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Commentary Free access | 10.1172/JCI57700
Children’s Hospital of Oakland Research Institute, Oakland, California, USA.
Address correspondence to: Ervin Epstein, Children’s Hospital of Oakland Research Institute, 5700 MLK Jr Way, Oakland, California 94609, USA. Phone: 510.502.6144; Fax: 510.597.7096; E-mail: eepstein@chori.org.
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Published April 25, 2011 - More info
Uncontrolled Hedgehog (Hh) signaling leads to the development of basal cell carcinoma (BCC), the most common human cancer, but the cell of origin for BCC is unclear. While Hh pathway dysregulation is common to essentially all BCCs, there exist multiple histological subtypes, including superficial and nodular variants, raising the possibility that morphologically distinct BCCs may arise from different cellular compartments in skin. Here we have shown that induction of a major mediator of Hh signaling, GLI2 activator (GLI2ΔN), selectively in stem cells of resting hair follicles in mice, induced nodular BCC development from a small subset of cells in the lower bulge and secondary hair germ compartments. Tumorigenesis was markedly accelerated when GLI2ΔN was induced in growing hair follicles. In contrast, induction of GLI2ΔN in epidermis led to the formation of superficial BCCs. Expression of GLI2ΔN at reduced levels in mice yielded lesions resembling basaloid follicular hamartomas, which have previously been linked to low-level Hh signaling in both mice and humans. Our data show that the cell of origin, tissue context (quiescent versus growing hair follicles), and level of oncogenic signaling can determine the phenotype of Hh/Gli-driven skin tumors, with high-level signaling required for development of superficial BCC-like tumors from interfollicular epidermis and nodular BCC-like tumors from hair follicle stem cells.
Marina Grachtchouk, Joanna Pero, Steven H. Yang, Alexandre N. Ermilov, L. Evan Michael, Aiqin Wang, Dawn Wilbert, Rajiv M. Patel, Jennifer Ferris, James Diener, Mary Allen, Seokchun Lim, Li-Jyun Syu, Monique Verhaegen, Andrzej A. Dlugosz
Identification of the cell of origin of cancers is a hot topic, and recently no fewer than five groups have addressed this question for basal cell carcinomas (BCCs) of the skin. In this issue of the JCI, Grachtchouk et al. present evidence from engineered mouse models that at least some BCCs can arise from hair follicle tissue stem cells. Although these cells sustain oncogenic mutations while in the stem cell niche, they may have to leave that stem cell niche to become tumor cells.
Basal cell carcinomas (BCCs), the most common of human cancers, are so named because of their histologic resemblance to basal keratinocytes (1), the cells of the interfollicular epidermis, sebaceous glands, and hair follicle that abut the dermis. In addition to their morphologic resemblance to these normal cells, BCCs also express keratins 5 and 14, which are characteristic of the normal basal layer. However, this histologic resemblance does not necessarily indicate that the cell that sustains the oncogenic mutation(s) leading to the development of the BCC (aka the “cell of origin”) is a basal cell, nor does it indicate in which basal compartment this cell might reside. In this issue of the JCI, Grachtchouk et al. weigh in on this question (2), extending their previous work (3) and joining a recent flurry of publications from a number of groups — including our own (4) — that address the cell of origin of BCCs using Cre-lox technology to activate hedgehog (Hh) signaling in various skin cell compartments. The studies used somewhat different models and came to somewhat different conclusions, but if we view the group from a distance, we can come to at least some conclusions.
One answer (beyond the joy of discovery that sustains us all through progressive lowering of NIH paylines), is that in general it is really, really hard to cure cancers once they become clinically apparent, and it might be easier to treat them at their very earliest stage. Such treatment implies we can identify cancers early, and it should be easier to do so if we know where they are lurking before they blossom into detectable lesions (5).
Beyond the simple fact of their high incidence and their ready accessibility for analysis, much about BCCs makes them attractive for study. Thus, these cancers are driven by enhanced Hh signaling due to mutations in genes encoding the signaling machinery; 80%–90% of cases are caused by inactivation of an inhibitor of the pathway, the PTCH1 gene, and 10%–20% of cases are caused by activating mutations of the Hh receptor SMO (1). Also, much is known about the stem cells of the skin, and tools enabling genetic alteration of various cell compartments are available. In addition, a number of murine models have been developed to study BCC carcinogenesis, all relying on activation of Hh signaling.
To control Hh signaling at will, Grachtchouk et al. engineered mice expressing the mutant GLI2ΔN allele, GLI2 being the transcription factor at the “business” end of the Hh signaling pathway. This mutant is a version that is a particularly strong transcriptional activator. The power of the technique used by this group was that it allowed tissue- and temporal-specific expression of GLI2ΔN, and by varying the amount of doxycycline given to the mouse, they also could control the degree of GLI2ΔN expression.
The group first focused their attention on the area containing the best-studied keratinocyte skin stem cells — the follicular bulge, which lies below the sebaceous glands. When they activated GLI2ΔN expression in keratin 15+ (K15+) cells of the bulge, the mice developed microscopic tumors with the histology and protein expression patterns of BCCs. These tumors developed on all body sites biopsied and became grossly evident on the back skin within three weeks. Grachtchouk et al. then focused in on the lowermost part of the bulge — the secondary hair germ — and found the same results when they activated Gli2 expression only in this site using Lgr5-driven Cre. Activating GLI2ΔN expression more broadly in all basal cell compartments produced hyperplasia within a few days in the follicle, the sebaceous glands, and the interfollicular epidermis, indicating that all of these are capable of responding to GLI2ΔN-stimulated transcription. Interestingly, the main part of the bulge — above the secondary hair germ — expressed GLI2ΔN but did not undergo hyperplasia, perhaps because of increased apoptosis at this site; and the follicular isthmus, the part just above the bulge, neither upregulated GLI2ΔN expression nor developed hyperplasia. Taken together, these data suggest that the BCCs seen with three weeks of GLI2ΔN expression in the K15-CrePR1 mice arose from the secondary hair germ, and that the main part of the bulge may be protected from Hh-driven hyperplasia at least in part by an apoptotic response. Finally, they assessed the results of administering lower doses of the tetracycline derivative doxycycline to produce lower expression of GLI2ΔN in basal cells and saw only hyperplasia and tumors appearing less malignant than BCCs, similar to what is seen when the apparently weaker Hh activating mutant Smo allele is expressed and consonant with their previous studies indicating that lower-level activation of Hh signaling produces more benign follicular tumors, whereas higher-level Hh activation produces tumors that are more BCC-like (6).
Three other groups have published studies (7–9) using mutant alleles to activate Hh signaling in the study of BCC. Hence, in total, investigators have assessed the effects of activating Smo, Gli1, or Gli2 and of deleting the pathway inhibitor Ptch1 (Figure 1). Of interest, two groups (8, 9) wounded mouse skin and found more vigorous microscopic tumor development from the newly formed epidermal covering. Various mechanisms can be invoked to explain this stimulation of tumorigenesis by wounding, and the idea of wounding causing the appearance of tumors is well founded in both clinical anecdotes as well as animal models (10). One potential mechanism on which both groups focus is the movement of cells out of the follicle, as occurs normally during skin wound repair. This suggests that the follicle, in particular the bulge, may be relatively resistant to tumorigenesis in these models (perhaps via increased apoptosis) but that once the cell leaves the follicle this inhibition dissipates. Alternatively, wound-associated inflammation could help stimulate tumorigenesis, but at least some other forms of inflammation (e.g., more superficial than full skin thickness wounding, such as hair plucking) appeared not to be stimulatory, suggesting that inflammation per se may not be the mechanism by which wounding stimulates tumorigenesis in their models. Consistent with this idea of movement of cells changing their tumorigenic potential, Grachtchouk et al. found that induction of the hair follicle growth phase (anagen) greatly enhanced BCC formation in parallel with the migration of tissue stem cells out of the bulge compartment. Finally, our group (4) assessed the cell of origin of tumors in the Ptch1+/– mouse, which unperturbed forms minimal tumors but when stressed by ionizing or ultraviolet radiation forms microscopic and then visible BCCs. Using K15-Cre and K14-Cre to conditionally remove specific DNA sequences from different cell populations, we found that BCCs in Ptch1+/– mice develop primarily from K15+ follicular stem cells as judged both directly, by fate mapping using an lsl-YFP allele that is expressed in cells in which Cre is activated and in their progeny, and indirectly, by stimulation of BCC carcinogenesis when p53 is deleted specifically from K15+ keratinocytes. In addition, we found that the interfollicular epidermis in our Ptch1+/– mouse does not express immunohistochemically detectable Smo protein, thus providing an explanation as to why the presumed radiation-induced loss of the wild-type Ptch1 allele failed to induce tumors at this site. By contrast, when p53 was deleted from the interfollicular epidermis, Smo was expressed, and some BCCs developed at this site.
The cell of origin of BCCs differs in mouse models according to the allele producing Hedgehog signaling activation, but at least some tumors arise from the hair follicle bulge stem cells. BCC here refers to an array of tumors of greater or lesser degrees of differentiation and growth potential. IR, ionizing radiation.
First, for sure BCCs, at least in mice, arise from keratinocytes of the skin. Second, high-level Hh signaling without any additional imposed mutations can produce murine tumors, of at least microscopic size, that resemble human BCCs. Third, the details of the site of the cell of origin of murine BCCs can differ depending on the model used, and there is even some hint that different histologic patterns of BCCs might arise from different cells of origin (3). The models used all are artificial — for example, although ionizing radiation can predispose to human BCC carcinogenesis, epidemiology and the presence of signature mutations suggest that ultraviolet radiation plays a bigger role than does ionizing radiation in human BCCs, but it is uncertain whether ultraviolet radiation penetrates human skin as deeply as the site of the follicular bulge. The situation is further complicated by the movement of these cell populations — how best to define the cell of origin when tumors may not appear until the mutant cells have taken up residence in a site well removed from that in which it sustained its oncogenic mutation and perhaps had a different phenotype. Analogously, multipotent cerebellar stem cells that sustain an Hh activating mutation appear quite normal until they commit to a more limited state of differentiation (11, 12), and the cited work suggests that the bulge stem cell might have to “commit” to a more limited differentiation potential accompanying its migration to the secondary hair germ before it can develop into a BCC. And why do the keratinocytes expressing high-level Hh signaling become BCCs, whereas it appears that it is the cells expressing low levels of aberrant signaling that escape intrinsic tumor suppressor mechanisms and develop into cancers of the lung and breast (13–15)?
The true value of these five papers is evident in the fact that they raise more questions than they answer . . . or, at least they suggest more avenues for further investigation.
This work was supported in part by CA115992.
Address correspondence to: Ervin Epstein, Children’s Hospital of Oakland Research Institute, 5700 MLK Jr Way, Oakland, California 94609, USA. Phone: 510.502.6144; Fax: 510.597.7096; E-mail: eepstein@chori.org.
Conflict of interest: Ervin H. Epstein Jr. has been a paid consultant for Genentech, Novartis, and BMS regarding their Hh inhibitor projects and is the principal investigator of an ongoing investigator-initiated trial of the anti-BCC efficacy of the Genentech Hh inhibitor GDC-0449 in patients with Gorlin syndrome.
Reference information: J Clin Invest. 2011;121(5):1681–1683. doi:10.1172/JCI57700.
See the related article at Basal cell carcinomas in mice arise from hair follicle stem cells and multiple epithelial progenitor populations.