Background Chromatin state provides a clear decipherable blueprint for maintenance of transcriptional patterns, exemplifying a mitotically stable form of cellular programming in dividing cells. In this regard, genomic studies of chromatin states within cancerous tissues have the potential to uncover novel aspects of tumor biology and unique mechanisms associated with disease phenotypes and outcomes. The degree to which chromatin state differences occur in accordance with breast cancer features has not been established. Methods We applied a series of unsupervised computational methods to identify chromatin and molecular differences associated with discrete physiologies across human breast cancer tumors. Results Chromatin patterns alone are capable of stratifying tumors in association with cancer subtype and disease progression. Major differences occur at DNA motifs for the transcription factor FOXA1, in hormone receptor-positive tumors, and motifs for SOX9 in Basal-like tumors. We find that one potential driver of this effect, the histone chaperone ANP32E, is inversely correlated with tumor progression and relaxation of chromatin at FOXA1 binding sites. Tumors with high levels of ANP32E exhibit an immune response and proliferative gene expression signature, whereas tumors with low ANP32E levels appear programmed for differentiation. Conclusions Our results indicate that ANP32E may function through chromatin state regulation to control breast cancer differentiation and tumor plasticity. This study sets a precedent for future computational studies of chromatin changes in carcinogenesis.
Despite highly advanced diagnosis and treatment strategies, breast cancer patient outcomes vary extensively, even among individuals with the same diagnosis. Thus, a better understanding of the unique molecular characteristics that underlie tumor trajectories and responses to therapy remains a central goal. We report that chromatin patterns represent an important characteristic, capable of stratifying tumor identity and progression. We find that patterns of chromatin accessibility can be classified into 3 major groups, representing Basal-like tumors, hormone receptor (HR)-expressing tumors, and invasive lobular Luminal-A tumors. Major chromatin differences occur throughout the genome at motifs for the transcription factor FOXA1 in HR-positive tumors, and motifs for SOX9 in Basal-like tumors. A large portion of lobular Luminal-A tumors display a chromatin signature defined by accessibility at FOXA1 binding motifs, distinguishing them from others within this subtype. Expression of the histone chaperone ANP32E is inversely correlated with tumor progression and chromatin accessibility at FOXA1 binding sites. Tumors with high levels of ANP32E exhibit an immune response and proliferative gene expression signature, whereas tumors with low ANP32E levels appear programmed for differentiation. Our results indicate that ANP32E may function through chromatin state regulation to control breast cancer differentiation and tumor plasticity.
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