AI Article Synopsis
- Maspin is a special protein that helps stop tumors, but when found in certain cancer cells, it might actually mean a worse outcome for patients.
- Researchers suggest that cancer stem cells (CSCs) need to be 'primed' before they can grow into different types of cells, just like special stem cells in normal development.
- The study looks at how Maspin might help scientists understand these cancer stem cells better and create new treatments that target them, which could lead to better therapies for cancer.
Article Abstract
Epithelial-specific Maspin is widely known as a tumor suppressor. However, while the level of maspin expression is inversely correlated with tumor grade and stage, emerging clinical evidence shows a correlation between seemingly better differentiated tumor cells that express Maspin in both the nucleus and the cytoplasm, (n + c)Maspin, with a poor prognosis of many types of cancer. Biological studies demonstrate that Maspin plays an essential role in stem cell differentiation. In light of the recently established characterization of primed stem cells (P-SCs) in development, we propose, for the first time, that cancer stem cells (CSCs) also need to undergo priming (P-CSCs) before their transition to various progeny phenotypes. We envisage major differences in the steady state kinetics between P-SCs and P-CSCs. We further propose that P-CSCs of carcinoma are both marked and regulated by (n + c)Maspin. The concept of P-CSCs helps explain the apparent dichotomous relationships of (n + c)Maspin expression with cancer diagnosis and prognosis, and is supported by the evidence from mechanistic studies. We believe that the potential utility of (n + c)Maspin as a molecular marker of P-CSCs may significantly accelerate the advancement in our understanding of the genesis of tumor phenotypic plasticity in response to changes of tumor microenvironments (TME) or drug treatments. The vulnerabilities of the cellular state of (n + c)Maspin-expressing P-CSCs are also discussed as the rationale for future development of P-CSC-targeted chemotherapeutic and immunotherapeutic strategies.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9713111 | PMC |
| http://dx.doi.org/10.1007/s10555-022-10070-2 | DOI Listing |
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