insulin-producing pancreatic β-cells. In other systems, Musashi genes regulate cell fate via Notch signaling, which we recently showed regulates β-cell survival. Here we show for the first time that human and mouse adult islet cells express mRNA and protein of both Musashi isoforms, as well Numb/Notch/Hes/neurogenin-3 pathway components. Musashi expression was observed in insulin/glucagon double-positive cells during human fetal development and increased during directed differentiation of human embryonic stem cells (hESCs) to the pancreatic lineage. De-differentiation of β-cells with activin A increased Msi1 expression. Endoplasmic reticulum (ER) stress increased Msi2 and Hes1, while it decreased Ins1 and Ins2 expression, revealing a molecular link between ER stress and β-cell dedifferentiation in type 2 diabetes. These effects were independent of changes in Numb protein levels and Notch activation. Overexpression of MSI1 was sufficient to increase Hes1, stimulate proliferation, inhibit apoptosis and reduce insulin expression, whereas Msi1 knockdown had the converse effects on proliferation and insulin expression. Overexpression of MSI2 resulted in a decrease in MSI1 expression. Taken together, these results demonstrate overlapping, but distinct roles for Musashi-1 and Musashi-2 in the control of insulin expression and β-cell proliferation. Our data also suggest that Musashi is a novel link between ER stress and the compensatory β-cell proliferation and the loss of β-cell gene expression seen in specific phases of the progression to type 2 diabetes.     

Musashi2 predicts poor prognosis and invasion in hepatocellular carcinoma by driving epithelial–mesenchymal transition

The high incidence of recurrence and the poor prognosis of hepatocellular carcinoma (HCC) necessitate the discovery of new predictive markers of HCC invasion and prognosis. In this study, we evaluated the expression pattern of two members of a novel oncogene family, Musashi1 (MSI1) and Musashi2 (MSI2) in 40 normal hepatic tissue specimens, 149 HCC specimens and their adjacent non‐tumourous tissues. We observed that MSI1 and MSI2 were significantly up‐regulated in HCC tissues. High expression levels of MSI1 and MSI2 were detectable in 37.6% (56/149) and 49.0% (73/149) of the HCC specimens, respectively, but were rarely detected in adjacent non‐tumourous tissues and were never detected in normal hepatic tissue specimens. Nevertheless, only high expression of MSI2 correlated with poor prognosis. In addition, MSI2 up‐regulation correlated with clinicopathological parameters representative of highly invasive HCC. Further study indicated that MSI2 might enhance invasion of HCC by inducing epithelial–mesenchymal transition (EMT). Knockdown of MSI2 significantly decreased the invasion of HCC cells and changed the expression pattern of EMT markers. Moreover, immunohistochemistry assays of 149 HCC tissue specimens further confirmed this correlation. Taken together, the results of our study demonstrated that MSI2 correlates with EMT and has the potential to be a new predictive biomarker of HCC prognosis and invasion to help guide diagnosis and treatment of post‐operative HCC patients.     

Musashi2 promotes the progression of pancreatic cancer through a novel ISYNA1‐p21/ZEB‐1 pathway

Our previous studies found overexpression of Musashi2 (MSI2) conduced to the progression and chemoresistance of pancreatic cancer (PC) by negative regulation of Numb and wild type p53 (wtp53). Now, we further investigated the novel signalling involved with MSI2 in PC. We identified inositol‐3‐phosphate synthase 1 (ISYNA1) as a novel tumour suppressor regulated by MSI2. High MSI2 and low ISYNA1 expression were prevalently observed in 91 PC tissues. ISYNA1 expression was negatively correlated with MSI2 expression, T stage, vascular permeation and poor prognosis in PC patients. What's more, patients expressed high MSI2 and low ISYNA1 level had a significant worse prognosis. And in wtp53 Capan‐2 and SW1990 cells, ISYNA1 was downregulated by p53 silencing. ISYNA1 silencing promoted cell proliferation and cell cycle by inhibiting p21 and enhanced cell migration and invasion by upregulating ZEB‐1. However, MSI2 silencing upregulated ISYNA1 and p21 but downregulated ZEB‐1, which can be rescued by ISYNA1 silencing. Moreover, reduction of cell migration and invasion resulting from MSI2 silencing was significantly reversed by ISYNA1 silencing. In summary, MSI2 facilitates the development of PC through a novel ISYNA1‐p21/ZEB‐1 pathway, which provides new gene target therapy for PC.     

MSI2通过下调circRNA_001214促进急性髓系白血病细胞HL60生长

Musashi-2（MSI2）是一种RNA结合蛋白质,对维持造血干细胞功能具有重要作用。研究表明,MSI2高表达能促进急性髓系白血病（acute myelocytic leukemia, AML）进展,但其作用机制尚不明确。本研究稳定沉默HL60细胞MSI2后,第1、2、3、4 d对照组的相对细胞生长率分别为1.931 ± 0.027、3.070 ± 0.073、4.017 ± 0.092和4.215 ± 0.246;敲减组分别为1.927 ± 0.035、2.564 ± 0.090、2.825 ± 0.097和3.223 ± 0.182,两组相比具有统计学差异,P<0.001;细胞凋亡明显增加(7.967% ± 0.698% vs 3.400% ± 0.322%., P<0.01);G₀/G₁期细胞比例明显增高（67.430% ± 4.390% vs. 50.360% ± 2.160%, P<0.01）;NUMB蛋白明显上调,LEF1明显下降。环状RNA（circular RNA, circRNA）芯片筛选和荧光定量PCR验证显示,MSI2沉默组circRNA_001214表达水平是对照组3.48倍。这一结果也在NALM6细胞得到证实。进一步用生物信息学分析,显示circRNA_001214最可能与miR-1273a、miR-1273e和miR 5095结合,进而影响参与细胞凋亡相关基因（CYCS、AKT1、BAX、TNFRSF10A、TNFRSF10D）、Wnt信号基因（WNT4、WNT2B、WNT7B、 DKK2、SFRP1、CSNKE1和LEF1）以及参与细胞代谢相关基因（RPE, PGAM4, PGAM1, TAT, CBS、RPE、SUCLG2、PGAM4、PGAM1和 IDNK）。总而言之,MSI2可能通过干扰circRNA_001214生成,减少靶miRNA对凋亡、Wnt信号及细胞代谢相关基因表达的影响,促进细胞生长。