Project description:The chromatins are folded into three-dimensional (3D) structures inside cells, which coordinates the regulation of gene transcription by the non-coding regulatory elements. Aberrant chromatin 3D folding has been shown in many diseases, such as acute myeloid leukemia (AML), and may contribute to tumorigenesis. The anthracycline topoisomerase II inhibitors can induce histone eviction and DNA damage. We performed genome-wide high-resolution mapping of the chemotherapeutic effects of various clinically used anthracycline drugs. ATAC-seq was used to profile the histone eviction effects of different anthracyclines. TOP2A ChIP-seq was used to profile the potential DNA damage regions. Integrated analyses show that different anthracyclines have distinct target selectivity on epigenomic regions, based on their respective ATAC-seq and ChIP-seq profiles. We identified the underlying molecular mechanism that unique anthracycline variants selectively target chromatin looping anchors via disrupting CTCF binding, suggesting an additional potential therapeutic effect on the 3D genome. We further performed Hi-C experiments, and data from K562 cells treated with the selective anthracycline drugs indicate that the 3D chromatin organization is disrupted. Furthermore, AML patients receiving anthracycline drugs showed altered chromatin structures around potential looping anchors of, which linked to distinct clinical outcomes. Our data indicate that anthracyclines are potent and selective epigenomic targeting drugs and can target the 3D genome for anticancer therapy, which could be used for personalized medicine to treat tumors with aberrant 3D chromatin structures

Project description:Anthracyclines act by disrupting the interface of TopoII and DNA and by evicting histones. The anthracycline-specific redistribution of TopoII and its association with histone eviction were addressed in K562 cells. Chromatin immunoprecipitation, followed by deep sequencing (ChIP-seq) against endogenously tagged TopoIIα, and transposase-accessible chromatin with sequencing (ATAC-seq) was performed 4 hours after anthracycline exposure.

Project description:PURPOSE: Validated biomarkers predictive of response/resistance to anthracyclines in breast cancer are currently lacking. The neoadjuvant TOP trial, in which patients with estrogen receptor (ER)-negative tumors were treated with anthracycline (epirubicin) monotherapy, was specifically designed to evaluate the predictive value of topoisomerase IIα (TOP2A) and to develop a gene expression signature to identify those patients who do not benefit from anthracyclines. METHODS: The TOP trial included 149 patients, of which 141 were evaluable for response prediction analyses. The primary endpoint was pathological complete response (pCR). TOP2A and gene expression profiles were evaluated using pre-epirubicin biopsies. Gene expression data from ER-negative samples of the EORTC 10994/BIG 00-01 and MDACC 2003-0321 neoadjuvant trials were used for validation purposes. RESULTS: A pCR was obtained in 14% of the evaluable TOP patients. TOP2A amplification, but not protein overexpression, was significantly associated with pCR (p=0.001 and 0.22). We developed an “anthracycline-based score (A-Score)” that combines three signatures: a TOP2A gene signature and two previously published signatures related to tumor invasion and immune response. The A-Score was characterized by a high negative predictive value (NPV=0.98 [95% CI: 0.90-1.00]) overall, and in the HER2-negative and HER2-positive subpopulations. Its performance was independently confirmed in the anthracycline-based (FAC/FEC) arms of the two validation trials (BIG 00-01: 0.80 [0.61-0.92] and MDACC 2003-0321: 1.00 [0.80-1.00]). CONCLUSION: Given its high NPV, the A-Score could become, if further validated, a useful clinical tool to identify those patients who do not benefit from anthracyclines and could therefore be spared the non-negligible side effects. Predicting the efficacy of anthracyclines (epirubicin) in breast cancer (BC) patients (TOP trial) 120 microarray experiments from primary ER-negative breast tumors of anthracycline-treated patients. No replicate, no reference sample.

Project description:Anthracyclines are a class of widely prescribed anti-cancer drugs that disrupt chromatin by intercalating into DNA and enhancing nucleosome turnover. To understand the molecular consequences of anthracycline-mediated chromatin disruption, we utilized CUT&Tag to profile RNA polymerase II during anthracycline treatment in Drosophila cells. We observed that treatment with the anthracycline aclarubicin leads to elevated levels of elongating RNA polymerase II and changes in chromatin accessibility. We found that promoter proximity and orientation impacts chromatin changes during aclarubicin treatment, as closely spaced divergent promoter pairs show greater chromatin changes when compared to codirectionally-oriented tandem promoters. We also found that aclarubicin treatment changes the distribution of non-canonical DNA G-quadruplex structures both at promoters and at G-rich pericentromeric repeats. Our work suggests that aclarubicin's anti-cancer activity is driven by the effects of nucleosome disruption on RNA polymerase II, chromatin accessibility and DNA structures.

Project description:PURPOSE: Validated biomarkers predictive of response/resistance to anthracyclines in breast cancer are currently lacking. The neoadjuvant TOP trial, in which patients with estrogen receptor (ER)-negative tumors were treated with anthracycline (epirubicin) monotherapy, was specifically designed to evaluate the predictive value of topoisomerase IIα (TOP2A) and to develop a gene expression signature to identify those patients who do not benefit from anthracyclines. METHODS: The TOP trial included 149 patients, of which 141 were evaluable for response prediction analyses. The primary endpoint was pathological complete response (pCR). TOP2A and gene expression profiles were evaluated using pre-epirubicin biopsies. Gene expression data from ER-negative samples of the EORTC 10994/BIG 00-01 and MDACC 2003-0321 neoadjuvant trials were used for validation purposes. RESULTS: A pCR was obtained in 14% of the evaluable TOP patients. TOP2A amplification, but not protein overexpression, was significantly associated with pCR (p=0.001 and 0.22). We developed an “anthracycline-based score (A-Score)” that combines three signatures: a TOP2A gene signature and two previously published signatures related to tumor invasion and immune response. The A-Score was characterized by a high negative predictive value (NPV=0.98 [95% CI: 0.90-1.00]) overall, and in the HER2-negative and HER2-positive subpopulations. Its performance was independently confirmed in the anthracycline-based (FAC/FEC) arms of the two validation trials (BIG 00-01: 0.80 [0.61-0.92] and MDACC 2003-0321: 1.00 [0.80-1.00]). CONCLUSION: Given its high NPV, the A-Score could become, if further validated, a useful clinical tool to identify those patients who do not benefit from anthracyclines and could therefore be spared the non-negligible side effects.

Project description:Vertebrate sperm genome differs from somatic cells and undergoes dramatic transformation after fertilization. However, the functional implications of the sperm genome structures have not been fully investigated. Here we show, in the sperms of Xenopus tropicalis, tens of genomic regions harbor multi-megabases, super-sized clustered loops (SSCLs) whose anchors are enriched with Helitrons, the only group of rolling-circle transposons. SSCL anchors are inaccessible and absent of active histone modifications, implying that SSCLs are repressive in nature. Moreover, genes associated with SSCL anchors express late during development, suggesting 3D structure in sperm may associate with gene expression control during embryo development. The absence of CTCF and RNAPII at SSCL anchors argues against CTCF-mediated or transcription-related looping for the SSCLs establishment. Furthermore, our molecular simulation excludes looping and supports a phase separation model through which SSCLs may form. Taken together, our work reveals a previously undiscovered, repressive 3D structure in sperm that may mediate intergenerational gene regulation.

Project description:Vertebrate sperm genome differs from somatic cells and undergoes dramatic transformation after fertilization. However, the functional implications of the sperm genome structures have not been fully investigated. Here we show, in the sperms of Xenopus tropicalis, tens of genomic regions harbor multi-megabases, super-sized clustered loops (SSCLs) whose anchors are enriched with Helitrons, the only group of rolling-circle transposons. SSCL anchors are inaccessible and absent of active histone modifications, implying that SSCLs are repressive in nature. Moreover, genes associated with SSCL anchors express late during development, suggesting 3D structure in sperm may associate with gene expression control during embryo development. The absence of CTCF and RNAPII at SSCL anchors argues against CTCF-mediated or transcription-related looping for the SSCLs establishment. Furthermore, our molecular simulation excludes looping and supports a phase separation model through which SSCLs may form. Taken together, our work reveals a previously undiscovered, repressive 3D structure in sperm that may mediate intergenerational gene regulation.

Project description:Vertebrate sperm genome differs from somatic cells and undergoes dramatic transformation after fertilization. However, the functional implications of the sperm genome structures have not been fully investigated. Here we show, in the sperms of Xenopus tropicalis, tens of genomic regions harbor multi-megabases, super-sized clustered loops (SSCLs) whose anchors are enriched with Helitrons, the only group of rolling-circle transposons. SSCL anchors are inaccessible and absent of active histone modifications, implying that SSCLs are repressive in nature. Moreover, genes associated with SSCL anchors express late during development, suggesting 3D structure in sperm may associate with gene expression control during embryo development. The absence of CTCF and RNAPII at SSCL anchors argues against CTCF-mediated or transcription-related looping for the SSCLs establishment. Furthermore, our molecular simulation excludes looping and supports a phase separation model through which SSCLs may form. Taken together, our work reveals a previously undiscovered, repressive 3D structure in sperm that may mediate intergenerational gene regulation.

Project description:Vertebrate sperm genome differs from somatic cells and undergoes dramatic transformation after fertilization. However, the functional implications of the sperm genome structures have not been fully investigated. Here we show, in the sperms of Xenopus tropicalis, tens of genomic regions harbor multi-megabases, super-sized clustered loops (SSCLs) whose anchors are enriched with Helitrons, the only group of rolling-circle transposons. SSCL anchors are inaccessible and absent of active histone modifications, implying that SSCLs are repressive in nature. Moreover, genes associated with SSCL anchors express late during development, suggesting 3D structure in sperm may associate with gene expression control during embryo development. The absence of CTCF and RNAPII at SSCL anchors argues against CTCF-mediated or transcription-related looping for the SSCLs establishment. Furthermore, our molecular simulation excludes looping and supports a phase separation model through which SSCLs may form. Taken together, our work reveals a previously undiscovered, repressive 3D structure in sperm that may mediate intergenerational gene regulation.

Project description:Vertebrate sperm genome differs from somatic cells and undergoes dramatic transformation after fertilization. However, the functional implications of the sperm genome structures have not been fully investigated. Here we show, in the sperms of Xenopus tropicalis, tens of genomic regions harbor multi-megabases, super-sized clustered loops (SSCLs) whose anchors are enriched with Helitrons, the only group of rolling-circle transposons. SSCL anchors are inaccessible and absent of active histone modifications, implying that SSCLs are repressive in nature. Moreover, genes associated with SSCL anchors express late during development, suggesting 3D structure in sperm may associate with gene expression control during embryo development. The absence of CTCF and RNAPII at SSCL anchors argues against CTCF-mediated or transcription-related looping for the SSCLs establishment. Furthermore, our molecular simulation excludes looping and supports a phase separation model through which SSCLs may form. Taken together, our work reveals a previously undiscovered, repressive 3D structure in sperm that may mediate intergenerational gene regulation.