Project description:Overcoming endocrine-resistance is the major challenge in treating Estrogen receptor (ER)-positive breast cancer. Breast Cancer Stem Cells (BCSCs) are blamed to be the driving force behind poor clinical outcomes and therapeutic resistance. Tumor microenvironment (TME) exerts a selective pressure on the tumor, supporting BCSCs behavior. The most prevalent cellular component of breast TME is represented by adipocytes, which secrete reduced levels of adiponectin in obesity, promoting ERα-positive breast cancer growth and progression. We examined the impact of low adiponectin levels on the enrichment of BCSC subpopulations and the molecular mechanisms by which this may contribute to hormone-resistance in breast cancer.

Project description:Tumor microenvironment (TME) consists of different cell populations, whose interactions contribute to tumor heterogeneity and therapy response. Spatial transcriptomics (ST) offers valuable insights into spatial complexity and heterogeneity of TME. We established a Python package, Geographic Information System (GIS)-augmented In-Silico Reconstruction of Tumor Architecture (GIS-ROTA), based on application of GIS methods to ST data to examine/explore spatial heterogeneity of co-regulated gene sets, such as pathways and cell types within the TME. In our Visium dataset of primary and metastatic estrogen receptor positive breast tumor samples, GIS-ROTA revealed extensive co-localization of estrogen response with metabolic pathway gene sets and mutual exclusivity with metastasis-related and specific immune-related pathway gene sets. Our findings demonstrate the robustness of GIS-ROTA in quantitating tumor heterogeneity and identifying spatially significant regions while minimizing the subjectivity involved in interpreting the clusters from conventional statistical methods. Thus, GIS-ROTA enables the development of therapeutic strategies that target multiple cell populations.

Project description:Tumor targeted therapies have been largely inefficient due to lack of concomitant effects on the tumor microenvironment (TME). We investigated the MAtrix REgulating MOtif (MAREMO) mimicking peptide MP5, that inhibits the pro-tumorigenic extracellular matrix (ECM) molecule tenascin-C, using immunocompetent autologous breast cancer bearing mice. MP5 treatment led to tumor regression and reduced tumor cell dissemination. Several cancer hallmarks were abolished such as tumor cell promoting growth suppression and inhibition of plasticity enhancing responsiveness to death inducers. MP5 acts on other TME players leading to blood vessel normalization and depletion of fibroblasts diminishing the ECM as an orchestrator of immune suppression, causing immune cell infiltration and reactivation of anti-tumor immunity involving IFNgamma. Thus, targeting the tumor matrix using MAREMO in tenascin-C represents a powerful novel anti-cancer strategy.

Project description:Comparing two agonists of interleukin-2 (IL-2), IL-2wt and IL-2nα, differentially reshape the tumor microenvironment (TME). To more comprehensively explore the mechanisms by which the two different IL-2R agonists regulate the TME, we performed single-cell RNA sequencing (scRNA-seq) on immune cells isolated from tumors. We clustered the 18,455 tumor-infiltrating immune cells into 5 populations, and found marked expansion of T cell populations as well as contraction of mononuclear phagocyte populations in both IL-2wt and IL-2nα treated tumors compared with immunoglobulin G (IgG) controls.

Project description:MicroRNA (miRNA/miR) miR526b and miR655 overexpressed tumor cell-free secretions promote breast cancer phenotypes in the tumor microenvironment (TME). However, the mechanisms of miRNA regulating TME have never been investigated. With mass spectrometry analysis of MCF7-miRNA-overexpressed versus miRNA-low MCF7-Mock tumor cell secretomes, we identified 34 novel secretory proteins coded by eight genes YWHAB, TXNDC12, MYL6B, SFN, FN1, PSMB6, PRDX4, and PEA15 those are differentially regulated. We used bioinformatic tools and systems biology approaches to identify these markers’ role in breast cancer. Gene ontology analysis showed that the top functions are related to apoptosis, oxidative stress, membrane transport, and motility, supporting miRNA-induced phenotypes. These secretory markers expression is high in breast tumors, and a strong positive correlation exists between upregulated markers’ mRNA expressions with miRNA cluster expression in luminal A breast tumors. Gene expression of secretome markers is higher in tumor tissues compared to normal samples, and immunohistochemistry data supported gene expression data. Moreover, both up and downregulated marker expressions are associated with breast cancer patient survival. miRNA regulates these marker protein expressions by targeting transcription factors of these genes. Premature miRNA (pri-miR526b and pri-miR655) are established breast cancer blood biomarkers. Here we report novel secretory markers upregulated by miR526b and miR655 (YWHAB, MYL6B, PSMB6, and PEA15) are significantly upregulated in breast cancer patients’ plasma, and are potential breast cancer biomarkers.

Project description:In cancer, improving diagnostics and therapeutic interventions can benefit from understanding the cellular and phenotypic heterogeneity of the tumor microenvironment (TME). In recent years, the TME has been profiled at an unprecedented level of detail by performing single-cell RNA sequencing (scRNAseq) on patient samples. However, from patient samples, studying the temporal dynamics of the TME has been challenging. Characterizing the temporal dynamics of the TME is critical to understand how inter-tumor heterogeneity is organized into a temporally ordered sequence of causes and consequences in cellular events. Here we survey the temporal dynamics of the TME by performing longitudinal scRNAseq on mouse breast tumors at different progression time points. We find multicellular phenotypic dynamics that follow one out of three possible temporal patterns: stable colonization, wave-like, or progressive increase. In particular, IFN-responsive cancer cells, GzmB+ cytotoxic T cells, as well as macrophages of a phagocytic phenotype, progressively increase as tumors progress. These findings establish the single-cell types and phenotypes in a progressing breast tumor, and determine when these players enter and leave the TME. This single-cell dataset could serve to position clinical samples where timing is unknown on a temporal axis of progression, and suggest optimal timing for different therapies.

Project description:Triple-negative breast cancer represents approximately 15–20% of all reported breast cancer cases, and is characterized by a shorter survival time and higher mortality rates compared to other breast cancer sub-types. Tumor microenvironment (TME) refers to the internal and external environment of tumor tissue. Increasing evidence indicates that a tumor’s microenvironment is tightly associated with the immunological surveillance and defense during the development of breast cancer. Although oncology studies employing digital dissection methodologies have provided some insight on the biological features of TME, the development of methods to investigate the cellular composition of the tumor microenvironment remain an important research priority. In this study, we extracted whole transcriptome from 30 Triple-negative breast cancer (TNBC) patients and then used bioinformatics approaches to characterize cell type content in tumor tissue compared with para-cancerous tissue. We identified 4 types of enriched immune cells and 6 types of downregulated immune cells in the tumor tissue samples. After comprehensive bioinformatics analyses, we developed an ‘immune infiltration score’  (IIS) to quantitatively model immune cell infiltration in TNBC. To demonstrate the utility of the IIS, we used 2 independent datasets for validation. We found that patients with a higher IIS showing a longer progression-free survival time and significantly better prognosis than those with a lower IIS value. In sum, we explored the immune infiltration landscape in 30 TNBC patients and provided a novel and reliable biomarker IIS to evaluate the progression-free survival and prognosis in the TNBC patients.

Project description:Cancer is driven by genetic aberrations in the tumor cells and fundamental changes in the tumor microenvironment (TME). These changes offer potential targets for novel therapeutics, yet lack of in vitro 3D models recapitulating this complex microenvironment impedes such progress. Here, we generated tumor-stroma spheroids reflecting the in vivo TME of early and advanced breast tumor, using a high throughput microfluidic system. The spheroids, composed of tumor cells, fibroblasts and activated immune cells, were generated and cultivated on-chip in alginate (Alg) or alginate-alginate sulfate (Alg/Alg-S) hydrogels.

Project description:Breast Cancer Dataset

Project description:Cancer cell metabolic reprogramming reshapes the tumor microenvironment (TME) into a pro-tumor niche. Arginine metabolism plays complex roles in regulating tumor progression through metabolic cross-feeding among various cell types within the TME, but the primary intercellular communication dominating the collective impact of arginine on tumor progression remains unclear. Here, we investigated the role of arginine metabolism in breast cancer progression using clinical analysis, single-cell RNA sequencing data analysis, and in vivo animal models. We found that the metabolic interplay between cancer cells and macrophages exerts a predominant influence on breast cancer progression mediated by arginine metabolism. Breast cancer cells act as the major source of arginine within the TME, where this tumor-derived arginine fosters a pro-tumor shift in tumor-associated macrophages (TAMs), leading them to suppress the anti-tumor activity of CD8+ T cells. Notably, this cancer cell-macrophage interaction overrides the stimulatory effect of arginine on the anti-tumor capability of CD8+ T cells. Mechanistically, polyamines derived from arginine metabolism mediate TAM polarization via TDG-mediated DNA demethylation, driven by p53 signaling. Importantly, inhibiting the arginine-polyamine-TDG axis across cancer cells to macrophages effectively suppresses breast cancer growth by modulating the immune microenvironment, suggesting therapeutic potential in targeting this axis for breast cancer therapy.