A developmental stage-dependent switch of the mechanisms for prostate epithelial maintenance.

P revious studies demonstrated that adult murine prostate basal and luminal cells are independently self-sustained, but prostate basal cells possess the potential to differentiate into multiple lineages upon induction by embryonic urogenital sinus mesenchyme. Nevertheless, it is unknown how prostate epithelia mature during the postnatal stage. Recently, Ousset et al. showed that some prostate basal cells in neonatal mice still possess the capacity for multilineage differentiation, while luminal cells have committed to become unipotent. This study demonstrates a developmental stage-dependent switch of the mechanisms for prostate epithelial maintenance, and implies a critical role of the stromal environment in regulating epithelial maintenance. During the last four decades, much progress has been made in understanding how the prostate develops and how prostate epithelial homeostasis is maintained. Recently, using an elegant lineage tracing approach, Ousset et al. determined how prostate epithelia develop at the postnatal stage. This study corroborated in vivo and in situ, many previous studies showing that prostate basal cells possess the stem cell capacity for multilineage differentiation. In addition, together with other recent studies, this study also reveals a developmental stage-dependent switch of the mechanisms for epithelial maintenance. There are three major types of epithelial cells in the prostate. Luminal cells express low-molecular weight cytokeratins (K8/18) and form a single continuous layer that surrounds glandular lumen filled with secretions. Basal cells express high molecular weight cytokeratins (K5/14) and are aligned between the luminal cells and the basement membrane. Neuroendocrine cells are very rare and are distributed sporadically within prostate acini. Classic work by Isaacs et al. showed that prostate epithelia can undergo extensive turnover in response to fluctuating serum testosterone levels. Because basal cells are independent of androgen for their survival, it has been hypothesized that basal cells contain the stem cells that can functionally regenerate prostate glands. This hypothesis was proven correct from the results of a prostate regeneration assay. It was demonstrated that a fraction of dissociated prostate epithelial cells are capable of forming clonogenic glandular structures that contain all three types of epithelial cells, when they are mixed with embryonic urogenital sinus mesenchymal cells and transplanted under renal capsules of immunodeficient host mice. With this assay, we and a few other groups showed that only basal cells in human and rodents are capable of regenerating prostate glands. One group reported that cells from castrated mice that display a luminal cell phenotype can also regenerate. Subsequently, our group used a lineage tracing approach to further investigate in vivo and in situ how adult prostate epithelial homeostasis is maintained. We used a K14-CreER and a K8-CreERT2 model, in combination with a fluorescent reporter mouse line, to specifically label prostate basal and luminal cells, respectively. We followed the fate of the labeled cells under physiological conditions, as well as under conditions when acute regeneration is induced by androgen deprivation and replacement. Surprisingly, we found that adult murine prostate basal and luminal cells are self-sustained independently. This result raises the question of whether the regenerative capacity of the basal cells in the prostate regeneration assay represents an obligate function of the prostate basal cells in adults in vivo. The study by Ousset et al. provided novel insights for this. The major focus of this study was to examine how prostate epithelia develop at the postnatal stage. Upon birth, male fetal prostate epithelial cells have undergone substantial lineage commitment. Many cells are phenotypically either K5/K14 positive basal cells or K8 positive luminal cells. There are also some intermediate cells that express both basal and luminal cell markers. Ousset et al. used a K14rtTA/TetOCRE/ RosaYFP triple transgenic model through which basal cells can be specifically marked with yellow fluorescent protein upon doxycycline induction. The authors treated newborn mice with doxycycline and demonstrated that only K14-expressing basal cells were labeled with YFP. Interestingly, after a 4-week chase, they identified YFP-expressing basal, luminal and neuroendocrine cells, demonstrating that the newborn fetal basal cells can generate all three different cell lineages. The authors obtained the same results when they performed similar lineage tracing on the K5expressing basal cells using a K5CreER/ RosaYFP bigenic model that enables fluorescent labeling of K5-expressing basal cells upon tamoxifen induction. By titrating doxycycline or tamoxifen, the authors were able to label and trace basal cells at clonal levels. They found that while some fluorescently labeled basal cells can generate foci that contain both basal and luminal cells, other foci contained only basal cells or luminal cells. This observation suggests that at this stage some basal cells have already committed to become unipotent basal or luminal progenitors. The other important conclusion procured from this experiment is that intermediate cells were only found in foci Department of Molecular and Cellular Biology, Baylor College of Medicine, One Baylor Plaza, Houston, TX 77030, USA; Department of Pathology and Immunology, Baylor College of Medicine, One Baylor Plaza, Houston, TX 77030, USA and Dan L. Duncan Cancer Center, Baylor College of Medicine, One Baylor Plaza, Houston, TX 77030, USA Correspondence: Dr L Xin ([email protected]) Asian Journal of Andrology (2013) 15, 85–86 2013 AJA, SIMM & SJTU. All rights reserved 1008-682X/13 $32.00