CD73 mitigates ZEB1 expression in papillary thyroid carcinoma.

BACKGROUND: ZEB1, a core transcription factor involved in epithelial-mesenchymal transition (EMT), is associated with aggressive cancer cell behavior, treatment resistance, and poor prognosis across various tumor types. Similarly, the expression and activity of CD73, an ectonucleotidase implicated in adenosine generation, is an important marker of tumor malignancy. Growing evidence suggests that EMT and the adenosinergic pathway are intricately linked and play a pivotal role in cancer development. Therefore, this study focuses on exploring the correlations between CD73 and ZEB1, considering their impact on tumor progression. METHODS: We employed CRISPR/Cas9 technology to silence CD73 expression in cell lines derived from papillary thyroid carcinoma. These same cells underwent lentiviral transduction of a reporter of ZEB1 non-coding RNA regulation. We conducted studies on cell migration using scratch assays and analyses of cellular speed and polarity. Additionally, we examined ZEB1 reporter expression through flow cytometry and immunocytochemistry, complemented by Western blot analysis for protein quantification. For further insights, we applied gene signatures representing different EMT states in an RNA-seq expression analysis of papillary thyroid carcinoma samples from The Cancer Genome Atlas. RESULTS: Silencing CD73 expression led to a reduction in ZEB1 non-coding RNA regulation reporter expression in a papillary thyroid carcinoma-derived cell line. Additionally, it also mitigated ZEB1 protein expression. Moreover, the expression of CD73 and ZEB1 was correlated with alterations in cell morphology characteristics crucial for cell migration, promoting an increase in cell polarity index and cell migration speed. RNA-seq analysis revealed higher expression of NT5E (CD73) in samples with BRAF mutations, accompanied by a prevalence of partial-EMT/hybrid state signature expression. CONCLUSIONS: Collectively, our findings suggest an association between CD73 expression and/or activity and the post-transcriptional regulation of ZEB1 by non-coding RNA, indicating a reduction in its absence. Further investigations are warranted to elucidate the relationship between CD73 and ZEB1, with the potential for targeting them as therapeutic alternatives for cancer treatment in the near future.

Mitochondrial response of glioma cells to temozolomide.

Metabolic adaptations are central for carcinogenesis and response to therapy, but little is known about the contribution of mitochondrial dynamics to the response of glioma cells to the standard treatment with temozolomide (TMZ). Glioma cells responded to TMZ with mitochondrial mass increased and the production of round structures of dysfunctional mitochondria. At single-cell level, asymmetric mitosis contributed to the heterogeneity of mitochondrial levels. It affected the fitness of cells in control and treated condition, indicating that the mitochondrial levels are relevant for glioma cell fitness in the presence of TMZ.

The role of mitosis in generating fitness heterogeneity.

Cancer cells have heterogeneous fitness, and this heterogeneity stems from genetic and epigenetic sources. Here, we sought to assess the contribution of asymmetric mitosis (AM) and time on the variability of fitness in sister cells. Around one quarter of sisters had differences in fitness, assessed as the intermitotic time (IMT), from 330 to 510 min. Phenotypes related to fitness, such as ERK activity (herein referring to ERK1 and ERK2, also known as MAPK3 and MAPK1, respectively), DNA damage and nuclear morphological phenotypes were also asymmetric at mitosis or turned asymmetric over the course of the cell cycle. The ERK activity of mother cell was found to influence the ERK activity and the IMT of the daughter cells, and cells with ERK asymmetry at mitosis produced more offspring with AMs, suggesting heritability of the AM phenotype for ERK activity. Our findings demonstrate how variabilities in sister cells can be generated, contributing to the phenotype heterogeneities in tumor cells.

Adipose-derived stromal cell secretome disrupts autophagy in glioblastoma.

Mesenchymal stromal cells (MSCs) are frequently recruited to tumor sites to play a part in the tumor microenvironment (TME). However, their real impact on cancer cell behavior remains obscure. Here we investigated the effects of human adipose-derived stromal cell (hADSC) secretome in autophagy of glioblastoma (GBM), as a way to better comprehend how hADSCs influence the TME. GBM U-87 MG cells were treated with conditioned medium (CM) from hADSCs and autophagic flux was evaluated. hADSC CM treatment blocked the autophagic flux in tumor cells, as indicated by the accumulation of autophagosomes in the cytosol, the high LC3-II and p62/SQSTM1 protein levels, and the lack of increase in the amount of acidic vesicular organelles. These effects were further detected in other GBM cell lines tested and also in co-cultures of hADSCs and U-87 MG. hADSC CM did not compromise lysosomal acidification; however, it was able to activate mTORC1 signaling and, as a consequence, led to a decrease in the nuclear translocation of TFEB, a master transcriptional regulator of lysosomal biogenesis and autophagy, thereby contributing to a defective autophagic process. hADSCs secrete transforming growth factor beta 1 (TGFß1) and this cytokine is an important mediator of CM effects on autophagy. A comprehensive knowledge of MSC roles in tumor biology is of great importance to shed light on the complex dialog between these cells and to explore such interactions therapeutically. The present results help to elucidate the paracrine effects of MSCs in tumors and bring attention to the potential to be explored in MSC secretome. KEY MESSAGES: hADSC secretome specifically affects the biology of GBM cells. hADSCs block the late steps of autophagic flux in GBM cells. hADSC secretome activates mTORC1 signaling and reduces TFEB nuclear translocation in GBM cells.