Project description:Tumors can occur in many sites in the body, but how tissues at different anatomical sites affect tumor microenvironments and their subsequent response to therapy is not known. Here we show that different tissues can cause the same tumor to develop fundamentally different microenvironments resulting in dramatic changes in responses to immunotherapy. Whereas established subcutaneous tumors could be eradicated in the majority of mice using a combination of three agonist antibodies, tumors in visceral organs responded much less. Orthotopic kidney tumors had a microenvironment with a higher frequency of alternatively-activated macrophages and their associated molecules. Neutralizing the CCL2 chemokine or IL-13 cytokine, important in macrophage biology led to a greatly improved therapeutic effect. Importantly, a significantly reduced therapeutic response of subcutaneous tumors was observed when visceral tumors were simultaneously present in the same mice. In this study we sought to compare gene expression of mouse renal cell carcinoma cells growing in the kidney to cells growing subcutaneously. Renca is a renal cell carcinoma cell line (Murphy and Hrushesky, 1973). To produce subcutaneous tumors, mice received 2 x 10^5 Renca. Orthotopic tumors were established by first surgically isolating the organ and then injecting 2 x 10^5 Renca cells intrakidney (IK) into the outer cortex of the kidney in 20 ul of PBS. Tumors were removed from mice 12 days after implantation, when approximately 20-30 mm2. Tumors were snap frozen on liquid nitrogen prior to processing for total RNA followed by analysis on Mouse Gene 1.0 chips. Kidney Renca tumors were excised from 3 BALB/c mice and subcutaneous Renca tumors were excised from another 3 BALB/c mice. cDNA was prepared and hybridized to Mouse Gene 1.0 ST chips.

Project description:In this study, we aimed to evaluate the effect of M2-like macrophages in the injured kidney on kidney cancer progression. As an acute kidney injury to chronic kidney disease model, we used unilateral ischemia-reperfusion injury (uIRI). And we inoculated RenCa cells, which are murine kidney cancer cell line, into renal subcapsule 14 days after uIRI (uIRI-Can) and compared uIRI-Can to RenCa cells inoculated into sham-operated renal subcapsule (Sham-Can) 20 days after inoculation. To identify gene characteristics of M2-like macrophages that are commonly detected both in the uIRI kidney cortex and uIRI-Can, we sorted Ly6Clow macrophages from 4 groups, uIRI kidney cortex, sham kidney cortex, uIRI-Can, and Sham-Can, and conducted RNA-Seq. This study revealed the characteristic gene expression of M2-like macrophages which were commonly detected in the injured kidney cortex and kidney cancer progressed on the injured kidney. And this could be a future therapeutic target of macrophage-targeted therapy.

Project description:The mouse renal cancer cell line RENCA was serially passaged in vivo using multiple implantation strategies (called Kidney, Tail and Lung) designed to replicate different aspects of primary tumour growth and metastasis. We have acquired methylomic data.

Project description:Three-dimensional (3D) organoids provide a new way to model various diseases, including cancer. We made use of recently developed kidney-organ-primordia tissue-engineering technologies to create novel renal organoids for cancer gene discovery. We then tested whether our novel assays can be used to examine kidney cancer development. First, we identified the transcriptomic profiles of quiescent embryonic mouse metanephric mesenchyme (MM) and of MM in which the nephrogenesis program had been induced ex vivo. The transcriptome profiles were then compared to the profiles of tumor biopsies from renal cell carcinoma (RCC) patients, and control samples from the same kidneys. Certain signature genes were identified that correlated in the developmentally induced MM and RCC, including components of the caveolar-mediated endocytosis signaling pathway. An efficient siRNA-mediated knockdown (KD) of Bnip3, Gsn, Lgals3, Pax8, Cav1, Egfr or Itgb2 gene expression was achieved in mouse RCC (Renca) cells. The live-cell imaging analysis revealed inhibition of cell migration and cell viability in the gene-KD Renca cells in comparison to Renca controls. Upon siRNA treatment, the transwell invasion capacity of Renca cells was also inhibited. Finally, we mixed the nephron progenitors with yellow fluorescent protein (YFP)-expressing Renca cells to establish chimera organoids. Strikingly, we found that the Bnip3-, Cav1- and Gsn-KD Renca-YFP+ cells as a chimera with the MM in 3D organoid rescued, in part, the RCC-mediated inhibition of the nephrogenesis program during epithelial tubules formation. Altogether, our research indicates that comparing renal ontogenesis control genes to the genes involved in kidney cancer may provide new growth-associated gene screens and that 3D RCC-MM chimera organoids can serve as a novel model with which to investigate the behavioral roles of cancer cells within the context of emergent complex tissue structures.

Project description:Pancreatic ductal adenocarcinoma (PDAC) originates from normal pancreatic ducts where digestive juice is regularly produced. It remains unclear how PDAC can escape auto-digestion by digestive enzymes. Here we show that human PDAC tumor cells use gasdermin E (GSDME), a pore-forming protein upon caspase 3 cleavage, to mediate the digestive resistance. We find that GSDME facilitates the expression of mucins 1 and 13 in pancreatic tumor cells, which forms a barrier to prevent chymotrypsin-mediated destruction. Inoculation of GSDME-/- PDAC cells results in subcutaneous but not orthotopic tumor formation in mice. Either inhibiting or knocking out MUC1 or MUC13 abrogates orthotopic PDAC growth in NOD-SCID mice. Mechanistically, GSDME interacts with and transports transcription factor YBX1 into the nucleus where YBX1 directly promotes mucin expression. This GSDME-YBX1-mucin axis is also confirmed in PDAC patients. These findings uncover a unique survival mechanism of PDAC cells in pancreatic microenvironments, thus providing a potential target for PDAC treatment.

Project description:We demonstrated that a visceral immunosuppressive tumor can influence a distant, normally-responsive tumor, located in the skin and rend it resistant to a particular immunotherapy. Examination of the transcriptome of sub-cutaneous tumors that were growing in a mouse model, in the presence or in the absence of a concomitant intra-kidney immunosuppressive tumor

Project description:Comparing gene expression profiles of murine subcutaneous vs. visceral adipose tissue. Gene expression was analyzed in two subcutaneous depots (inguinal and axillary) and two visceral depots (epididymal and mesenteric) from male C57Bl/6 mice. 4 samples were analyzed as two groups: inguinal and axillary (subcutaneous) and epididymal and mesenteric (visceral). Each sample was derived by pooling RNA from the relevant fat depot from 3 age-matched, male C57Bl6 mice.

Project description:Comparing gene expression profiles of murine subcutaneous vs. visceral adipose tissue. Gene expression was analyzed in two subcutaneous depots (inguinal and axillary) and two visceral depots (epididymal and mesenteric) from male C57Bl/6 mice.

Project description:Assessment of secreted proteins from EDL and soleus muscle, as well as visceral and subcutaneous adipose tissue of sedentary and exercise-trained obese male mice.

Project description:Global gene expression was measured with Affymetrix in seven organs after 3 weeks swimming and control (non swimming) C57BL6 male mice, 14wks old ( by the end of the study). We used microarrays to detail the global programme of gene expression indicative of adaptatie changes occuring in seven tissues, skeletal muscle (quadricepts), liver, kidney, subcutaneous and visceral white adipose tissues, spleen, brain, after 3 weeks of swimming