Project description:The patients with locally advanced squamous cervical cancer (SCC) were examined in this study. All patients received neoadjuvant chemotherapy followed by radical hysterectomy. Tumor response against NAC was determined based on RECIST criterior. Gene-expression profiles of SCC were determined using Human Genome GeneChip arrays U133. SCC patients who had undergone radical hysterectomy after NAC were studied. To identify molecular signatures to predict response to NAC using Irinotecan/Nedaplatin, gene expression profiles were compared between NAC Reponder and Non-responder.

Project description:The combination of PD-1 blockade with neoadjuvant chemotherapy (NAC) has achieved unprecedented clinical success in non-small-cell lung cancer (NSCLC) compared to NAC alone, but the underlying mechanisms by which PD-1 blockade augments the effects of chemotherapy remain incompletely elucidated. Single-cell RNA sequencing was performed on CD45+ immune cells isolated from surgically resected fresh tumor tissues of seven NSCLC patients receiving NAC or neoadjuvant pembrolizumab and chemotherapy (NAPC). Multiplex fluorescent immunohistochemistry was performed on paired FFPE tissues before and after NAC or NAPC from 65 resectable NSCLC patients, and results were validated with GEO dataset. NAC resulted in an increase only of CD20+ B cells, whereas NAPC increased the infiltration of CD20+ B cells, CD4+ T cells, CD4+CD127+ T cells, CD8+ T cells, CD8+CD127+ and CD8+KLRG1+ T cells. Synergistic increase in B and T cells promotes favorable therapeutic response after NAPC. Spatial distribution analysis discovered that CD8+ T cells and their CD127+ and KLRG1+ subsets were in closer proximity to CD4+ T/CD20+ B cells in NAPC versus NAC. GEO dataset validated that B-cell, CD4, memory and effector CD8 signatures correlated with therapeutic responses and clinical outcomes. The adding of PD-1 blockade to NAC promoted anti-tumor immunity through T and B cells recruitment in the tumor microenvironment and induced tumor-infiltrating CD8+ T cells skewed toward CD127+ and KLRG1+ phenotypes，which may be assisted by CD4+ T cells and B cells. Our comprehensive study identified key immune cell subsets exerting anti-tumor responses during PD-1 blockade therapy and that may be therapeutically targeted to improve upon existing immunotherapies for NSCLC.

Project description:<p>Checkpoint blockade therapy using antibodies targeting CTLA4, PD1 or PDL1 have changed the way cancer patients with advanced disease are being treated, as evident by their FDA approval in a wide variety of malignancies, and their ability to induce high response rates when compared to conventional therapies (e.g. chemotherapy). However, even in melanoma, despite the high response rate, most patients are refractory to therapy or acquire resistance in 10-12 months. To identify key immunological elements coupled with response or resistance to checkpoint immunotherapy, we performed an unbiased analysis on 16,291 CD45&#43; immune cells from 32 patients (48 samples) treated with checkpoint therapy (anti-PD1&#61;37; anti-PD1/CTLA4&#61;11), using single cell transcriptomics. Initial unsupervised clustering of all CD45&#43; cells identified 11 clusters. When examining the association of these clusters with clinical outcome, we found that two clusters (B-cells, p&#61;0.005; memory T-cells, p&#61;0.03) were significantly enriched in responder lesions while 4 clusters (monocytes/macrophages, p&#61;0.003; dendritic cells, p&#61;0.015; exhausted CD8&#43; T-cells, p&#61;0.005; and exhausted/cell-cycle lymphocytes, 1.3x10^-5) are enriched in non-responder lesions. Next, by leveraging our unbiased single cell approach, we identified not only clusters but also specific markers associated with either responder lesions (PLAC8, LTB, LY9, SELL, TCF7, IGKC and CCR7) or non-responder ones (CCL3, CD38, HAVCR2, ENTPD1 and WARS), many of which were not previously reported to be associated with clinical outcome to checkpoint therapy. Due to the importance of CD8&#43; T-cells in controlling tumors, the significant association of T-cell states with clinical outcome, and their high abundance in melanoma tumors, we next focused our analysis on CD8&#43; T-cells and identified 2 main clusters CD8_G (with increased expression of genes linked to memory) and CD8_B (enriched for genes linked to cell dysfunction), that were significantly enriched in responder (CD8_G, p&#61;1.4x10^-6) and non-responder (CD8_B, p&#61;0.005) lesions, respectively. Since cells with both states coexist in each of the responder and non-responder lesions, we decided to calculate the ratio between the number of cells in these 2 clusters and observed a significant separation between responders (CD8_G/CD8_B&#62;1) and non-responders (CD8_G/CD8_B&#60;1) when looking at all samples, baseline or post samples separately. Similar results were detected when looking at the expression of a single transcription factor, TCF7, in CD8 T-cells in an independent cohort (n&#61;43) using a simple immunofluorescence assay. Additionally, we validated the identity and function of some of the newly identified cell states as well as their epigenetic landscape, and found that cells expressing the inhibitory molecules CD39 and TIM3, on top of being enriched in non-responder lesions, are likely to play a crucial role in T-cell exhaustion in melanoma. Collectively, our study provides extensive unbiased data in human tumors for discovery of predictors and therapeutic targets to checkpoint immunotherapy.</p>

Project description:In this study, we comprehensively investigated the impact of neoadjuvant chemotherapy (NAC) on immune cells in the tumor microenvironment (TME) of esophageal squamous cell carcinoma (ESCC) using single cell RNA sequence. CD8+ T cells, CD4+ T cells, dendritic cells, and macrophages in TME of ESCC all showed higher levels of anti-tumor immune response in the NAC(+) group than in the NAC(-) group. Furthermore, the immune cells in the TME of the NAC(+) group interacted with each other to enhance the anti-tumor immune response. Our results suggest that NAC potentially enhance the anti-tumor immune response of immune cells in the TME.

Project description:Neoadjuvant chemotherapy (NAC) is the major pre-treatment for breast cancer before surgery. Patients who achieve pathologic complete response (pCR) have a higher chance to receive lumpectomy and a better quality of life after neoadjuvant treatment. Luminal subtype breast cancer has poor NAC response compared with triple-negative breast cancer (TNBC) subtype. The molecular and cellular mechanisms underlying this chemoresistance are not fully understood. Here we report that the 17 featured transcriptional factors (TFs) in luminal and TNBC were identified. The association between 17 TFs and NAC pCR were analysis and exogenous luminal featured TF GATA3 overexpression promotes chemotherapy resistance in TNBC cell lines whereas its knockdown promotes sensitivity. In mechanism, we found that anthracycline based chemotherapy induces robust cellular ROS and Fe2+ overload in sensitivity cells; GATA3 mediates cell survival through repress CYB5R2 expression and Fenton reducing in DOX recycle which reduce cellular ROS and Fe2+ level during chemotherapy procedure. These founding altogether indicate that luminal featured transcription factor GATA3 enhance NAC resistance thorough repress ROS production and Fenton reducing. Breast cancer patient with GATA3 high expression might not suit for anthracycline based NAC regimen.

Project description:In this study, we have analyzed the transcriptional patterns of breast cancer cell lines and tumors of NAC resistant patients evaluated by GGI, and screened potential genes associated with chemoresistance. Furthermore, we have constructed a neoadjuvant chemotherapy response risk model and examined the evaluation accuracy of the risk score for NAC response. We conducted molecular bioinformatics analysis of the genes that constitute the chemotherapy resistance risk score, and explored potential drugs to reverse breast cancer chemotherapy resistance. Finally, we have examined the the risk score for predicting prognosis in breast cancer. In all, we have reported a novel signature to evaluate neoadjuvant chemotherapy response and predicts prognosis in breast cancer, and screened out potential drugs to reverse chemotherapy resistance in breast cancer.

Project description:Reliable blood-based tests for identifying early-stage breast cancer remain elusive. Employing single-cell transcriptomic sequencing analysis, we illustrate a close correlation between nucleotide metabolism in breast tumor cells and activation of regulatory T cells (Tregs) in the tumor microenvironment, which show distinction in subtypes of triple-negative breast cancer (TNBC) and non-TNBC patients and likely to impact on prognosis of BC through A2AR-Treg pathway. Combining machine learning with absolute quantitative plasma metabolomics, we establish an effective diagnostic model for early-stage breast cancer, utilizing a four-metabolite panel including two nucleoside metabolites, inosine and uridine. This metabolomics study, involving 1111 participants, demonstrates high accuracy across training, test, and independent validation cohorts. Surprisingly, inosine and uridine prove predictive of the response to neoadjuvant chemotherapy (NAC) in TNBC patients. This study deepens the understanding of nucleotide metabolism in development of breast cancer and introduces a promising non-invasive approach with low radiation exposure for early breast cancer detection and predicting NAC response in TNBC patients.

Project description:Despite objective responses to PARP inhibition and improvements in progression-free survival compared to standard chemotherapy in patients with BRCA-associated triple-negative breast cancer (TNBC), benefits are transitory. Using high dimensional single-cell profiling of human TNBC, here we demonstrate that macrophages are the predominant infiltrating immune cell type in BRCA-associated TNBC. Through multi-omics profiling we show that PARP inhibitors enhance both anti- and pro-tumor features of macrophages through glucose and lipid metabolic reprogramming driven by the sterol regulatory element-binding protein 1 (SREBP-1) pathway. Combined PARP inhibitor therapy with CSF-1R blocking antibodies significantly enhanced innate and adaptive anti-tumor immunity and extends survival in BRCA-deficient tumors in vivo and is mediated by CD8+ T-cells. Collectively, our results uncover macrophage-mediated immune suppression as a liability of PARP inhibitor treatment and demonstrate combined PARP inhibition and macrophage targeting therapy induces a durable reprogramming of the tumor microenvironment, thus constituting a promising therapeutic strategy for TNBC.

Project description:Many studies have shown association of tumor infiltrating B-cells and presence of tertiary lymphoid structure with improved clinical responses to immune checkpoint inhibitors therapy. We hypothesized that their presence could also have an impact on TIL therapy response. To address this, we performed RNA-seq of FFPE samples from a cohort of patients that received TIL therapy. Melanoma tumors collected prior to TIL infusion were evaluated for immune content in 9 responders and 11 non-responders to TIL therapy. Our data demonstrate an increase in class-switched memory B-cells in responders compared with non-responders to TIL therapy. In the myeloid compartment, increased presence of dendritic cell populations (pDC, aDC, and iDC) and basophils was observed in responders to TIL therapy, as well as higher content of γδ T cells and effector memory CD8+ T cells (CD8+ Tem) in the T-cell compartment. Next, we assessed the TLS presence in the same cohort by a gene expression signature of 12 chemokines using principal component analysis. The responders showed a higher TLS score compared with the non-responder patients, suggesting that patients responding to TIL therapy had more TLS in their tumors than the non-responder patients. These observations indicate that, same as in the immune checkpoint inhibitors therapy response, presence of B-cells and TLS might have a positive impact in the clinical outcome to TIL therapy.

Project description:The presence of liver tumor changes the transcriptome of SQ tumor-infiltrating adaptive and innate immune cells. We report differential transcriptomic changes within in the SQ tumor immune infiltrate of mice with and without concurrent liver tumor implantation within their livers. We show heatmap displaying the top 20 differentially expressed genes by SQ MDSC and Tregs between the two groups via scRNAseq. Violin plots showing the top 2 differentially upregulated genes by SQ Tregs from mice with liver tumor. Heatmap displaying the top 20 differentially upregulated genes by SQ CD8 T cells between the two groups. Violin plots showing differential expression of ICOS and CTLA-4 by SQ CD8 T cells between the two groups. Unbiased re clustering (UMAP) and stacked bar graph of relative frequencies of monocyte/myeloid cells showing 9 distinct scRNAseq subclusters. Violin plots showing relative MDSC score ordered by monocyte/myeloid cell subclusters. Our data suggests that mice with liver tumors have increased activation of Tregs, decreased activation of CD8 T cells and transcriptomic modifications within the MDSC compartment within their SQ tumors.