Juan M. Barajas, Masayuki Umeda, Ryan Hiltenbrand, Reethu Krishnan, Tamara Westover, Michael P. Walsh, Jing Ma, Sherif Abdelhamed, J. Klco
{"title":"摘要A45:UBTF-TD分子改变通过直接相互作用和调节HOXB基因座驱动儿童AML中的白血病发生","authors":"Juan M. Barajas, Masayuki Umeda, Ryan Hiltenbrand, Reethu Krishnan, Tamara Westover, Michael P. Walsh, Jing Ma, Sherif Abdelhamed, J. Klco","doi":"10.1158/2643-3249.aml23-a45","DOIUrl":null,"url":null,"abstract":"\n Pediatric acute myeloid leukemia (AML) is often refractory to chemotherapy and remains a devastating disease with poor outcomes. Consequently, there is an urgent need to characterize molecular drivers of pediatric AML with the goal of developing more effective molecular therapies. Our group recently identified somatic tandem duplications (TD) in exon 13 of upstream binding transcription factor (UBTF) as a subtype-defining genomic alteration in pediatric AML that is associated with poor outcomes, high relapse rate, and measurable residual disease (MRD) positivity. However, how these alterations drive leukemogenesis is yet to be investigated. Wild-type UBTF regulates rRNA transcription, ribosome biogenesis, and nucleolar formation. Our recent work suggests that UBTF-TD retains these functions. However, we found that expression of UBTF-TD in cord blood CD34+ cells, but not wild-type UBTF, leads to their increased proliferation, self-renewal, and CD117/CD33 surface marker expression, suggesting a potential gain of function as well. Furthermore, we also observed increased expression of HOXB locus genes, PRDM16, MEIS1, and NKX2-3 in the CD34+ UBTF-TD overexpression model relative to our WT control. These expression patterns are similar to what we see in patients, collectively implicating UBTF-TD driving leukemic phenotypes. Based on our localization studies of UBTF-TD to DNA, we hypothesized that UBTF-TD protein may gain the ability to interact with genomic loci that characterize UBTF-TD AML, like the HOXB locus. We therefore wanted to test if UBTF-TD localized to the HOXB cluster and if this lead direct transcriptional upregulation. To test this, we expressed HA-tagged UBTF-TD in cord-blood CD34+ cells and mapped UBTF-TD genomic occupancy using CUT&RUN. We found that UBTF-TD localized to the promoters and gene bodies of key genes, including PRDM16, MEIS1, NKX2-3, and the HOXB cluster. These sites were accompanied by H3K4me3 and H3K27ac active marks without the H3K27me3 repressive mark. To validate these as bone-fide UBTF-TD-occupied regions, we utilized a expressed FKBP12F36V-HA-UBTF-TD fusion in CD34+ cells. This degradation tag (dTAG) system allows for rapid degradation of UBTF-TD protein upon dTAG-13 treatment. We treated our FKBP12F36V-HA-UBTF-TD expressing cord blood CD34+ cells with 1uM of dTAG-13 or DMSO. We found that a 3-day treatment with dTAG-13 led to downregulation of HOXB gene locus expression, but loss of CD117 expression or cell growth required prolonged treatment. Furthermore, our CUT&RUN data showed that dTAG-13 treatment resulted in loss of UBTF-TD protein at the HOXB gene cluster. Collectively, these data show that UBTF-TD interacts with genomic loci at the HOXB gene cluster to directly upregulate their expression. This loss of HOX gene expression leads then leads to loss of a leukemic phenotype. Our data highlights a potential mechanism for UBTF-TD leukemogenesis and sets a foundation where inhibiting the UBTF-TD molecular signature may be a viable therapeutic option.\n Citation Format: Juan M Barajas, Masayuki Umeda, Ryan Hiltenbrand, Reethu Krishnan, Tamara Westover, Michael P Walsh, Jing Ma, Sherif Abdelhamed, Jeffery M Klco. UBTF-TD molecular alterations drive leukemogenesis in pediatric AML by directly interacting and regulating the HOXB gene locus [abstract]. In: Proceedings of the AACR Special Conference: Acute Myeloid Leukemia and Myelodysplastic Syndrome; 2023 Jan 23-25; Austin, TX. Philadelphia (PA): AACR; Blood Cancer Discov 2023;4(3_Suppl):Abstract nr A45.","PeriodicalId":29944,"journal":{"name":"Blood Cancer Discovery","volume":null,"pages":null},"PeriodicalIF":11.5000,"publicationDate":"2023-05-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Abstract A45: UBTF-TD molecular alterations drive leukemogenesis in pediatric AML by directly interacting and regulating the HOXB gene locus\",\"authors\":\"Juan M. Barajas, Masayuki Umeda, Ryan Hiltenbrand, Reethu Krishnan, Tamara Westover, Michael P. Walsh, Jing Ma, Sherif Abdelhamed, J. Klco\",\"doi\":\"10.1158/2643-3249.aml23-a45\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"\\n Pediatric acute myeloid leukemia (AML) is often refractory to chemotherapy and remains a devastating disease with poor outcomes. Consequently, there is an urgent need to characterize molecular drivers of pediatric AML with the goal of developing more effective molecular therapies. Our group recently identified somatic tandem duplications (TD) in exon 13 of upstream binding transcription factor (UBTF) as a subtype-defining genomic alteration in pediatric AML that is associated with poor outcomes, high relapse rate, and measurable residual disease (MRD) positivity. However, how these alterations drive leukemogenesis is yet to be investigated. Wild-type UBTF regulates rRNA transcription, ribosome biogenesis, and nucleolar formation. Our recent work suggests that UBTF-TD retains these functions. However, we found that expression of UBTF-TD in cord blood CD34+ cells, but not wild-type UBTF, leads to their increased proliferation, self-renewal, and CD117/CD33 surface marker expression, suggesting a potential gain of function as well. Furthermore, we also observed increased expression of HOXB locus genes, PRDM16, MEIS1, and NKX2-3 in the CD34+ UBTF-TD overexpression model relative to our WT control. These expression patterns are similar to what we see in patients, collectively implicating UBTF-TD driving leukemic phenotypes. Based on our localization studies of UBTF-TD to DNA, we hypothesized that UBTF-TD protein may gain the ability to interact with genomic loci that characterize UBTF-TD AML, like the HOXB locus. We therefore wanted to test if UBTF-TD localized to the HOXB cluster and if this lead direct transcriptional upregulation. To test this, we expressed HA-tagged UBTF-TD in cord-blood CD34+ cells and mapped UBTF-TD genomic occupancy using CUT&RUN. We found that UBTF-TD localized to the promoters and gene bodies of key genes, including PRDM16, MEIS1, NKX2-3, and the HOXB cluster. These sites were accompanied by H3K4me3 and H3K27ac active marks without the H3K27me3 repressive mark. To validate these as bone-fide UBTF-TD-occupied regions, we utilized a expressed FKBP12F36V-HA-UBTF-TD fusion in CD34+ cells. This degradation tag (dTAG) system allows for rapid degradation of UBTF-TD protein upon dTAG-13 treatment. We treated our FKBP12F36V-HA-UBTF-TD expressing cord blood CD34+ cells with 1uM of dTAG-13 or DMSO. We found that a 3-day treatment with dTAG-13 led to downregulation of HOXB gene locus expression, but loss of CD117 expression or cell growth required prolonged treatment. Furthermore, our CUT&RUN data showed that dTAG-13 treatment resulted in loss of UBTF-TD protein at the HOXB gene cluster. Collectively, these data show that UBTF-TD interacts with genomic loci at the HOXB gene cluster to directly upregulate their expression. This loss of HOX gene expression leads then leads to loss of a leukemic phenotype. Our data highlights a potential mechanism for UBTF-TD leukemogenesis and sets a foundation where inhibiting the UBTF-TD molecular signature may be a viable therapeutic option.\\n Citation Format: Juan M Barajas, Masayuki Umeda, Ryan Hiltenbrand, Reethu Krishnan, Tamara Westover, Michael P Walsh, Jing Ma, Sherif Abdelhamed, Jeffery M Klco. UBTF-TD molecular alterations drive leukemogenesis in pediatric AML by directly interacting and regulating the HOXB gene locus [abstract]. In: Proceedings of the AACR Special Conference: Acute Myeloid Leukemia and Myelodysplastic Syndrome; 2023 Jan 23-25; Austin, TX. 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引用次数: 0
摘要
儿童急性髓细胞白血病(AML)通常对化疗难以治愈,并且仍然是一种预后不佳的毁灭性疾病。因此,迫切需要表征儿童AML的分子驱动因素,以开发更有效的分子疗法。我们的研究小组最近确定,上游结合转录因子(UBTF)外显子13中的体细胞串联重复(TD)是定义儿童AML基因组改变的一种亚型,与不良预后、高复发率和可测量的残留疾病(MRD)阳性相关。然而,这些改变如何驱动白血病的发生尚待研究。野生型UBTF调节rRNA转录、核糖体生物发生和核仁形成。我们最近的工作表明,UBTF-TD保留了这些功能。然而,我们发现脐血CD34+细胞中UBTF-TD的表达,而不是野生型UBTF的表达,会导致其增殖、自我更新和CD117/CD33表面标记物表达增加,这也表明功能的潜在获得。此外,我们还观察到,与我们的WT对照相比,在CD34+UBTF-TD过表达模型中,HOXB基因座基因、PRDM16、MEIS1和NKX2-3的表达增加。这些表达模式与我们在患者中看到的相似,共同暗示UBTF-TD驱动白血病表型。基于我们对UBTF-TD与DNA的定位研究,我们假设UBTF-TD蛋白可能获得与表征UBTF-TD-AML的基因组基因座(如HOXB基因座)相互作用的能力。因此,我们想测试UBTF-TD是否定位于HOXB簇,以及这是否导致直接的转录上调。为了测试这一点,我们在脐血CD34+细胞中表达了HA标记的UBTF-TD,并使用CUT&RUN绘制了UBTF-TD的基因组占有率。我们发现UBTF-TD定位于关键基因的启动子和基因体,包括PRDM16、MEIS1、NKX2-3和HOXB簇。这些位点伴有H3K4me3和H3K27ac活性标记,而没有H3K27me3抑制标记。为了验证这些是真正的UBTF-TD占据区,我们在CD34+细胞中使用了表达的FKBP12F36V-HA-UBTF-TD融合物。该降解标签(dTAG)系统允许在dTAG-13处理时快速降解UBTF-TD蛋白。我们用1uM的dTAG-13或DMSO处理表达FKBP12F36V-HA-UBTF-TD的脐血CD34+细胞。我们发现,dTAG-13治疗3天会导致HOXB基因座表达下调,但CD117表达或细胞生长的丧失需要延长治疗时间。此外,我们的CUT&RUN数据显示,dTAG-13处理导致HOXB基因簇处的UBTF-TD蛋白损失。总之,这些数据表明,UBTF-TD与HOXB基因簇的基因组基因座相互作用,直接上调其表达。HOX基因表达的这种损失随后导致白血病表型的损失。我们的数据强调了UBTF-TD白血病发生的潜在机制,并为抑制UBTF-TD分子特征可能是一种可行的治疗选择奠定了基础。引文格式:Juan M Barajas、Masayuki Umeda、Ryan Hiltenbrand、Reethu Krishnan、Tamara Westover、Michael P Walsh、Jing Ma、Sherif Abdelhamed、Jeffery M Klco。UBTF-TD分子改变通过直接相互作用和调节HOXB基因座来驱动儿童AML中的白血病发生[摘要]。载:AACR特别会议论文集:急性髓细胞白血病和骨髓增生异常综合征;2023年1月23日至25日;德克萨斯州奥斯汀。费城(PA):AACR;血液癌症Discov 2023;4(3_Suppl):摘要编号A45。
Abstract A45: UBTF-TD molecular alterations drive leukemogenesis in pediatric AML by directly interacting and regulating the HOXB gene locus
Pediatric acute myeloid leukemia (AML) is often refractory to chemotherapy and remains a devastating disease with poor outcomes. Consequently, there is an urgent need to characterize molecular drivers of pediatric AML with the goal of developing more effective molecular therapies. Our group recently identified somatic tandem duplications (TD) in exon 13 of upstream binding transcription factor (UBTF) as a subtype-defining genomic alteration in pediatric AML that is associated with poor outcomes, high relapse rate, and measurable residual disease (MRD) positivity. However, how these alterations drive leukemogenesis is yet to be investigated. Wild-type UBTF regulates rRNA transcription, ribosome biogenesis, and nucleolar formation. Our recent work suggests that UBTF-TD retains these functions. However, we found that expression of UBTF-TD in cord blood CD34+ cells, but not wild-type UBTF, leads to their increased proliferation, self-renewal, and CD117/CD33 surface marker expression, suggesting a potential gain of function as well. Furthermore, we also observed increased expression of HOXB locus genes, PRDM16, MEIS1, and NKX2-3 in the CD34+ UBTF-TD overexpression model relative to our WT control. These expression patterns are similar to what we see in patients, collectively implicating UBTF-TD driving leukemic phenotypes. Based on our localization studies of UBTF-TD to DNA, we hypothesized that UBTF-TD protein may gain the ability to interact with genomic loci that characterize UBTF-TD AML, like the HOXB locus. We therefore wanted to test if UBTF-TD localized to the HOXB cluster and if this lead direct transcriptional upregulation. To test this, we expressed HA-tagged UBTF-TD in cord-blood CD34+ cells and mapped UBTF-TD genomic occupancy using CUT&RUN. We found that UBTF-TD localized to the promoters and gene bodies of key genes, including PRDM16, MEIS1, NKX2-3, and the HOXB cluster. These sites were accompanied by H3K4me3 and H3K27ac active marks without the H3K27me3 repressive mark. To validate these as bone-fide UBTF-TD-occupied regions, we utilized a expressed FKBP12F36V-HA-UBTF-TD fusion in CD34+ cells. This degradation tag (dTAG) system allows for rapid degradation of UBTF-TD protein upon dTAG-13 treatment. We treated our FKBP12F36V-HA-UBTF-TD expressing cord blood CD34+ cells with 1uM of dTAG-13 or DMSO. We found that a 3-day treatment with dTAG-13 led to downregulation of HOXB gene locus expression, but loss of CD117 expression or cell growth required prolonged treatment. Furthermore, our CUT&RUN data showed that dTAG-13 treatment resulted in loss of UBTF-TD protein at the HOXB gene cluster. Collectively, these data show that UBTF-TD interacts with genomic loci at the HOXB gene cluster to directly upregulate their expression. This loss of HOX gene expression leads then leads to loss of a leukemic phenotype. Our data highlights a potential mechanism for UBTF-TD leukemogenesis and sets a foundation where inhibiting the UBTF-TD molecular signature may be a viable therapeutic option.
Citation Format: Juan M Barajas, Masayuki Umeda, Ryan Hiltenbrand, Reethu Krishnan, Tamara Westover, Michael P Walsh, Jing Ma, Sherif Abdelhamed, Jeffery M Klco. UBTF-TD molecular alterations drive leukemogenesis in pediatric AML by directly interacting and regulating the HOXB gene locus [abstract]. In: Proceedings of the AACR Special Conference: Acute Myeloid Leukemia and Myelodysplastic Syndrome; 2023 Jan 23-25; Austin, TX. Philadelphia (PA): AACR; Blood Cancer Discov 2023;4(3_Suppl):Abstract nr A45.
期刊介绍:
The journal Blood Cancer Discovery publishes high-quality Research Articles and Briefs that focus on major advances in basic, translational, and clinical research of leukemia, lymphoma, myeloma, and associated diseases. The topics covered include molecular and cellular features of pathogenesis, therapy response and relapse, transcriptional circuits, stem cells, differentiation, microenvironment, metabolism, immunity, mutagenesis, and clonal evolution. These subjects are investigated in both animal disease models and high-dimensional clinical data landscapes.
The journal also welcomes submissions on new pharmacological, biological, and living cell therapies, as well as new diagnostic tools. They are interested in prognostic, diagnostic, and pharmacodynamic biomarkers, and computational and machine learning approaches to personalized medicine. The scope of submissions ranges from preclinical proof of concept to clinical trials and real-world evidence.
Blood Cancer Discovery serves as a forum for diverse ideas that shape future research directions in hematooncology. In addition to Research Articles and Briefs, the journal also publishes Reviews, Perspectives, and Commentaries on topics of broad interest in the field.