更新于：2024-05-01

TIGAR

TP53 induced glycolysis regulatory phosphatase

更新于：2024-05-01

基本信息

别名

C12orf5、Fructose-2,6-bisphosphatase TIGAR、TIGAR

+ [3]

简介

Fructose-bisphosphatase hydrolyzing fructose-2,6-bisphosphate as well as fructose-1,6-bisphosphate (PubMed:19015259). Acts as a negative regulator of glycolysis by lowering intracellular levels of fructose-2,6-bisphosphate in a p53/TP53-dependent manner, resulting in the pentose phosphate pathway (PPP) activation and NADPH production (PubMed:16839880, PubMed:22887998). Contributes to the generation of reduced glutathione to cause a decrease in intracellular reactive oxygen species (ROS) content, correlating with its ability to protect cells from oxidative or metabolic stress-induced cell death (PubMed:16839880, PubMed:19713938, PubMed:23726973, PubMed:22887998, PubMed:23817040). Plays a role in promoting protection against cell death during hypoxia by decreasing mitochondria ROS levels in a HK2-dependent manner through a mechanism that is independent of its fructose-bisphosphatase activity (PubMed:23185017). In response to cardiac damage stress, mediates p53-induced inhibition of myocyte mitophagy through ROS levels reduction and the subsequent inactivation of BNIP3. Reduced mitophagy results in an enhanced apoptotic myocyte cell death, and exacerbates cardiac damage (By similarity). Plays a role in adult intestinal regeneration; contributes to the growth, proliferation and survival of intestinal crypts following tissue ablation (PubMed:23726973). Plays a neuroprotective role against ischemic brain damage by enhancing PPP flux and preserving mitochondria functions (By similarity). Protects glioma cells from hypoxia- and ROS-induced cell death by inhibiting glycolysis and activating mitochondrial energy metabolism and oxygen consumption in a TKTL1-dependent and p53/TP53-independent manner (PubMed:22887998). Plays a role in cancer cell survival by promoting DNA repair through activating PPP flux in a CDK5-ATM-dependent signaling pathway during hypoxia and/or genome stress-induced DNA damage responses (PubMed:25928429). Involved in intestinal tumor progression (PubMed:23726973).

关联

100 项与 TIGAR 相关的临床结果

登录后查看更多信息

100 项与 TIGAR 相关的转化医学

登录后查看更多信息

0 项与 TIGAR 相关的专利（医药）

登录后查看更多信息

359

项与 TIGAR 相关的文献（医药）

2024-02-19·International journal of molecular sciences

TIGAR Deficiency Blunts Angiotensin-II-Induced Cardiac Hypertrophy in Mice.

Article

作者: Xiaochen He ; Quinesha A Williams ; Aubrey C Cantrell ; Jessie Besanson ; Heng Zeng ; Jian-Xiong Chen

Hypertension is the key contributor to pathological cardiac hypertrophy. Growing evidence indicates that glucose metabolism plays an essential role in cardiac hypertrophy. TP53-induced glycolysis and apoptosis regulator (TIGAR) has been shown to regulate glucose metabolism in pressure overload-induced cardiac remodeling. In the present study, we investigated the role of TIGAR in cardiac remodeling during Angiotensin II (Ang-II)-induced hypertension. Wild-type (WT) and TIGAR knockout (KO) mice were infused with Angiotensin-II (Ang-II, 1 µg/kg/min) via mini-pump for four weeks. The blood pressure was similar between the WT and TIGAR KO mice. The Ang-II infusion resulted in a similar reduction of systolic function in both groups, as evidenced by the comparable decrease in LV ejection fraction and fractional shortening. The Ang-II infusion also increased the isovolumic relaxation time and myocardial performance index to the same extent in WT and TIGAR KO mice, suggesting the development of similar diastolic dysfunction. However, the knockout of TIGAR significantly attenuated hypertension-induced cardiac hypertrophy. This was associated with higher levels of fructose 2,6-bisphosphate, PFK-1, and Glut-4 in the TIGAR KO mice. Our present study suggests that TIGAR is involved in the control of glucose metabolism and glucose transporters by Ang-II and that knockout of TIGAR attenuates the development of maladaptive cardiac hypertrophy.

2023-12-06·Biochemical and biophysical research communications

Bioinformatics analysis and experimental validation reveal the anti-ferroptosis effect of FZD7 in acute kidney injury.

Article

作者: Huanping Long ; Huhai Zhang ; Lingyu Ran ; Lunli Xiang ; Pan Xie ; Liying Zou ; Li Yi ; Xiaopeng Tang ; Liping Chen ; Qixuan Li ; Hongwen Zhao

BACKGROUND:

Ferroptosis plays an important role in acute kidney injury (AKI), but the specific regulatory mechanism of ferroptosis in AKI remains unclear. This study is expected to analyze ferroptosis-related genes (FRGs) in AKI and explore their underlying mechanisms.

RESULTS:

A total of 479 differentially expressed genes (DEGs), including 196 up-regulated genes and 283 down-regulated genes were identified in the AKI chip GSE30718. 341 FRGs were obtained from the Genecard, OMIM and NCBI database. Totally 11 ferroptosis-related DEGs in AKI were found, in which 7 genes (CD44, TIGAR, RB1, LCN2, JUN, ARNTL, ACSL4) were up-regulated and 4 genes (FZD7, EP300, FOXC1, DLST) were down-regulated. Three core genes (FZD7, JUN, EP300) were obtained by PPI and KEGG analysis, among which the function of FZD7 in AKI is unclear. The WGCNA analysis found that FZD7 belongs to a module that was negatively correlated with AKI. Further basic experiments confirmed that FZD7 is down-regulated in mouse model of ischemia-reperfusion-AKI and cellular model of hypoxia-reoxygenation(H/R). In addition, knockdown of FZD7 could further aggravate the down-regulation of cell viability induced by H/R and Erastin, while overexpression of FZD7 can rescue its down-regulation to some extent. Furthermore, we verified that knockdown of FZD7 decreased the expression of GPX4 and overexpression of FZD7 increased the expression of GPX4, suggesting that FZD7 may inhibit ferroptosis by regulating the expression of GPX4 and plays a vital role in the onset and development of AKI.

CONCLUSIONS:

This article revealed the anti-ferroptosis effect of FZD7 in acute kidney injury through bioinformatics analysis and experimental validation, suggesting that FZD7 is a promising target for AKI and provided more evidence about the vital role of ferroptosis in AKI.

2023-12-01·Toxicology research

Repeated radon exposure induced epithelial-mesenchymal transition-like transformation via disruption of p53-dependent mitochondrial function.

Article

作者: Shan Shan ; Xiaoyu Chen ; Aiqing Wang ; Weici Yan ; Qianqian Wu ; Jianmei Wan ; Chengjiao Hong ; Yarong Wang ; Jian Tong ; Hailin Tian ; Lili Xin

Backgrouds:

As a human carcinogen, radon and its progeny are the second most important risk factor for lung cancer after smoking. The tumor suppressor gene, p53, is reported to play an important role in the maintenance of mitochondrial function. In this work, we investigated the association between p53 and p53-responsive signaling pathways and radon-induced carcinogenesis.

Methods:

After repeated radon exposure, the malignant characteristics, cell cycle arrest, cell apoptotic rate, adenosine triphosphate (ATP) content, reactive oxygen species (ROS) level, mitochondrial DNA (mtDNA) copy number as well as indicative biomarkers involved in mitochondrial energy metabolism were evaluated in BEAS-2B cells or BALB-c mouse lung tissue.

Results:

Radon exposure induced epithelial-mesenchymal transition (EMT)-like transformation in BEAS-2B cells, as indicated by increased cell proliferation and migration. Additional mitochondrial alterations, including decreased ATP content, increased ROS levels, mtDNA copy numbers, cell apoptosis, and G2/M cell cycle arrest were observed. Radon exposure caused an energy generation shift from aerobic respiration to glycolysis as reflected by increased expression of TIGAR and p53R2 proteins and decreased expression of SCO2 protein in BEAS-2B cells, and increased expression of p53, SCO2 and TIGAR proteins in mouse lung tissue, respectively. The effects of p53 deficiency on the prevention of mitochondrial dysfunction suggested a protective role of p53 in radon-induced malignant-like features in BEAS-2B cells.

Conclusions:

Repeated radon exposure induced EMT-like transformation in BEAS-2B cells via disruption of mitochondrial function. Activation of p53 and p53-responsive signaling pathways in BEAS-2B cells and BALB-c mice may confer a protective mechanism for radon-induced lung injury.

项与 TIGAR 相关的新闻（医药）

2024-03-12

·BioSpace

SOTIO Presents New Preclinical Data on Enhanced CAR T-Cell Therapies at AACR Annual Meeting

PRAGUE & BOSTON--(BUSINESS WIRE)-- SOTIO Biotech, a clinical-stage immuno-oncology company owned by PPF Group, today announced it will present new preclinical data at the American Association for Cancer Research (AACR) Annual Meeting taking place April 5-10, 2024, in San Diego, California. In a poster at the conference, SOTIO will present data from the company’s BOXR platform of enhanced T cell therapies. SOTIO leveraged the BOXR technology to design CAR T cells enhanced with transgenes encoding GOT2 (glutamine oxaloacetate transaminase) and TIGAR (TP53-induced glycolysis and apoptosis regulator), both of which are believed to play a role in T cell fitness in the hostile solid tumor microenvironment. Compared to unmodified CAR T cells and CAR T cells enhanced with GOT2 solely, CAR T cells enhanced with GOT2 and TIGAR showed better tumor infiltration, lower levels of exhaustion, and superior anti-tumor activity in a mouse model of solid tumors. SOTIO’s lead candidate from the BOXR platform, BOXR1030 — a GOT2-enhanced CAR T-cell therapy — is currently being evaluated in a Phase 1/2 study for patients with solid tumors. A second study to be presented at the meeting investigated the immunostimulatory effects of PARP inhibitors in models of epithelial ovarian cancer, determining their activity on molecular and cellular pathways to inform better combination therapy strategies with cancer immunotherapies. Poster details are as follows: Title: “Dual expression of exogenous glutamine oxaloacetate transaminase (GOT2) and TP53-induced glycolysis and apoptosis regulator (TIGAR) enhance CAR T cell activity in preclinical solid tumor models” Presenting Author: Amy Jensen-Smith Abstract Number: 4012 Date & Time: April 9, 2024, 9:00 a.m. – 12:30 p.m. PT Title: “Immunological control by PARP inhibitors for successful immunotherapy in metastatic ovarian carcinoma” Presenting Author: Peter Holicek Abstract Number: 5278 Date & Time: April 9, 2024, 1:30 p.m. – 5:00 p.m. PT Presentation materials will be available after presentations conclude here. About SOTIO Biotech SOTIO Biotech (SOTIO) is shaping the future of cancer immunotherapies by translating compelling science into patient benefit. The SOTIO pipeline includes SOT102, a next-generation Claudin-18.2-targeted antibody-drug conjugate which entered the clinic in 2022; BOXR1030, a metabolically-enhanced CAR-T cell therapy targeting GPC3-expressing tumors as well as other molecules approaching clinical stage such as SOT201, our next-generation PD-1-inhibiting immunocytokine. SOTIO is a member of the PPF Group. For more information, please visit the company’s website at . SOTIO is a registered trademark of SOTIO Biotech a.s. in selected countries.

免疫疗法AACR会议细胞疗法

2022-10-22

·生物制药小编

肿瘤靶向治疗新靶点：MUC1

MUC1是一种高度糖化的跨膜粘蛋白，位于上皮细胞的管腔表面，保护它们免受极端因素的影响。在癌细胞中，MUC1表达上调，蛋白质结构、糖基化水平和空间分布发生改变。上调的MUC1参与了多种信号通路的调节，并在肿瘤细胞代谢、细胞凋亡、上皮间质转化和转移中发挥重要作用。MUC1糖基化不足导致新的抗原表位的暴露，这些表位可作为治疗和诊断的特异性靶点。目前，基于MUC1的靶向药物包括单抗、ADC、适配子和肿瘤疫苗，其中一些已经进入临床试验。本文就MUC1结构、表达、在肿瘤生物学功能中的作用以及针对MUC1的治疗药物做一个简单介绍。MUC1结构与表达MUC1基因位于染色体1q22上，由7个外显子和6个内含子组成，编码MUCIN家族中的I型跨膜蛋白。通过选择性剪接，MUC1可以形成多种异构体，目前已鉴定出70多种，主要包括MUC1/A、MUC1/B、MUC1/C、MUC1/D、MUC1/X、MUC1/Y等 (图1)。在正常细胞中，MUC1以极性分布分布在上皮细胞的管腔表面，而在肿瘤细胞中，MUC1的分布失去了其极性。图1. MUC1异构体示意图MUC1合成后，由于空间应力作用，被水解成两个多肽片段：MUC1-C和MUC1-N，其通过共价键相连。MUC1-C包括胞外区(MUC1-C/ED)、跨膜区(MUC1-C/TMD)和胞内区(MUC1-C/CD)。MUC1-C/ED是EGFR和其他受体激酶的识别位点。MUC1-C/TMD帮助MUC1锚定在细胞膜上，并将信息从细胞外传递到细胞内。MUC1-C/CD具有多个磷酸化位点和胞内蛋白结合位点，在细胞信号转导中发挥重要作用。MUC1-N包含多个可变数目的串联重复序列(PDTRPAPGSTAP PAHGVTSA)(VNTR)。VNTR形成的多肽骨架为糖基化提供了支架。肽骨架含有一个富含Pro(P)、Thr(T)和Ser(S)的PTS区域，糖链主要通过O-糖苷键与肽骨架上的Ser/Thr相连。在正常细胞中，糖基化隐藏了免疫优势多肽表位，而癌细胞中异常的MUC1糖基化导致免疫优势多肽表位暴露。此外，在肿瘤细胞中，MUC1-N/MUC1-C复合体的破坏导致MUC1-N的脱落和MUC1-C的激活。血液中的游离MUC1-N可以中和MUC1治疗性抗体，使它们无效。MUC1在多种肿瘤中高度表达，包括乳腺癌、膀胱癌、胰腺癌和卵巢癌，并与预后不良有关。MUC1在正常组织和肿瘤中扮演着完全不同的角色。在正常组织中，正常糖基化的MUC1在上皮细胞表面形成一种保护性屏障，保护它们免受极端环境的影响。在癌细胞中，MUC1异常高表达，异常糖基化改变了细胞内的定位，通过许多信号通路参与多种细胞活动的调节。MUC1在肿瘤细胞中的作用MUC1与癌细胞代谢新陈代谢的转化已成为癌细胞的特征之一。癌细胞对新陈代谢进行重新编程，以维持其能量需求并适应恶劣的肿瘤微环境，同时为强劲的增殖创造条件。MUC1在肿瘤代谢重编程中起重要作用，包括葡萄糖代谢、脂肪代谢、核苷酸代谢、嘧啶代谢和谷氨酰胺代谢(图2)。图2. MUC1在肿瘤代谢重编程中的作用MUC1通过调节HIF-1a的表达帮助肿瘤细胞在低氧条件下存活和增殖。研究发现，MUC1通过调节HIF-1a调节癌细胞的代谢重编程，增加癌细胞中葡萄糖的摄取和有氧糖酵解，导致肿瘤进展。在子宫内膜癌中，AGR2通过MUC1/HIF-1a途径诱导糖酵解关键基因(LDHA、PGK1、HK2和ENO1)的表达，增加细胞对葡萄糖的摄取和乳酸的产生，从而促进肿瘤进展。此外，MUC1增强TIGAR的表达，从而促进糖酵解中间产物分流到戊糖磷酸途径。代谢旁路碳流的增加促进了肿瘤细胞的合成代谢。脂代谢紊乱也是癌症最显著的代谢变化之一。癌细胞利用脂类代谢获得能量，促进合成代谢，增加恶性表型。MUC-1通过上调胆固醇和脂肪代谢酶相关基因的转录使得tamoxifen耐药。MUC1介导的EMT与转移上皮肿瘤的癌细胞需要一系列过程才能实现远处转移。从上皮细胞到间充质细胞第一次转化的特征是上皮细胞标志物减少，间充质细胞特征增加。这一过程的完成使得细胞脱离邻近细胞的紧密连接，为进入循环做准备。MUC1通过多条途径促进EMT(图3)。图3. MUC1通过多条途径促进EMT癌细胞在趋化因子的诱导下接近血管或淋巴，并黏附于内皮细胞，然后通过内皮细胞间隙进入循环。在血液循环中，癌细胞需要克服氧化作用才能生存。在乳腺癌中，MUC1通过JAK/STAT信号与STAT1相互作用，刺激干扰素诱导的跨膜蛋白1(IFITM1)转录，进而促进乳腺癌细胞中的EMT。在三阴性乳腺癌中，MUC1-C激活STAT3，与pSTAT3形成复合体，驱动Twist1基因的表达，进而与Twist1直接形成复合体，不仅促进MUC1-C的表达，还在EMT过程中促进EMT转化转录因子(EMT-TF)的表达和多基因表达。此外，MUC1-C通过与ZEB1启动子区域结合的NF-kB p65形成转录复合体来促进ZEB1的转录。反过来，ZEB1与MUC1-C形成ZEB1/MUC1-C复合体，抑制上皮分化诱导剂miR-200C的转录。ZEB1和MUC1-C的协同作用最终导致EMT。在肾癌中，SNAI2促进MUC1的表达，反过来，MUC1-C和b-catenin复合体通过与SNAI2启动子区域相互作用诱导细胞的EMT而增加SNAI2的转录活性。ALKBH2通过抑制E-catenin和通过MUC1增加vimentin的表达来促进膀胱癌细胞的EMT。MUC1与癌细胞凋亡细胞凋亡是一种受基因控制的正常细胞死亡，在细胞对环境的适应和维持动态平衡方面发挥着重要作用。MUC1可抑制由凋亡物质、化疗药物和雌激素诱导的细胞凋亡(图4)。图4. MUC1抑制由凋亡物质、化疗药物和雌激素诱导的细胞凋亡死亡受体超家族的激活诱导了caspase-8的激活，从而引发了一种凋亡反应。MUC1-CD通过直接与caspase-8 p18片段结合并阻止caspase-8募集到死亡诱导信号复合体来抑制细胞凋亡。在化疗药物应激条件下，miR-551b通过抑制过氧化氢酶的表达导致细胞内ROS积聚。累积的ROS促进MUC1的过度表达，而MUC1促进EGFR介导的涉及Akt/c-Flip/COX-2的细胞生存级联的激活并抑制细胞凋亡。此外，MUC1通过激活HCT116中的JNK1抑制顺铂诱导的细胞凋亡。MUC1和STAT1之间的相互作用通过JAK/STAT信号通路驱动IFITM1在芳香酶抑制剂耐药的乳腺癌细胞中过表达，并抑制雌激素诱导的细胞凋亡。MUC1与肿瘤干细胞肿瘤干细胞(CSCs)是肿瘤细胞中具有自我更新能力的一组细胞，被认为是致癌、促进肿瘤进展、肿瘤转移和癌症复发的原因。MUC1-C直接与MYC结合并驱动BRN2、Yamanaka OSKM(OCT4、SOX2、KLF4和MYC)多能因子的激活和神经内分泌(NE)去分化(图5)。图5. MUC1与肿瘤干细胞MUC1-C直接与E2F1结合，激活esBAF复合体(BRG1、ARID1A、BAF60a、BAF155和BAF170)，驱动NOTCH1、NANOG和CSC自我更新。MUC1-C整合了神经内分泌前列腺癌(NEPC)中的MYC和E2F1信号通路。MUC1-C/E2F1/esBAF/ARID1A通路可诱导EMT及NOTCH1、NANOG和MYC的表达。MUC1-C/E2F1/PBAF/PBRM1途径诱导NRF2介导的氧化还原平衡以及OSKM和NANOG的表达。MUC1-C还在PBRM1激活、氧化还原动态平衡、活性氧水平和CSC状态的相互作用中起着关键作用。MUC1与DNA甲基化MUC1和DNA甲基化过程之间有错综复杂的联系。一方面，MUC1可以调节基因甲基化。研究发现发现MUC1-C通过与DNMT1和DNMT3b启动子区域结合来调节DNA甲基化。此外，研究也发现MUC1降低了胃癌细胞中TFF2的甲基化，进而增加了TFF2的表达，并与预后相关。MUC1与肿瘤耐药研究发现，MUC1-CD不仅参与了多药耐药的形成，而且促进了多药耐药(MDR)基因的表达。沉默MUC1的癌细胞可使其对曲妥珠单抗、顺铂和tamoxifen敏感。长期使用曲妥珠单抗会导致对曲妥珠单抗敏感的乳腺细胞中FN、EGF和IL-6上调，促进STAT3的过度激活，从而促进MUC1和MUC4的表达，并通过维持HER2的持续激活最终导致对曲妥珠单抗的抗药性。沉默MUC1-C通过下调HER2激活逆转乳腺癌细胞对曲妥珠单抗的耐药性。Namba等人使用KL-6/MUC1的单抗隔离MUC1，逆转了乳腺癌细胞对曲妥珠单抗介导的耐药性。Keisuke Shigeta等人的研究发现，在顺铂耐药的尿路上皮细胞系中，MUC1-C高表达，并伴有PI3K-AKT-mTOR信号通路和MDR1表达上调。MUC1下调后，PI3K-AKT mTOR信号通路和MDR1水平均降低，对顺铂的敏感性显著提高。这表明MUC1-C通过PI3K-AKTmTOR信号通路激活MDR1，导致尿路上皮癌细胞耐药。MUC1-C在Rab31的启动子上与ERa形成复合体，从而减少了tamoxifen对ERa的占据，最终导致对tamoxifen的耐药性。沉默MUC1-C导致pHER2下调，并恢复tamoxifen的敏感活性。以MUC1为基础的抗肿瘤治疗基于MUC1的治疗主要包括单抗、ADC、肿瘤疫苗、适配子，其中一些已经进入临床实验（图6）。图6. 基于MUC1药物的临床试验单抗以往针对MUC1的单抗治疗主要针对MUC1-N，但在治疗肿瘤方面效果不佳。研究人员目前正在开发针对MUC1-C和MUC1糖基的下一代单抗。Kim等人通过噬菌体展示技术分离出针对MUC1-C的抗体。后续实验证实，SKM1-02、-13和-20抗体显著抑制TNBC细胞的侵袭，SKM1-02显著抑制细胞生长。Naito等人以MUC1糖肽库为基础，设计合成了两种新型的MUC1单抗(1B2和12D10)。1B2和12D10都识别MUC1肽的PDT*R基序上的糖链。1B2识别GalNAc上O6位的O-糖链，而12D10识别相同位置的Neu5Ac。ADC基于MUC1的ADC的靶点包括MUC1蛋白骨架(MUC1-C、MUC1-N)和MUC1糖基相关蛋白。Wu等人开发了一种人源化MUC1抗体(HzMUC1)，它只识别肿瘤细胞表面的MUC1。ADC由HzMUC1与MMAE偶联而成。HzMUC1 MMAE通过诱导G2/M细胞周期停滞和促进细胞凋亡来抑制曲妥珠单抗耐药和HER2阳性乳腺癌细胞生长。Panchamoorthy等人研制了基于MUC1-C的3D1-MMAE ADC药物，并在体外实验中验证了其对MUC1-C阳性肿瘤细胞的杀伤作用。除了在MUC1蛋白骨架上发挥作用的ADC外，MUC1糖基化相关蛋白也是ADC的靶标。例如，SAR566658通过识别MUC1相关的唾液酸糖蛋白CA6来诱导肿瘤细胞死亡，并且在动物肿瘤模型中观察到SAR566658的有效剂量与CA6的表达相关。GSTA是一种特异性糖基化新抗原肽，位于MUC1异常糖基化的串联重复序列区域。MUC1 ADC的通过将GSTA新抗原特异性16A抗体与MMAE偶联来诱导细胞杀伤。研究发现16A-MMAE以剂量依赖的方式抑制肿瘤生长，并且在表达人MUC1的转基因小鼠中不会产生显著的毒性。适配子适配子是具有高度特异性和亲和力的单链DNA、RNA寡核苷酸或具有三维结构的多肽。适配子可以与多种分子结合，包括纳米粒子、两亲性物质、药物等。Hanafi-Bojd开发了一种与二氧化硅纳米颗粒相结合的MUC1适配子，以有效地靶向乳腺癌细胞。Vivo-Llorca等人进一步表明，MUC1适配子包裹的二氧化硅纳米颗粒可以靶向Navitoclax耐药的TNBC细胞并诱导凋亡。Tan L等人的研究以MUC1适配子(APT)为载体，将阿霉素(DOX)导入表达MUC1的乳腺癌细胞(MCF7)。研究发现与游离DOX相比，APT-DOX复合体在不降低对靶细胞的细胞毒性的情况下，将巨噬细胞的存活率提高了近6倍。Khanet等人开发并验证了一种DNA适配子，它能特异性识别剪接变异体MUC1/Y，该剪接变异体在体内抑制乳腺癌细胞的生长。肿瘤疫苗与正常表型相比，恶性表型癌细胞的MUC1糖基化显著改变，肿瘤相关的O-糖链可作为肿瘤疫苗设计的靶点。Bilusic等人研制的基于多靶点的Ad5PSA/MUC-1/Brachyury重组免疫治疗疫苗。对于转移性去势抵抗前列腺癌(MCRPC)的患者，已经完成了I期临床试验，该疫苗耐受性良好。Wu等人开发了一种基于MUC1保护性抗原决定簇的Qβ-MUC1偶联疫苗，对乳腺癌细胞具有显著的选择性，克服了免疫耐受的缺陷。Liu等人构建的纳米颗粒能够将MUC1 mRNA疫苗运送到淋巴结中的树突状细胞(DC)，以激活和放大肿瘤特异性T细胞。mRNA疫苗联合CTLA-4单抗可显著增强机体免疫应答，有效抑制TNBC细胞生长。小编小结MUC1是一种高度糖基化的I型跨膜蛋白，在上皮细胞的管腔表面形成一种保护性屏障。MUC1在肿瘤细胞中高表达，其可通过调节肿瘤细胞代谢、EMT、抑制肿瘤细胞凋亡等方面促进肿瘤进展、增强肿瘤耐药性。因此，MUC1可能成为未来肿瘤靶向治疗的新靶点。目前针对MUC1的疫苗、抗体、ADC适配子正在开发中，一些处于I/II期临床试验，并已经显示出显著的治疗效果。尽管取得了这些进展，MUC1的具体作用机制仍然有待进一步探索。参考文献1.MUC1: An emerging target in cancer treatment and diagnosis.2.MUC1: structure, function, and clinic application in epithelial cancers.

抗体疫苗抗体药物偶联物信使RNA小分子药物