Abstract
Treatment-induced neuroendocrine transdifferentiation (NEtD) complicates therapies for metastatic prostate cancer (PCa). Based on evidence that PCa cells can transdifferentiate to other neuroectodermally-derived cell lineages in vitro, we proposed that NEtD requires first an intermediary reprogramming to metastable cancer stem-like cells (CSCs) of a neural class and we demonstrate that several different AR+/PSA+ PCa cell lines were efficiently reprogrammed to, maintained and propagated as CSCs by growth in androgen-free neural/neural crest (N/NC) stem medium. Such reprogrammed cells lost features of prostate differentiation; gained features of N/NC stem cells and tumor-initiating potential; were resistant to androgen signaling inhibition; and acquired an invasive phenotype in vitro and in vivo. When placed back into serum-containing mediums, reprogrammed cells could be re-differentiated to N-/NC-derived cell lineages or return back to an AR+ prostate-like state. Once returned, the AR+ cells were resistant to androgen signaling inhibition. Acute androgen deprivation or anti-androgen treatment in serum-containing medium led to the transient appearance of a sub-population of cells with similar characteristics. Finally, a 132 gene signature derived from reprogrammed PCa cell lines distinguished tumors from PCa patients with adverse outcomes. This model may explain neural manifestations of PCa associated with lethal disease. The metastable nature of the reprogrammed stem-like PCa cells suggests that cycles of PCa cell reprogramming followed by re-differentiation may support disease progression and therapeutic resistance. The ability of a gene signature from reprogrammed PCa cells to identify tumors from patients with metastasis or PCa-specific mortality implies that developmental reprogramming is linked to aggressive tumor behaviors.
Highlights
Hormone therapies for advanced prostate cancer (PCa) can shrink metastatic lesions, slow tumor growth and significantly extend patient survival
Based on evidence that PCa cells can transdifferentiate to other neuroectodermally-derived cell lineages in vitro, we proposed that neuroendocrine transdifferentiation (NEtD) requires first an intermediary reprogramming to metastable cancer stem-like cells (CSCs) of a neural class and we demonstrate that several different androgen receptor (AR)+/prostate specific antigen (PSA)+ PCa cell lines were efficiently reprogrammed to, maintained and propagated as CSCs by growth in androgen-free neural/neural crest (N/NC) stem medium
When we cultured any of four AR+ PCa cell lines (LNCaP, VCaP, LAPC4 and 22Rv1) in N/NC StemTransition Medium (STM), they underwent a marked change in morphology, characterized by transition to cells with a rounded body, enlarged nuclei and strikingly distinct nucleoli (Figure 1B) over the period of a week
Summary
Hormone therapies for advanced prostate cancer (PCa) can shrink metastatic lesions, slow tumor growth and significantly extend patient survival. They remain palliative as treated patients usually progress to castration resistant disease (CRPC) that portends lethality [1]. The clinical success of a new generation of anti-androgens in further prolonging survival of CRPC patients demonstrates that promiscuous androgen receptor (AR) activity plays a role in hormone resistance [2]. While neuroendocrine PCa (NEPC) remains a relatively limited condition, its occurrence is increasing under the constraints of stringent anti-androgen therapies and its aggressive nature raises concerns that NEtD will increasingly confound opportunities for disease control
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