GATA3 is known to be one of the most frequently mutated genes in breast cancer. More than 10% of breast tumors carry mutations in this gene. However, the functional consequence of GATA3 mutations is still largely unknown. Clinical data suggest that different types of GATA3 mutations may have distinct roles in breast cancer characterization. In this study, we have established three luminal breast cancer cell lines that stably express different truncation mutants (X308 splice site deletion, C321 frameshift, and A333 frameshift mutants) found in breast cancer patients. Transcriptome analysis identified common and distinct gene expression patterns in these GATA3 mutant cell lines. In particular, the impacts on epithelial-to-mesenchymal transition (EMT) related genes are similar across these mutant cell lines. Chromatin localization of the mutants is highly overlapped and exhibits non-canonical motif enrichment. Interestingly, the A333 frameshift mutant expressed cells displayed the most significant impact on the GATA3 binding compared to X308 splice site deletion and C321fs mutants expressed cells. Our results suggest the common and different roles of GATA3 truncation mutations during luminal breast cancer development.
Leptomeningeal carcinomatosis (LC) occurs when tumor cells spread to the cerebrospinal fluid–containing leptomeninges surrounding the brain and spinal cord. LC is an ominous complication of cancer with a dire prognosis. Although any malignancy can spread to the leptomeninges, breast cancer, particularly the HER2+ subtype, is its most common origin. HER2+ breast LC (HER2+ LC) remains incurable, with few treatment options, and the molecular mechanisms underlying proliferation of HER2+ breast cancer cells in the acellular, protein, and cytokine-poor leptomeningeal environment remain elusive. Therefore, we sought to characterize signaling pathways that drive HER2+ LC development as well as those that restrict its growth to leptomeninges. Primary HER2+ LC patient-derived (“Lepto”) cell lines in coculture with various central nervous system (CNS) cell types revealed that oligodendrocyte progenitor cells (OPC), the largest population of dividing cells in the CNS, inhibited HER2+ LC growth in vitro and in vivo, thereby limiting the spread of HER2+ LC beyond the leptomeninges. Cytokine array–based analyses identified Lepto cell–secreted GMCSF as an oncogenic autocrine driver of HER2+ LC growth. LC/MS-MS-based analyses revealed that the OPC-derived protein TPP1 proteolytically degrades GMCSF, decreasing GMCSF signaling and leading to suppression of HER2+ LC growth and limiting its spread. Finally, intrathecal delivery of neutralizing anti-GMCSF antibodies and a pan-Aurora kinase inhibitor (CCT137690) synergistically inhibited GMCSF and suppressed activity of GMCSF effectors, reducing HER2+ LC growth in vivo. Thus, OPC suppress GMCSF-driven growth of HER2+ LC in the leptomeningeal environment, providing a potential targetable axis. Significance: This study characterizes molecular mechanisms that drive HER2+ leptomeningeal carcinomatosis and demonstrates the efficacy of anti-GMCSF antibodies and pan-Aurora kinase inhibitors against this disease.
GATA3 has been identified as one of the most frequently mutated genes in breast cancer. In the METABRIC cohort, among 1,980 patient cases, 230 breast cancers harbored GATA3 mutations (~12%). 75% of the GATA mutations were observed in luminal breast tumors (47% in luminal A, 28% in luminal B). The recent genomic data in metastatic breast cancer also showed that the frequency of GATA3 somatic mutations was even higher in the metastatic breast cancer cohort. Lung, lymph nodes, and brain metastases were observed in the GATA3 mutant breast cancer patients. Based on these patient genomic data, GATA3 mutations have been considered as cancer drivers, yet the functional consequences of GATA3 mutations are underexplored. We and other groups previously identified that patients carrying GATA3 mutations have diverse clinical features. More than 70% of cases are small nucleotide deletions or insertions (indel), while less than 30% are missense mutations. By classifying the GATA3 indel mutations into 4 groups, we observed distinct clinical features. Somatic mutations found in the GATA3 second zinc-finger domain (ZnFn2) are significantly associated with poorer patient outcomes including worse patient survival. ZnFn2 mutations are predominantly found in luminal B breast tumors, while splice site mutations are frequently found in luminal A breast tumors and associated with better patient survival. These distinct clinical features clearly suggest the differential impacts of GATA3 mutations on breast cancer cells. To dissect the function of GATA3 mutants, we developed a GATA3 mutant cell line (R330fs/WT T47D cells) by CRISPR, which endogenously expresses a heterozygous R330 frame-shift (R330fs) mutant. R330fs mutations are found in multiple data cohorts. The majority (>90%) of GATA3 mutations are heterozygous. Therefore, this R330fs mutant T47D cell line mimics the type of alteration found in patients. Importantly, we found that the R330fs mutation induces transcriptional reprogramming in T47D luminal breast cancer cells leading to more aggressive phenotypes such as faster tumor growth. In the mutant cells, many epithelial marker genes (such as progesterone receptor and TFF1) were down-regulated while mesenchymal marker genes (such as TWIST1 and SNAI2) are up-regulated suggesting that R330fs induces a partial EMT in T47D cells. We also found that transcriptional changes in the R330fs mutant cells were strongly associated with redistribution of GATA3, Estrogen Receptor alpha, and FOXA1. Gene expression profiles in the other GATA3 mutant breast cancer cell lines also suggest similar genomic alterations. These results suggest the active roles of GATA3 mutations during breast cancer development. Citation Format: Motoki Takaku, Mika Saotome, Renju Nair. Breast cancer derived GATA3 mutations disrupt luminal transcriptional network [abstract]. In: Proceedings of the 2021 San Antonio Breast Cancer Symposium; 2021 Dec 7-10; San Antonio, TX. Philadelphia (PA): AACR; Cancer Res 2022;82(4 Suppl):Abstract nr P3-09-12.
Biologically precise enhancer licensing by lineage-determining transcription factors enables activation of transcripts appropriate to biological demand and prevents deleterious gene activation. This essential process is challenged by the millions of matches to most transcription factor binding motifs present in many eukaryotic genomes, leading to questions about how transcription factors achieve the exquisite specificity required. The importance of chromatin remodeling factors to enhancer activation is highlighted by their frequent mutation in developmental disorders and in cancer. Here we determine the roles of CHD4 to enhancer licensing and maintenance in breast cancer cells and during cellular reprogramming. In unchallenged basal breast cancer cells, CHD4 modulates chromatin accessibility at transcription factor binding sites; its depletion leads to altered motif scanning and redistribution of transcription factors to sites not previously occupied. During GATA3-mediated cellular reprogramming, CHD4 activity is necessary to prevent inappropriate chromatin opening and enhancer licensing. Mechanistically, CHD4 competes with transcription factor-DNA interaction by promoting nucleosome positioning over binding motifs. We propose that CHD4 acts as a chromatin proof-reading enzyme that prevents inappropriate gene expression by editing binding site selection by transcription factors.
Biologically precise enhancer licensing by lineage-determining transcription factors enables activation of transcripts appropriate to biological demand and prevents deleterious gene activation. This essential process is challenged by the millions of matches to most transcription factor binding motifs present in many eukaryotic genomes, leading to questions about how transcription factors achieve the exquisite specificity required. The importance of chromatin remodeling factors to enhancer activation is highlighted by their frequent mutation in developmental disorders and in cancer. Here we determine the roles of CHD4 to enhancer licensing and maintenance in breast cancer cells and during cellular reprogramming. In unchallenged basal breast cancer cells, CHD4 modulates chromatin accessibility at transcription factor binding sites; its depletion leads to altered motif scanning and redistribution of transcription factors to sites not previously occupied. During GATA3-mediated cellular reprogramming, CHD4 activity is necessary to prevent inappropriate chromatin opening and enhancer licensing. Mechanistically, CHD4 competes with transcription factor-DNA interaction by promoting nucleosome positioning over binding motifs. We propose that CHD4 acts as a chromatin proof-reading enzyme that prevents inappropriate gene expression by editing binding site selection by transcription factors.
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