Murine and human invariant natural killer T (iNKT) lymphocytes are activated by agalactosylceramide (a-GalCer) presented on CD1d. a-GalCer was first described as a lipid that had strong anti-metastatic effects in a mouse melanoma model, and it has subsequently been shown to induce efficient iNKT cell dependent tumor immunity in several tumor models. We have shown that a-GalCer treatment leads to a weak reduction of polyp burden in the autochthonous Apc Min/+ mouse model for human colon cancer, however this treatment resulted in upregulation of the inhibitory receptor PD-1 on iNKT cells. While anti-PD-1 treatment can prevent immune-suppression in other cancer types, human colon cancer is generally resistant to this treatment. Here we have used the Apc Min/+ model to investigate whether a combined treatment with a-GalCer and PD-1 blockade results in improved effects on polyp development. We find that PD-1 expression was high on T cells in polyps and lamina propria (LP) of Apc Min/+ mice compared to polyp free Apc+/+ littermates. Anti-PD-1 treatment alone promoted Tbet expression in iNKT cells and CD4 T cells, but did not significantly reduce polyp numbers. However, the combined treatment with anti-PD-1 and a-GalCer had synergistic effects, resulting in highly significant reduction of polyp numbers in the small and large intestine. Addition of PD-1 blockade to a-GalCer treatment prevented loss of iNKT cells that were skewed towards a TH1-like iNKT1 phenotype specifically in polyps. It also resulted in TH1 skewing and increased granzyme B expression of CD4 T cells. Taken together this demonstrates that a combination of immune stimulation targeting iNKT cells and checkpoint blockade may be a promising approach to develop for improved tumor immunotherapy.
Chemotherapy resistance and relapses are common in high-risk neuroblastoma (NB). Here, we developed a clinically relevant in vivo treatment protocol mimicking the first-line five-chemotherapy treatment regimen of high-risk NB and applied this protocol to mice with MYCN -amplified NB patient-derived xenografts (PDXs). Genomic and transcriptomic analyses were used to reveal NB chemoresistance mechanisms. Intrinsic resistance was associated with high genetic diversity and an embryonic phenotype. Relapsed NB with acquired resistance showed a decreased adrenergic phenotype and an enhanced immature mesenchymal–like phenotype, resembling multipotent Schwann cell precursors. NBs with a favorable treatment response presented a lineage-committed adrenergic phenotype similar to normal neuroblasts. Novel integrated phenotypic gene signatures reflected treatment response and patient prognosis. NB organoids established from relapsed PDX tumors retained drug resistance, tumorigenicity, and transcriptional cell states. This work sheds light on the mechanisms of NB chemotherapy response and emphasizes the importance of transcriptional cell states in chemoresistance.
Traditional cancer treatments, such as chemotherapy and radiation therapy continue to have limited efficacy due to tumor hypoxia. While bacterial cancer therapy has the potential to overcome this problem, it comes with the risk of toxicity and infection. To circumvent these issues, this paper investigates the anti-tumor effects of non-viable bacterial derivatives of Clostridium sporogenes. These non-viable derivatives are heat-inactivated C. sporogenes bacteria (IB) and the secreted bacterial proteins in culture media, known as conditioned media (CM). In this project, the effects of IB and CM on CT26 and HCT116 colorectal cancer cells were examined on a 2-Dimensional (2D) and 3-Dimensional (3D) platform. IB significantly inhibited cell proliferation of CT26 to 6.3% of the control in 72 hours for the 2D monolayer culture. In the 3D spheroid culture, cell proliferation of HCT116 spheroids notably dropped to 26.2%. Similarly the CM also remarkably reduced the cell-proliferation of the CT26 cells to 2.4% and 20% in the 2D and 3D models, respectively. Interestingly the effect of boiled conditioned media (BCM) on the cells in the 3D model was less inhibitory than that of CM. Thus, the inhibitive effect of inactivated C. sporogenes and its conditioned media on colorectal cancer cells is established.
Chemotherapy resistance and relapses are common in high-risk neuroblastoma (NB), an aggressive pediatric solid tumor of the sympathetic nervous system. Here, we developed a clinically-relevant in vivo treatment protocol mimicking the first line five-chemotherapy treatment regimen of high-risk NB and applied this protocol to mice with MYCN-amplified NB patient-derived xenografts (PDXs). Genomic and transcriptomic analyses were used to reveal the genetic and non-genetic mechanisms involved in NB chemoresistance. We observed convergent and parallel evolution of key NB genetic aberrations over time. Intrinsic resistance to chemotherapy was associated with high genetic diversity and an embryonic phenotype. Relapsed NB PDX tumors with acquired resistance showed an immature mesenchymal-like phenotype resembling multipotent Schwann cell precursors that are found in the adrenal gland. NBs with a successful treatment response presented a lineage-committed adrenergic phenotype similar to normal neuroblasts, reduced cell cycle gene expression, and negative regulation of the mitogen-activated protein kinase (MAPK)/extracellular signal-regulated kinase (ERK) cascade. NB organoids established from relapsed PDX tumors retained drug resistance, tumorigenicity, and transcriptional cell states ex vivo. This work sheds light on mechanisms involved in NB chemotherapy response in vivo and ex vivo using a clinically-relevant protocol, and emphasizes the importance of transcriptional cell states in treatment response. Detailed characterization of resistance mechanisms is essential for the development of novel treatment strategies in non-responsive or relapsed high-risk NB.
ix for coming into my life and standing by me through thick and thin. You had faith in me when I wanted to give up, and you motivated me to overcome every challenge that came my way. Thank you for inspiring me to become a better researcher and a better person.
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