预约演示

更新于：2025-05-07

PSMB9

更新于：2025-05-07

基本信息

别名

beta1i、large multifunctional peptidase 2、LMP2

+ [15]

简介

The proteasome is a multicatalytic proteinase complex which is characterized by its ability to cleave peptides with Arg, Phe, Tyr, Leu, and Glu adjacent to the leaving group at neutral or slightly basic pH (PubMed:33727065, PubMed:34819510). The proteasome has an ATP-dependent proteolytic activity. This subunit is involved in antigen processing to generate class I binding peptides. Replacement of PSMB6 by PSMB9 increases the capacity of the immunoproteasome to cleave model peptides after hydrophobic and basic residues.

关联

项与 PSMB9 相关的药物

Zetomipzomib

泽托佐米

靶点

PSMB8 x PSMB9

作用机制

PSMB8抑制剂 [+1]

在研机构

Kezar Life Sciences, Inc. [+2]

原研机构

Onyx Pharmaceuticals, Inc.

在研适应症

自身免疫性肝炎 [+5]

非在研适应症

自身免疫性溶血性贫血 [+1]

最高研发阶段临床2期

首次获批国家/地区-

首次获批日期1800-01-20

IPSI-001

靶点

PSMB9

作用机制

PSMB9抑制剂

在研机构-

原研机构

The University of Texas MD Anderson Cancer Center

在研适应症-

非在研适应症

多发性骨髓瘤

最高研发阶段无进展

首次获批国家/地区-

首次获批日期1800-01-20

LU-001i

靶点

PSMB9

作用机制

PSMB9抑制剂

在研机构-

原研机构

University of Leiden

在研适应症-

非在研适应症

肿瘤

最高研发阶段无进展

首次获批国家/地区-

首次获批日期1800-01-20

项与 PSMB9 相关的临床试验

CTR20240905

/ Terminated临床2期

一项在活动性狼疮肾炎患者中比较 Zetomipzomib (KZR-616) 30 mg 或 60 mg 与安慰剂的疗效和安全性的 IIb 期、随机、对照、双盲、多中心研究

评估 Zetomipzomib 在活动性 III 或 IV 型（伴或不伴 V 型；III/IV +/-V 型）狼疮肾炎 (LN) 和单纯 V 型 LN 患者中的疗效和安全性。

开始日期2024-04-24

申办/合作机构

云顶新耀医药科技有限公司

NCT05781750

/ Terminated临床2期

A Phase 2b, Randomized, Controlled Double-blind, Multicenter Study Comparing the Efficacy and Safety of Zetomipzomib (KZR-616) 30 Mg or 60 Mg with Placebo in Patients with Active Lupus Nephritis

The purpose of this study is to assess the efficacy and safety of zetomipzomib (30 mg or 60 mg) compared with placebo in achieving renal response after 52 weeks of treatment in patients with active lupus nephritis (LN).

开始日期2023-11-03

申办/合作机构

Kezar Life Sciences, Inc.

NCT05569759

/ Active, not recruiting临床2期

A Randomized, Double-blind, Placebo-controlled, Phase 2a Study With Open-label Extension to Evaluate the Safety and Efficacy of Zetomipzomib (KZR-616) in Patients With Autoimmune Hepatitis

This is a Phase 2a, multi-center, placebo-controlled study in which patients with autoimmune hepatitis will receive zetomipzomib or placebo in addition to standard-of-care for 24 weeks; an optional open-label extension period allows patients to receive zetomipzomib (KZR-616) for an additional 24 weeks of treatment.

开始日期2023-05-23

申办/合作机构

Kezar Life Sciences, Inc.

100 项与 PSMB9 相关的临床结果

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100 项与 PSMB9 相关的转化医学

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0 项与 PSMB9 相关的专利（医药）

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227

项与 PSMB9 相关的文献（医药）

2025-03-24·Cureus

Influence of PSMB6 and PSMB9 Genetic Polymorphisms on Bortezomib-Based Therapy Response in Newly Diagnosed Multiple Myeloma

Article

作者: Sood, Nidhi ; Hamide, Abdoul ; Dubashi, Biswajit ; Jayanthi, Mathaiyan ; Munirajan, A K

BACKGROUNDBortezomib (BTZ)-based regimens play a crucial role in the treatment of multiple myeloma (MM), significantly improving patient outcomes. BTZ, a proteasome inhibitor, interferes with cellular processes essential for cancer cell growth and survival, resulting in high response rates. Its use in initial and recurrent treatment strategies has been associated with extended disease control and improved long-term outcomes, contributing to overall survival. This study aimed to delineate the clinical characteristics of newly diagnosed MM patients and investigate the influence of single nucleotide polymorphisms (SNPs) in PSMB6 and PSMB9 genes on the risk and response to BTZ-based chemotherapy, in comparison with the control group.METHODSThis prospective study was conducted at Jawaharlal Institute of Postgraduate Medical Education and Research (JIPMER), Pondicherry, India, comprising 92 newly diagnosed MM cases and 92 controls. Patient selection was based on receiving first-line BTZ therapy with available outcome data. DNA was extracted from peripheral blood samples, followed by SNP analysis using real-time polymerase chain reaction (PCR) with appropriate validation and quality control measures. The patients were stratified into good responders and poor responders. The association of genetic polymorphism with the response to BTZ treatment was carried out using chi-square. Survival analysis was conducted using Kaplan-Meier to estimate the overall survival (OS) and progression-free survival (PFS).RESULTSIn our study, the median age of participants was 55 years, with a predominant 71.7% being males. Backache (66.3%) emerged as the most commonly reported symptom in patients followed by myalgia (53.3%) and bony swelling (12%). The GA+AA genotype in PSMB6 (rs3169950) was significantly more prevalent in poor responders compared to good responders (odds ratio (OR)=3.20, p=0.011), indicating a potential genetic marker for treatment response. The presence of the GA+AA genotype in PSMB6 gene rs3169950 was significantly higher among poor responders compared to good responders (OR=3.200, p=0.011). Likewise, the GA+AA genotype of the PSMB9 gene (rs17587) was predominantly observed among poor responders (OR=3.08, p=0.011). However, no differences were noted in survival analysis.CONCLUSIONThe findings of this study represent a potential breakthrough, indicating that common genetic variants may significantly influence the development of MM and impact treatment response, providing valuable insights for predicting patient outcomes with BTZ-based therapies.

2025-03-01·Med

DHDH-mediated D-xylose metabolism induces immune evasion in triple-negative breast cancer

Article

作者: Liu, Guang-Yu ; Gong, Yue ; Ling, Yun-Xiao ; Shao, Zhi-Ming ; Ling, Yun-xiao ; Zhao, Qian ; Wu, Si-Yu ; Liu, Guang-yu ; Jiang, Yi-Zhou ; Wu, Si-yu ; He, Li-Hua ; Wu, Huai-liang ; Ji, Peng ; Wu, Huai-Liang

BACKGROUNDAlthough the prognosis of triple-negative breast cancer (TNBC) has significantly improved in the era of immunotherapy, many TNBC patients are resistant to therapies, and their disease progresses rapidly. Deciphering the metabolic mechanisms regulating anticancer immunity will provide new insights into therapeutic strategies for TNBC.METHODSIn this study, we performed bioinformatics analysis in our multi-omics TNBC database and identified that a metabolic enzyme, dihydrodiol dehydrogenase (DHDH), might promote the phenotype of "cold tumor" in TNBC. The biological function of DHDH was verified by in vitro and in vivo functional experiments, and the potential molecular mechanism of DHDH promoting TNBC immune escape was further explored.FINDINGSMechanistically, DHDH mediated the synthesis and depletion of the substrate D-xylose and inhibited the activation of the proteasome subunit beta type 9 (PSMB9) and further induction of the immune response. We demonstrated that D-xylose supplementation could enhance the proliferation of CD8⁺ T cells and the expression of cytotoxic markers against cocultured DHDH-wild type (WT) cells. Consistently, D-xylose supplementation in vivo promoted CD8⁺ T cell infiltration and the expression of cytotoxic markers and increased the sensitivity of DHDH-overexpressing tumors to immune checkpoint blockade (ICB).CONCLUSIONSOur findings reveal that a D-xylose-regulated PSMB9-dependent pathway governs tumor-intrinsic immunogenicity and, hence, the sensitivity to ICB, which may provide approaches to promote the "cold-to-hot" transition in TNBC.FUNDINGThis study was funded by the National Key Research and Development Plan of China, Shanghai Science and Technology Commission, National Natural Science Foundation of China, and China Postdoctoral Science Foundation.

2025-03-01·International Immunopharmacology

A druggable targets discovery strategy for diseases (DTDS): Taking Rheumatoid arthritis as a case

Article

作者: Xu, Zhenzhen ; Yuan, Anlei ; Zheng, Lulu ; Qiao, Liansheng ; Wang, Zewen ; Liu, Kaiyang ; Zhao, Shuai ; Ren, Yue ; Zhang, Yanling ; Bi, Shijie ; Liu, Chaoqun ; Li, Beiyan

Identifying effective druggable targets with disease-specific for diseases is a tremendous challenge in new drug development. However, current studies of druggable targets identification are most based on either druggability or disease-specific, lacking a combination of two factors. To further improve the accuracy of druggable targets discovery, a druggable target discovery strategy for diseases (DTDS) was proposed, which combined druggable targets prediction by machine learning and key targets identification by tissue-level and cellular-level transcriptomics analysis. Rheumatoid arthritis (RA), an autoimmune disease that cannot be treated entirely, was taken as a case. First, the protein-protein interaction network was constructed as the disease background network, and the classification models were established based on the topological parameters of known RA-druggable targets with druggability and non-RA targets without therapeutic effects on RA. 168 potential druggable targets were predicted by the classification models from 264 RA-related targets. Subsequently, 40 RA-specific targets were identified by tissue-level and cellular-level transcriptomics analysis from 168 potential druggable targets. Most of them were RA-druggable targets except PSMB9 and PTPRC. Finally, PSMB9 and PTPRC were further verified by in vitro experiments. The results showed that the inhibitor of PSMB9 or PTPRC could effectively inhibit inflammation and abnormal proliferation of synovial cells, proving that PSMB9 and PTPRC were potential RA-druggable targets, and further indicating that DTDS had high accuracy. In conclusion, the DTDS strategy established in this study is reliable and has been proven in identification of potential RA-druggable targets, which is expected to provide ideas and methods for systematic discovery of potential druggable targets for diseases.

项与 PSMB9 相关的新闻（医药）

2024-11-12

·肿瘤界

Cell子刊 | 柳光宇/江一舟/龚悦团队揭示三阴性乳腺癌“冷到热”转变的关键介导因子！

点击蓝字关注我们 2024年11月8日，复旦大学附属肿瘤医院柳光宇、江一舟、龚悦作为共同通讯在Med（IF=12.8）杂志在线发表了题为“DHDH-mediated D-xylose metabolism induces immune evasion in triple-negative breast cancer”的研究论文，该研究发现DHDH介导的D-木糖（D-xylose）代谢诱导三阴性乳腺癌（TNBC）的免疫逃逸。 TNBC病理学定义为雌激素受体和孕激素受体的表达缺失和人类表皮生长因子受体2（HER2）的基因扩增缺失，以其侵袭性和异质性而闻名，在不同分子亚型的乳腺癌中预后最差。目前，虽然免疫检查点阻断（ICB）疗法在新辅助和辅助治疗中取得了巨大成功，但化疗仍然是TNBC的标准治疗选择，然而，由于疾病的异质性，许多TNBC患者由于免疫浸润低、免疫细胞耗竭程度高以及许多其他因素而表现出免疫治疗抵抗。因此，由于免疫疗法在一些TNBC患者中的有效作用，发现和探索与免疫逃逸相关的基因正成为广泛研究的焦点。代谢重编程被认为是肿瘤发生和进展的标志。有证据表明，代谢途径、代谢酶和代谢物可能在肿瘤免疫微环境（TIME）和癌细胞之间的信号传导、相互作用和调节中起调节作用。既往报道揭示了中国人群中TNBC的转录组、基因组和代谢组图谱。多组学分析表明，靶向代谢重编程可以增强对TNBC的免疫治疗效果。TNBC可以分为以下三个亚型，具有明显的基于TIME的特征：簇1为"免疫荒漠型"，簇2为"先天性免疫失活型"，簇3为"免疫炎症型"。免疫炎症型对应俗称的“热肿瘤”，免疫荒漠型和先天性免疫失活型皆称为“冷肿瘤”。热肿瘤高表达免疫检查点分子，且从ICB治疗中获益，尽管已经建立了精确的分类系统来识别热肿瘤，但该人群仅占所有TNBC的28%。因此，识别免疫炎症型肿瘤，将非免疫炎症型肿瘤转化为免疫炎症型肿瘤，并增加联合免疫治疗的益处是新兴的临床问题。机理模式图（图源自Med）在这项最新研究中，研究团队对复旦大学上海肿瘤中心三阴性乳腺癌（FUSCC TNBC）多组学数据库进行了生物信息学分析，确定了一种关键代谢酶-二氢二醇脱氢酶（DHDH），可能促进了TNBC的“冷肿瘤”表型，并进一步通过体内外功能实验验证DHDH的生物学功能，探索了DHDH促进TNBC免疫逃逸的潜在分子机制。从机制上来说，DHDH介导了D-木糖的合成和消耗，并抑制PSMB9蛋白的活化和进一步诱导免疫应答。证明了D-木糖可以增强CD8+T细胞的增殖和对共培养的DHDH-野生型细胞的细胞毒性标志物的表达。在体内补充D-木糖促进了CD8+T细胞浸润和细胞毒性标志物的表达，并增加了DHDH过表达的肿瘤对ICB的敏感性。这些研究结果表明，D-木糖调节的PSMB9依赖性通路控制着肿瘤的固有免疫原性，因此也控制着对ICB的敏感性，这可能为促进TNBC的“由冷向热”转变提供了新方法。推荐阅读 ● 顶刊BMJ发表邵志敏/王中华/江一舟教授团队三阴性乳腺癌研究最新结果 ● 世界乳腺癌宣传日丨一文收藏86部乳腺癌指南&共识声明：本文由“肿瘤界”整理与汇编，欢迎分享转载，如需使用本文内容，请务必注明出处。来源：iNature 编辑：lagertha 审核：松月

免疫疗法

2024-11-11

·生物世界

Cell子刊：柳光宇/江一舟/龚悦团队揭示三阴性乳腺癌免疫逃逸新机制，并提出潜在治疗策略

编辑丨王多鱼排版丨水成文三阴性乳腺癌（TNBC）有着转移率高、预后差、患者生存率低等特征，是最具侵袭性和最致命的乳腺癌亚型，其缺乏雌激素受体（ER）和孕激素受体（PR），以及人表皮生长因子受体2（HER2）这几个乳腺癌治疗靶点，也因此得名。虽然三阴性乳腺癌（TNBC）的预后在当前的免疫治疗时代得到了显著改善，但许多TNBC患者对免疫治疗产生抵抗，疾病进展迅速。解析调控抗肿瘤免疫的代谢机制将为TNBC的治疗策略提供新思路。 2024年11月7日，复旦大学附属肿瘤医院柳光宇、江一舟、龚悦等人在 Cell 子刊 Med 上发表了题为：DHDH-mediated D-xylose metabolism induces immune evasion in triple-negative breast cancer 的研究论文。研究团队对复旦大学上海肿瘤中心三阴性乳腺癌（FUSCC TNBC）多组学数据进行生物信息分析，发现了与低免疫浸润相关的关键代谢酶二氢二醇脱氢酶（DHDH），并进一步揭示了其促进肿瘤免疫逃逸的机制。该研究还发现，在体内补充D-木糖（DHDH的底物）促进了CD8+T细胞浸润和细胞毒性标志物的表达，并增加了DHDH过表达的肿瘤对免疫检查点阻断疗法（ICB）的敏感性。这一发现为在DHDH高表达的三阴性乳腺癌（TNBC）患者中将D-木糖或富含木糖的饮食（例如高纤维膳食）与免疫治疗联合，提供了理论支持。在这项最新研究中，研究团队对复旦大学上海肿瘤中心三阴性乳腺癌（FUSCC TNBC）多组学数据库进行了生物信息学分析，确定了一种关键代谢酶——二氢二醇脱氢酶（DHDH），可能促进了TNBC的“冷肿瘤”表型，并进一步通过体内外功能实验验证DHDH的生物学功能，探索了DHDH促进TNBC免疫逃逸的潜在分子机制。从机制上来说，DHDH介导了底物D-木糖（D-xylose）的合成和消耗，并抑制PSMB9蛋白的活化和进一步诱导免疫应答。证明了D-木糖可以增强CD8+T细胞的增殖和对共培养的DHDH-野生型细胞的细胞毒性标志物的表达。在体内补充D-木糖促进了CD8+T细胞浸润和细胞毒性标志物的表达，并增加了DHDH过表达的肿瘤对免疫检查点阻断疗法（ICB）的敏感性。这些研究结果表明，D-木糖调节的PSMB9依赖性通路控制着肿瘤的固有免疫原性，因此也控制着对免疫检查点阻断疗法（ICB）的敏感性，这可能为促进三阴性乳腺癌（TNBC）的“由冷向热”转变提供了新方法。论文链接： https://www-cell-com.libproxy1.nus.edu.sg/med/abstract/S2666-6340(24)00410-0 设置星标，不错过精彩推文开放转载欢迎转发到朋友圈和微信群微信加群为促进前沿研究的传播和交流，我们组建了多个专业交流群，长按下方二维码，即可添加小编微信进群，由于申请人数较多，添加微信时请备注：学校/专业/姓名，如果是PI/教授，还请注明。点在看，传递你的品味

免疫疗法

2024-11-10

·ioncology

木糖可促进三阴性乳腺癌免疫疗效

点击蓝字，关注我们三阴性乳腺癌是雌激素受体、孕激素受体、HER2均为阴性的一类乳腺癌，大约占全部乳腺癌的15%，与其他乳腺癌相比，其异质性、侵袭性、复发转移率相对较高，一直以来是临床治疗的难题。此外，虽然化疗联合免疫治疗已经对三阴性乳腺癌的治疗取得极大成功，但是许多患者仍对免疫治疗并不敏感。2019年，复旦大学附属肿瘤医院揭示了三阴性乳腺癌内部的免疫微环境异质性，提出三阴性乳腺癌“复旦免疫微环境分型”，即免疫沙漠型、免疫失活型、免疫炎症型。同时，复旦大学附属肿瘤医院前期研究亦系统性解析了三阴性乳腺癌代谢图谱，揭示了其代谢的异质性。深入研究三阴性乳腺癌免疫代谢失调的分子机制，探索潜在促进三阴性乳腺癌“冷肿瘤”转变为“热肿瘤”的代谢靶点，是亟待解决的临床科学问题。 2024年11月8日，美国细胞出版社旗舰期刊《医学》在线发表复旦大学附属肿瘤医院吴怀亮①、龚悦①✉、凌云霄、邬思雨、吉芃、赵谦、何李华、邵志敏、江一舟✉、柳光宇✉等学者的研究报告，首次发现关键代谢酶二氢二醇脱氢酶（DHDH）与三阴性乳腺癌“冷肿瘤”微环境形成密切相关，并发现DHDH可以通过介导右旋木糖代谢促进三阴性乳腺癌免疫逃逸，提出外源补充右旋木糖联合免疫检查点抑制剂可以作为DHDH高表达三阴性乳腺癌潜在的治疗策略。众所周知，地球生物体内天然氨基酸均为左旋、天然糖类均为右旋，木糖亦不例外。因此，以下将将右旋木糖简称为木糖。该单中心回顾研究利用前期建立的三阴性乳腺癌多组学队列，对465例三阴性乳腺癌患者的代谢基因进行分析，筛选出显著高表达于三阴性乳腺癌免疫沙漠型及显著低表达于免疫炎症型的DHDH。DHDH主要介导的代谢反应包括烟酰胺腺嘌呤二核苷酸磷酸（NADP）依赖性芳香烃氧化为相应的邻苯二酚和木糖转化为木糖-1,5-内酯。体内外实验发现DHDH促进三阴性乳腺癌的生长并依赖免疫微环境CD8阳性T细胞，并且一系列生物信息学分析鉴定到DHDH的下游蛋白PSMB9。免疫蛋白酶体PSMB9可影响抗原降解及下游免疫反应的激活，该研究发现过表达DHDH可显著抑制PSMB9的表达及免疫浸润。进一步机制研究提示，DHDH介导免疫逃逸依赖于其代谢酶活性。非靶向代谢物检测和木糖检测提示，木糖缺乏可能是DHDH高表达冷肿瘤表型的原因。该研究进一步揭示外源补充木糖可显著促进下游PSMB9的表达，并进一步提高三阴性乳腺癌免疫浸润及增敏DHDH高表达三阴性乳腺癌免疫检查点抑制剂疗效。此外，三阴性乳腺癌患者的临床标本分析提示尿液木糖水平与肿瘤CD8表达呈显著正相关。因此，该研究结果表明，补充木糖或者富含木糖的膳食模式联合免疫治疗有望为DHDH高表达的三阴性乳腺癌“冷肿瘤”提供新的临床治疗策略，故有必要进一步开展前瞻临床研究进行验证。木糖为白色细针状结晶或结晶性粉末，可溶于水和温热乙醇，不溶于乙醚，有还原性、右旋光性和变旋现象，略有特殊气味和爽口甜味，甜味相当于蔗糖的0.4倍。木糖广泛存在于各种植物中，可从白桦、覆盆子、玉米、燕麦壳等植物原料中提取，目前主要产自中国。木糖以多糖的形式天然存在于植物，可以从黑木耳或农产品废弃物（如棉桃的外皮，玉米的秸秆、穗轴）提取，通常以草木类、种子壳、木材等多缩木糖含量高的植物作为原料，与硫酸或盐酸进行加水分解，使木材中属半纤维素的木聚糖水解成木糖，然后用酵母发酵以除去葡萄糖，再精制浓缩而成。人体无法消化和利用木糖，木糖不能被消化酶分解，而是直接经空肠黏膜吸收，不在体内代谢，直接从肾排出，因此被用作无热量的甜味剂，以满足糖尿病患者和爱吃甜食却又担心发胖者的需求。医学上的木糖吸收试验就是通过测定患者在空腹口服木糖5小时后尿内的木糖排出量而反映出患者的小肠吸收功能。将木糖催化氢化还原后就得到木糖醇，木糖醇用作甜味剂，用途更加广泛，不过目前尚不明确木糖醇能否促进三阴性乳腺癌免疫疗效。 Med. 2024 Nov 8. IF: 12.8 DHDH-mediated D-xylose metabolism induces immune evasion in triple-negative breast cancer. Huai-liang Wu, Yue Gong, Yun-xiao Ling, Si-yu Wu, Peng Ji, Qian Zhao, Li-Hua He, Zhi-Ming Shao, Yi-Zhou Jiang, Guang-yu Liu. Fudan University Shanghai Cancer Center, Shanghai, China; Shanghai Medical College, Fudan University, Shanghai, China; Sun Yat-sen University Cancer Center, Guangzhou, China. CONTEXT AND SIGNIFICANCE: Triple-negative breast cancer (TNBC) exhibits resistance to immunotherapy due to its heterogeneous metabolic characteristics. Deciphering the metabolic mechanisms regulating anticancer immunity will provide new insights into therapeutic strategies for TNBC. Wu et al. performed bioinformatics analysis using FUSCC TNBC multi-omics data and identified a key metabolic enzyme, dihydrodiol dehydrogenase (DHDH), which is correlated with low immune infiltration. They found that D-xylose supplementation in vivo promoted CD8+ T cell infiltration and the expression of cytotoxic markers and increased the sensitivity of DHDH-overexpressing tumors to immunotherapy. Therefore, these findings may provide theoretical support for incorporating D-xylose or a xylose-rich diet alongside immunotherapy in TNBC patients with high DHDH expression. HIGHLIGHTS DHDH is an upregulated enzyme in “cold tumors” of TNBC DHDH promotes tumor growth via immune regulation mediated by its enzymatic activity D-xylose promotes immune infiltration via upregulation of PSMB9 D-xylose supplementation potentiates the efficacy of immunotherapy in TNBC BACKGROUND: Although the prognosis of triple-negative breast cancer (TNBC) has significantly improved in the era of immunotherapy, many TNBC patients are resistant to therapies, and their disease progresses rapidly. Deciphering the metabolic mechanisms regulating anticancer immunity will provide new insights into therapeutic strategies for TNBC. METHODS: In this study, we performed bioinformatics analysis in our multi-omics TNBC database and identified that a metabolic enzyme, dihydrodiol dehydrogenase (DHDH), might promote the phenotype of “cold tumor” in TNBC. The biological function of DHDH was verified by in vitro and in vivo functional experiments, and the potential molecular mechanism of DHDH promoting TNBC immune escape was further explored. FINDINGS: Mechanistically, DHDH mediated the synthesis and depletion of the substrate D-xylose and inhibited the activation of the proteasome subunit beta type 9 (PSMB9) and further induction of the immune response. We demonstrated that D-xylose supplementation could enhance the proliferation of CD8+ T cells and the expression of cytotoxic markers against cocultured DHDH-wild type (WT) cells. Consistently, D-xylose supplementation in vivo promoted CD8+ T cell infiltration and the expression of cytotoxic markers and increased the sensitivity of DHDH-overexpressing tumors to immune checkpoint blockade (ICB). CONCLUSIONS: Our findings reveal that a D-xylose-regulated PSMB9-dependent pathway governs tumor-intrinsic immunogenicity and, hence, the sensitivity to ICB, which may provide approaches to promote the “cold-to-hot” transition in TNBC. FUNDING: This study was funded by the National Key Research and Development Plan of China, Shanghai Science and Technology Commission, National Natural Science Foundation of China, and China Postdoctoral Science Foundation. KEYWORDS: triple-negative breast cancer, dihydrodiol dehydrogenase, d-xylose, proteasome subunit beta type 9, immunotherapy DOI: 10.1016/j.medj.2024.10.012 （来源：SIBCS）声明凡署名原创的文章版权属《肿瘤瞭望》所有，欢迎分享、转载。本文仅供医疗卫生专业人士了解最新医药资讯参考使用，不代表本平台观点。该等信息不能以任何方式取代专业的医疗指导，也不应被视为诊疗建议，如果该信息被用于资讯以外的目的，本站及作者不承担相关责任。

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