C. R. G. D. Alcazar, S. Huh, Muhammad B Ekram, A. Trinh, Lin L. Liu, F. Beca, Zi Xiaoyuan, M. Kwak, Helga Bergholtz, Ying Su, L. Ding, H. Russnes, A. Richardson, Kirsten Babski, E. M. Kim, C. H. McDonnell, Jon Wagner, Ron Rowberry, G. Freeman, D. Dillon, T. Sørlie, L. Coussens, J. Garber, R. Fan, Kristie A. Bobolis, Joon Jeong, S. Y. Park, F. Michor, K. Polyak
{"title":"A15:乳腺癌肿瘤演变中的免疫相关变化","authors":"C. R. G. D. Alcazar, S. Huh, Muhammad B Ekram, A. Trinh, Lin L. Liu, F. Beca, Zi Xiaoyuan, M. Kwak, Helga Bergholtz, Ying Su, L. Ding, H. Russnes, A. Richardson, Kirsten Babski, E. M. Kim, C. H. McDonnell, Jon Wagner, Ron Rowberry, G. Freeman, D. Dillon, T. Sørlie, L. Coussens, J. Garber, R. Fan, Kristie A. Bobolis, Joon Jeong, S. Y. Park, F. Michor, K. Polyak","doi":"10.1158/2326-6074.TUMIMM17-A15","DOIUrl":null,"url":null,"abstract":"Immunotherapy is a highly promising therapeutic option in metastatic disease albeit only in a subset of patients possibly due to heterogeneity in the mechanisms by which tumors escape immune surveillance. Immune cells shape tumor evolution directly (e.g., anti-tumor immune response) and indirectly (e.g., changing the microenvironment) by selecting for cancer cells with certain properties. We hypothesized that the in situ (DCIS) to invasive ductal carcinoma (IDC) transition is a critical tumor progression step for immune escape in breast cancer that defines subsequent tumor evolution. In DCIS, cancer cells are physically separated from the stroma by the basement membrane and myoepithelial cell layer, and tumor-infiltrating leukocytes are rarely detected in direct contact with cancer cells. In contrast, in IDC, cancer cells and leukocytes are intermingled, thus, only cancer cells that can survive in this environment will play a role in disease progression. To dissect mechanisms of immune escape in breast cancer, we first analyzed the composition of leukocytes in normal breast tissues, DCIS, and IDC by polychromatic FACS. We found that DCIS and IDC contained significantly higher numbers of leukocytes, compared to normal breast, whereas in normal tissues more leukocytes were in the stromal than in the epithelial fraction. We also observed significant differences in the relative frequencies of several CD45+ cell types including increased neutrophils and decreased CD8+/CD4+ T cell ratios in tumors compared to normal stroma. Next, we analyzed the gene expression profiles of CD45+CD3+ T cells and found gene set enrichment of cytotoxic cells in DCIS including CD8+ T cells and NKT cells when compared to IDC. Conversely, we found enrichment for gene sets corresponding to regulatory T cells in IDC when compared to DCIS. Overall this suggested that DCIS had a more activated immune environment and IDC a more suppressed immune environment. We further explored this result by immunofluorescence (IF) and found fewer activated GZMB+CD8+ T cells in IDC than in DCIS, including a set of matched DCIS and locally recurrent IDC tissues. We also found that the TCR clonotype was more diverse in DCIS than in normal breast and IDCs. Interestingly we detected a few relatively frequent clones that were shared among different DCIS, one of which was previously shown to recognize a protein from the Epstein-Bar virus. To elucidate mechanisms of immune evasion in IDC, we performed IF analysis of immune checkpoint proteins PD-L1 and TIGIT and found significant differences between DCIS and IDC. TIGIT-expressing T cells were more slightly frequent in DCIS than in IDC. PD-L1 expression was higher in the epithelial cancer cells in triple negative IDC compared to DCIS, and amplification of CD274 (encoding PD-L1) was only detected in triple negative IDCs. Given the close proximity of ERBB2 (encoding HER2) to a cluster of genes encoding several chemokines, we analyzed the HER2+ samples from the TCGA. We found that co-amplification of 17q12 chemokine cluster (CC) with ERBB2 was enriched in HER+ER+ luminal-like tumors but not in the HER2+ER breast tumors. We also found higher expression of both T cell activation and inhibition-related genes in tumors that lack CC gain. Also by assessing tumor samples by multicolor FISH and IF, we determined that there is an inverse correlation between CC amplification and activation of CD8+ T cells. Overall our results show co-evolution of cancer cells and the immune microenvironment during tumor progression. Citation Format: Carlos R. Gil del Alcazar, SungJin Huh, Muhammad B. Ekram, Anne Trinh, Lin L. Liu, Francisco Beca, Zi Xiaoyuan, Misuk Kwak, Helga Bergholtz, Ying Su, Lina Ding, Lina Ding, Hege G. Russnes, Andrea L. Richardson, Kirsten Babski, Elizabeth Min Hui Kim, Charles H. McDonnell, III, Jon Wagner, Ron Rowberry, Gordon Freeman, Deborah Dillon, Therese Sorlie, Lisa M. Coussens, Judy E. Garber, Rong Fan, Kristie Bobolis, Joon Jeong, So Yeon Park, Franziska Michor, Kornelia Polyak. Immune-related changes in breast cancer tumor evolution [abstract]. 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Conversely, we found enrichment for gene sets corresponding to regulatory T cells in IDC when compared to DCIS. Overall this suggested that DCIS had a more activated immune environment and IDC a more suppressed immune environment. We further explored this result by immunofluorescence (IF) and found fewer activated GZMB+CD8+ T cells in IDC than in DCIS, including a set of matched DCIS and locally recurrent IDC tissues. We also found that the TCR clonotype was more diverse in DCIS than in normal breast and IDCs. Interestingly we detected a few relatively frequent clones that were shared among different DCIS, one of which was previously shown to recognize a protein from the Epstein-Bar virus. To elucidate mechanisms of immune evasion in IDC, we performed IF analysis of immune checkpoint proteins PD-L1 and TIGIT and found significant differences between DCIS and IDC. TIGIT-expressing T cells were more slightly frequent in DCIS than in IDC. PD-L1 expression was higher in the epithelial cancer cells in triple negative IDC compared to DCIS, and amplification of CD274 (encoding PD-L1) was only detected in triple negative IDCs. Given the close proximity of ERBB2 (encoding HER2) to a cluster of genes encoding several chemokines, we analyzed the HER2+ samples from the TCGA. We found that co-amplification of 17q12 chemokine cluster (CC) with ERBB2 was enriched in HER+ER+ luminal-like tumors but not in the HER2+ER breast tumors. We also found higher expression of both T cell activation and inhibition-related genes in tumors that lack CC gain. Also by assessing tumor samples by multicolor FISH and IF, we determined that there is an inverse correlation between CC amplification and activation of CD8+ T cells. Overall our results show co-evolution of cancer cells and the immune microenvironment during tumor progression. Citation Format: Carlos R. Gil del Alcazar, SungJin Huh, Muhammad B. Ekram, Anne Trinh, Lin L. Liu, Francisco Beca, Zi Xiaoyuan, Misuk Kwak, Helga Bergholtz, Ying Su, Lina Ding, Lina Ding, Hege G. Russnes, Andrea L. Richardson, Kirsten Babski, Elizabeth Min Hui Kim, Charles H. McDonnell, III, Jon Wagner, Ron Rowberry, Gordon Freeman, Deborah Dillon, Therese Sorlie, Lisa M. Coussens, Judy E. Garber, Rong Fan, Kristie Bobolis, Joon Jeong, So Yeon Park, Franziska Michor, Kornelia Polyak. Immune-related changes in breast cancer tumor evolution [abstract]. In: Proceedings of the AACR Special Conference on Tumor Immunology and Immunotherapy; 2017 Oct 1-4; Boston, MA. 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引用次数: 0
摘要
免疫治疗是一种非常有前途的转移性疾病的治疗选择,尽管仅适用于一小部分患者,可能是由于肿瘤逃避免疫监视的机制存在异质性。免疫细胞通过选择具有某些特性的癌细胞,直接(例如,抗肿瘤免疫反应)或间接(例如,改变微环境)影响肿瘤的进化。我们假设原位癌(DCIS)向浸润性导管癌(IDC)的转变是乳腺癌免疫逃逸的关键肿瘤进展步骤,这决定了随后的肿瘤演变。在DCIS中,癌细胞被基底膜和肌上皮细胞层物理地与间质分离,肿瘤浸润的白细胞很少与癌细胞直接接触。相反,在IDC中,癌细胞和白细胞是混杂的,因此只有能够在这种环境中生存的癌细胞才会在疾病进展中发挥作用。为了剖析乳腺癌中免疫逃逸的机制,我们首先通过多色FACS分析了正常乳腺组织、DCIS和IDC中白细胞的组成。我们发现,与正常乳腺相比,DCIS和IDC的白细胞数量明显增加,而在正常组织中,基质中的白细胞多于上皮部分。我们还观察到,与正常基质相比,肿瘤中几种CD45+细胞类型的相对频率存在显著差异,包括中性粒细胞增加和CD8+/CD4+ T细胞比例降低。接下来,我们分析了CD45+CD3+ T细胞的基因表达谱,发现与IDC相比,DCIS细胞毒性细胞包括CD8+ T细胞和NKT细胞的基因集富集。相反,与DCIS相比,我们发现IDC中与调节性T细胞相关的基因组富集。总体而言,这表明DCIS具有更激活的免疫环境,而IDC具有更抑制的免疫环境。我们通过免疫荧光(IF)进一步探讨了这一结果,发现IDC中活化的GZMB+CD8+ T细胞少于DCIS,包括一组匹配的DCIS和局部复发的IDC组织。我们还发现TCR克隆型在DCIS中比在正常乳腺和肝癌中更多样化。有趣的是,我们发现了一些在不同DCIS之间共享的相对频繁的克隆,其中一个先前被证明可以识别来自爱泼斯坦-巴尔病毒的蛋白质。为了阐明IDC中免疫逃避的机制,我们对免疫检查点蛋白PD-L1和TIGIT进行了IF分析,发现DCIS和IDC之间存在显著差异。表达tigit的T细胞在DCIS中的频率略高于IDC。与DCIS相比,三阴性IDC上皮癌细胞中PD-L1的表达更高,CD274(编码PD-L1)的扩增仅在三阴性IDC中检测到。鉴于ERBB2(编码HER2)与编码几种趋化因子的基因簇非常接近,我们分析了来自TCGA的HER2+样本。我们发现17q12趋化因子簇(CC)与ERBB2的共扩增在HER+ER+发光样肿瘤中富集,而在HER2+ER乳腺肿瘤中不富集。我们还发现,在缺乏CC增益的肿瘤中,T细胞激活和抑制相关基因的表达更高。此外,通过多色FISH和IF评估肿瘤样本,我们确定CC扩增与CD8+ T细胞活化之间存在负相关。总的来说,我们的结果显示在肿瘤进展过程中癌细胞和免疫微环境的共同进化。引用形式:Carlos R. Gil del Alcazar, SungJin Huh, Muhammad B. Ekram, Anne Trinh, Lin L. Liu, Francisco Beca, Zi Xiaoyuan, Misuk Kwak, Helga Bergholtz, Ying Su, Lina Ding, Lina Ding, Hege G. Russnes, Andrea L. Richardson, Kirsten Babski, Elizabeth Min Hui Kim, Charles H. McDonnell, III, Jon Wagner, Ron Rowberry, Gordon Freeman, Deborah Dillon, Therese Sorlie, Lisa M. Coussens, Judy E. Garber, Rong Fan, Kristie Bobolis, Joon Jeong, So Yeon Park, Franziska Michor, Kornelia Polyak。乳腺癌肿瘤演变中的免疫相关变化[摘要]。摘自:AACR肿瘤免疫学和免疫治疗特别会议论文集;2017年10月1-4日;波士顿,MA。费城(PA): AACR;癌症免疫学杂志,2018;6(9增刊):摘要nr A15。
Abstract A15: Immune-related changes in breast cancer tumor evolution
Immunotherapy is a highly promising therapeutic option in metastatic disease albeit only in a subset of patients possibly due to heterogeneity in the mechanisms by which tumors escape immune surveillance. Immune cells shape tumor evolution directly (e.g., anti-tumor immune response) and indirectly (e.g., changing the microenvironment) by selecting for cancer cells with certain properties. We hypothesized that the in situ (DCIS) to invasive ductal carcinoma (IDC) transition is a critical tumor progression step for immune escape in breast cancer that defines subsequent tumor evolution. In DCIS, cancer cells are physically separated from the stroma by the basement membrane and myoepithelial cell layer, and tumor-infiltrating leukocytes are rarely detected in direct contact with cancer cells. In contrast, in IDC, cancer cells and leukocytes are intermingled, thus, only cancer cells that can survive in this environment will play a role in disease progression. To dissect mechanisms of immune escape in breast cancer, we first analyzed the composition of leukocytes in normal breast tissues, DCIS, and IDC by polychromatic FACS. We found that DCIS and IDC contained significantly higher numbers of leukocytes, compared to normal breast, whereas in normal tissues more leukocytes were in the stromal than in the epithelial fraction. We also observed significant differences in the relative frequencies of several CD45+ cell types including increased neutrophils and decreased CD8+/CD4+ T cell ratios in tumors compared to normal stroma. Next, we analyzed the gene expression profiles of CD45+CD3+ T cells and found gene set enrichment of cytotoxic cells in DCIS including CD8+ T cells and NKT cells when compared to IDC. Conversely, we found enrichment for gene sets corresponding to regulatory T cells in IDC when compared to DCIS. Overall this suggested that DCIS had a more activated immune environment and IDC a more suppressed immune environment. We further explored this result by immunofluorescence (IF) and found fewer activated GZMB+CD8+ T cells in IDC than in DCIS, including a set of matched DCIS and locally recurrent IDC tissues. We also found that the TCR clonotype was more diverse in DCIS than in normal breast and IDCs. Interestingly we detected a few relatively frequent clones that were shared among different DCIS, one of which was previously shown to recognize a protein from the Epstein-Bar virus. To elucidate mechanisms of immune evasion in IDC, we performed IF analysis of immune checkpoint proteins PD-L1 and TIGIT and found significant differences between DCIS and IDC. TIGIT-expressing T cells were more slightly frequent in DCIS than in IDC. PD-L1 expression was higher in the epithelial cancer cells in triple negative IDC compared to DCIS, and amplification of CD274 (encoding PD-L1) was only detected in triple negative IDCs. Given the close proximity of ERBB2 (encoding HER2) to a cluster of genes encoding several chemokines, we analyzed the HER2+ samples from the TCGA. We found that co-amplification of 17q12 chemokine cluster (CC) with ERBB2 was enriched in HER+ER+ luminal-like tumors but not in the HER2+ER breast tumors. We also found higher expression of both T cell activation and inhibition-related genes in tumors that lack CC gain. Also by assessing tumor samples by multicolor FISH and IF, we determined that there is an inverse correlation between CC amplification and activation of CD8+ T cells. Overall our results show co-evolution of cancer cells and the immune microenvironment during tumor progression. Citation Format: Carlos R. Gil del Alcazar, SungJin Huh, Muhammad B. Ekram, Anne Trinh, Lin L. Liu, Francisco Beca, Zi Xiaoyuan, Misuk Kwak, Helga Bergholtz, Ying Su, Lina Ding, Lina Ding, Hege G. Russnes, Andrea L. Richardson, Kirsten Babski, Elizabeth Min Hui Kim, Charles H. McDonnell, III, Jon Wagner, Ron Rowberry, Gordon Freeman, Deborah Dillon, Therese Sorlie, Lisa M. Coussens, Judy E. Garber, Rong Fan, Kristie Bobolis, Joon Jeong, So Yeon Park, Franziska Michor, Kornelia Polyak. Immune-related changes in breast cancer tumor evolution [abstract]. In: Proceedings of the AACR Special Conference on Tumor Immunology and Immunotherapy; 2017 Oct 1-4; Boston, MA. Philadelphia (PA): AACR; Cancer Immunol Res 2018;6(9 Suppl):Abstract nr A15.