Abstract
Simple SummaryIn addition to the classical cell-to-cell communication patterns, extracellular vesicles (EVs) are instrumental in conveying molecular messages across cell types and have the potential to mediate changes at a tissue level. Since it is now appreciated that carcinomas are fundamentally reliant on two-way communication with activated cells in the tumor microenvironment, elucidating the roles of EVs exchange and of the cargo that is transferred is essential to obtain a thorough understanding of tumor progression. This study reveals that mutant p53 proteins—the result of the most frequent mutated gene in human cancer—are packed into EVs and delivered to neighboring cells with the potential to reprogram immune cells and subsequently establish a positive feedback loop that will enhance tumor progression. This non-cell autonomous role of mutant p53 is evidence of an extra layer of communication that is orchestrated by smaller vesicles that transfer oncogenic elements between cellular entities. Building on the foundation of our work on mutant p53, future studies may aim to characterize the potential activation of additional oncogenes, thus opening new paths of research at the interface of extracellular vesicles, cancer, and evolution.Extracellular vesicles (EVs) shed by cancer cells play a major role in mediating the transfer of molecular information by reprogramming the tumor microenvironment (TME). TP53 (encoding the p53 protein) is the most mutated gene across many cancer types. Mutations in TP53 not only result in the loss of its tumor-suppressive properties but also results in the acquisition of novel gain-of-functions (GOF) that promote the growth of cancer cells. Here, we demonstrate that GOF mutant p53 proteins can be transferred via EVs to neighboring cancer cells and to macrophages, thus modulating them to release tumor supportive cytokines. Our data from pancreatic, lung, and colon carcinoma cell lines demonstrate that the mutant p53 protein can be selectively sorted into EVs. More specifically, mutant p53 proteins in EVs can be taken up by neighboring cells and mutant p53 expression is found in non-tumor cells in both human cancers and in non-human tissues in human xenografts. Our findings shed light on the intricate methods in which specific GOF p53 mutants can promote oncogenic mechanisms by reprogramming and then recruiting non-cancerous elements for tumor progression.
Highlights
Malignant transformation is driven by an accumulation of genetic mutations
It is becoming increasingly clear that extracellular vesicles (EVs) play a major role in shuttling bioactive molecules including proteins, DNA, mRNA, and non-coding RNAs from one cell to another, which mediates the transfer of molecular information and the reprogramming of recipient cells [4,5,6]
In order to investigate whether cancer cells harboring GOF mutant p53 can encapsulate the mutated proteins into EVs and release them using the exosomal machinery, we chose to test several complementary cellular systems that originate from several different types of cancer and that contain a series of different p53 GOF mutations
Summary
When the balance between oncogenic and tumor suppressing events is skewed towards the former during the transformation process, growth control is compromised, which could result in cancer Beyond these well established cell-autonomous driving forces, the entire process is regulated and controlled by myriad factors derived from the non-tumoral surrounding tissue that constitutes the tumor microenvironment (TME) [1,2,3]. While many characteristics of TME modulation are well established, the biochemical basis of TME conversion is not well understood In this respect, it is becoming increasingly clear that extracellular vesicles (EVs) play a major role in shuttling bioactive molecules including proteins, DNA, mRNA, and non-coding RNAs from one cell to another, which mediates the transfer of molecular information and the reprogramming of recipient cells [4,5,6]. The question of whether EVs play an important role in TME subversion via their transfer of mutated protein products from the cancer cells is sparsely studied
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