Haiyan Chen1,2, Xusheng Wang1,3,4, Yu Chen1, Jimin Han1,3, Deqiang Kong1,3, Meizhong Zhu5, Xiaobing Fu6, Yaojiong Wu1,2. 1. Tsinghua-Berkeley Shenzhen Institute (TBSI), Tsinghua University, Guangdong, China. 2. State Key Laboratory of Chemical Oncogenomics, and the Shenzhen Key Laboratory of Health Sciences and Technology, the Graduate School at Shenzhen, Tsinghua University, Shenzhen, Guangdong, China. 3. School of Life Sciences, Tsinghua University, Beijing, China. 4. School of Pharmaceutical Sciences (Shenzhen), Sun Yat-sen University, Guangzhou, China. 5. Shenzhen Second People's Hospital (The First Hospital Affiliated to Shenzhen University), Guangdong China. 6. Wound Healing and Cell Biology Laboratory, Institute of Basic Medical Science, Chinese PLA General Hospital, Beijing, China; Stem Cell and Tissue Regeneration Laboratory, The First Affiliated Hospital, General Hospital of PLA, Beijing, China.
Accumulating evidence indicates that certain cancers such as leukemia arise from somatic stem cells with gene mutations 1, 2. Lgr5 marks hair follicle stem cells (HFSCs) located in the lower bulge and the secondary hair germ of the telogen hair follicle (HF) 3. Lgr5+ cells substantially contribute to the cycling portion of anagen HFs and take part in the reepithelialization in skin wound healing 3, 4. In addition, HFSCs with misactivated Hedgehog (Hh) signaling recruited to the epidermis by wounding contribute to basal cell carcinoma (BCC)-like lesions 5, 6. Moreover, progeny of Lgr5+ HFSCs contribute to papillomavirus-induced SCC, the second most common skin cancer 7. Pten (phosphatase and tensin homolog deleted on chromosome ten), is a tumor suppressor gene that frequently mutated in hereditary cancer syndromes such as Cowden disease, which is featured with papillomatosis in cutaneous tissues and hyperkeratosis in the acral region of the skin 8, 9, and many other cancers 10. Additionally, mice with keratinocyte-specific Pten deficiency show epidermal hyperplasia and spontaneous tumor formation 11. However, the impact of Pten mutation in HFSCs, such as in Lgr5+ HFSCs, on cutaneous squamous cell carcinoma (SCC) formation is unclear. β-catenin has also shown to be involved in the development of SCC. SCC exhibit a preferential nuclear location of β-catenin, and inhibition of β-catenin signaling significantly attenuates the growth of SCC cells 12-14. However, whether the activity of β‐catenin signaling in HFSCs affecting SCC formation is unclear. In addition, it is also desired to uncover the interaction between Pten/Akt and β‐catenin signaling in SCC formation. Furthermore, previous studies show that TNF-/- mice are resistant to DMBA/TPA-induced skin SCC 15, suggestive of the involvement of TNF in SCC development. In this study, we found that mice with Pten knock out in Lgr5+ HFSCs showed increased incidences of skin papilloma and SCC upon DMBA/TPA induction, while double loss of Pten /CTNNB1(β‐catenin gene) or Pten/TNF in Lgr5+ HFSCs greatly diminished the tumorigenesis. Thus our data indicate that Pten loss in HFSCs greatly promotes the formation of SCCs, and β‐catenin and TNF are critically involved.
Methods
Mice
C57BL/B6 mice (6-week-old, female) were purchased from Guangdong Medical Laboratory Animal Center, Guangzhou, China. Lgr5-GFP-Cre-ERT2 (Lgr5-CreER) mice were obtained from Jackson Laboratory (Stock No.: 008875). The mice were crossed with Ptenmice (a gift from Dr. Hong Wu at the University of California, Los Angeles) to obtain Lgr5-CreER;Ptenmice, whose identify were verified (Figure S1A-B). Lgr5-CreER; Ptenmice were crossed with β-catenin (B6.129-Ctnnb1tm2Kem/KnwJ, provided by Dr. Zhenge Luo, Institute of Neuroscience, CAS) to obtain Lgr5-CreER; Ptenmice. TNF knockout mice (TNFα-KO, B6.129S6-Tnftm1Gkl/J) were obtained from Jackson Laboratory. Lgr5-CreER; Ptenmice were crossed with TNF knockout mice to obtain Lgr5-CreER; Pten; TNF KO (knock out) mice. Lgr5-CreER; Ptenmice were crossed with Rosa-mTmG mice (Jackson Laboratory, Stock No.: 007576) to get Lgr5-CreER; Ptenmice. To knock out Pten, β-catenin, in Lgr5 cells, Lgr5-CreER; Ptenmice, Lgr5-CreER; Ptenmice, Lgr5-CreER; Pten; TNF KO (knock out) mice, Lgr5-CreER; Ptenmice aged 3 weeks received an intraperitoneal injection of 100 μL of tamoxifen (TAM, Sigma Aldrich) in corn oil at a concentration of 10 mg/mL for three times. In addition, we used littermate mice for control in all genetic mice model involved experiments. Mice were randomly divided into groups using a random-number table. The animals were maintained in a temperature-controlled environment (20 ± 1 °C) with free access to food and water. All procedures were performed with the approval of Animal Ethics Committee of Shenzhen Center for Disease Control and Prevention (CDC).
Tumor induction in mice
Skin SCC in mice was induced as previously described 16, 17. Briefly, 25 μg DMBA (Sigma Aldrich) in 200 μL acetone was applied to the dorsal skin after shaving. After 2 weeks, TPA (10 nmol) in 200 μL was applied to the same area twice weekly for up to 30 weeks. Skin specimens were collected 4 weeks and 9 weeks after DMBA treatment, and when papilloma and SCC formed. The number of tumors per mouse was counted each week as palpable mass >1 mm in size. Tumor volume was also estimated and recorded periodically 16, 18, 19.
Immunofluorescence (IF) staining
Freshly obtained skin samples from mice back with hair removal were fixed in 4% paraformaldehyde for 8 h. Then were taken off water in 10%, 20% and 30% sucrose gradient for 8 h and embedded in Tissue Freezing Medium (SAKURA Tissue-Tek® OCT Compound). Frozen tissue sections of the skin were incubated with different primary antibodies at 4 ℃ overnight, which were anti-p-Akt (Ser473, 1:200, GTX28932,GeneTex), anti-Ki67 (1:100, 20Raj1, eBioscience), and anti-p-β-Catenin (Ser552, 1:100, 5651S, Cell Signaling Technology), anti-Pten (1:100, 138G6,Cell Signaling Technology), anti-TNF (1:100, 1F3F3D4, eBioscience), anti-CD11b (1:50, 101201, Biolegend), anti-GFP (1:100, 598, MBL), anti-Keratin 14 (1:100, 906004, Biolegend), anti-MHC-II (1:100, 14-4-4S, eBioscience). Followed by detection with a TRITC or FITC-conjugated secondary antibody. Nuclei were stained with 4, 6-diamidino-2-phenylin-dole (DAPI). After mounting, samples were visualized under confocal microscope (FV1000; Olympus, Tokyo, Japan) 20.
Western blotting
Freshly obtained skin samples from mice with hair removal were prepared in a lysis buffer containing 1% Triton X-100, 1% deoxycholic acid, 2 mM CaCl2 and protease inhibitors (10 μg/mL leupeptin, 10 μg/mL aprotinin, 1.8 mg/mL iodoacetamide and 1 mmol/L phenylmethyl sulfonyl fluoride) and quantified with a BCA protein assay kit (Pierce). Equal amounts of total protein were subjected to electrophoresis on 12% Bis-Tris gels, transblotted onto nitrocellulose membranes and probed with different primary antibodies: anti-Pten (1:1000, 138G6, Cell Signaling Technology), anti-p-Akt (Ser473, 1:1500, GTX28932, GeneTex), anti-p-β-catenin antibody (Ser552, 1:1000, 5651S, Cell Signaling Technology), anti-p-Gsk-3β (Ser9) antibody (1:1000, 5558S, Cell Signaling Technology), and anti-p-β-catenin antibody (Ser675, 1:1000, 4176S, Cell Signaling Technology), anti-Akt antibody (1:1000, GTX121937, GeneTex), anti-β-catenin antibody (1:1000, 8480, Cell Signaling Technology), respectively, followed by a peroxidase-conjugated secondary antibody (KPL). Immunoreactive bands were detected using ECL kit according to the manufacturer's instructions. Subsequent reprobing using anti-GAPDH was performed for internal loading control.
Isolation and culture of epidermal stem cells
Neonatal mouse dorsal skin was harvested from Ptenmice 1~3 days after birth. The tissue was cut into 2~3 mm2 pieces, washed 3 times in HBSS, and digested with 0.3% Dispase II (sigma) for 90 min at 37 °C. The epidermis was manually removed from the tissue. Epithelial stem cells were isolated based on their high adhesive property 21. Briefly, the epithelial layer was cut into slurry and treated with 0.2% collagenase I (Sigma) for 60 min at 37 °C with shaking and filtered through a 40 µm cell strainer. The cells were seeded in tissue culture dishes coated with 50 µg/mL collagen I (Sigma) and incubated in CnT-07 PCT Epidermal Keratinocyte Medium (CnT-07; CELLnTEC Advanced Cell Systems, Bern, Switzerland) with supplements provided by the manufacture for 60 min. The non-adherent cells were removed and the adherent cells were maintained. When reaching 80% confluence, the culture was passaged after digestion with accutase (Sigma) 4.
Transfection
Epidermal stem cells were seeded on 6 wells culture dishes, and when cells reached 40% confluence, the medium was exchanged with 1 mL new medium containing 40 µL 1.0×1010 pfu GFP-Cre-adenovirus and incubated for 24 h. Then the medium was changed to growth medium, and cells were collected after incubation for 24, 48 and 72 h.
Histological analysis
Freshly obtained skin samples from mice back with hair removal were fixed in 10% formalin or other fixatives for 12-24 h at room temperature. After dehydration, tissues were embedded in paraffin. Tissue sections were rehydrated with 100% ethanol, 95% ethanol, 75% ethanol, and deionized H2O, 3 min each. Then use hematoxylin to stain nuclear and eosin to stain cytoplasm and visualized with a Leica microscope. The mean width of HFs was measured, and 100 HFs per mice were measured per mouse.
Statistical analysis
Results are expressed as mean±s.e.m. unless stated otherwise. Statistical comparisons between two groups were evaluated by Student's t-test. A probability (P) value <0.05 was considered to indicate statistical significance.
Results
Pten loss in Lgr5+ stem cells induces hair follicle hyperplasia
A previous study showed that Pten deletion in Lgr5+ HFSCs in 7~8 weeks old mice did not induce the hyperproliferation of HFSCs 22. Here we examined the influence of Pten loss on Lgr5+ HFSCs in 3 weeks old Lgr5-CreER;Ptenmice. The mice were treated with tamoxifen to induce Pten loss in Lgr5+ cells (Lgr5-Pten). At the 12th day after intraperitoneal injection of tamoxifen, immunofluorescence staining of the skin tissue showed that Pten level was extensively reduced in Lgr5+ HFSCs, resulting in increased levels of p-Akt (Figure S2A-B). Notably, 20 days after tamoxifen administration, the mice showed significantly enlarged HF containing more cells (hyperplasia), compared to Lgr5-CreER;Ptenmice without tamoxifen treatment (Lgr5-Pten) (Figure 1A, C). The enlarged HF shortened when proceeding into the telogen phase but still much wider than in the Lgr5-Ptenmice, as examined 40 days (8-9 weeks of age) after Pten deletion (Figure 1B, D). Taken together, the data indicate that Pten loss in Lgr5+ HFSCs induce HF hyperplasia in 3 weeks old mice.
Figure 1
Lgr5-CreER;Pten mice aged 3 weeks were treated with or without tamoxifen (TAM), and the skin tissues were harvested for histological analysis at different time points. (A) 20 days after TAM treatment, Lgr5-Ptenmice showed enlargement of the HF with increased cell number (hyperplasia). (B) 40 days after TAM treatment, in Lgr5-Ptenmice the HF entered telogen phase, but they were still larger than telogen HFs in Lgr5-Pten mice.100 hair follicles per mouse were measured, 10 mice were analyzed. Scale bars, 100 μm. Epi, Epidermis; Derm, Dermis; HF, hair follicle. Data are expressed as the mean±s.e.m. ***P< 0.005.
Pten loss in Lgr5+ stem cells promotes papilloma formation
To gain insight into the role of Pten loss in Lgr5+ HFSCs in the development of SCCs, we employed DMBA/TPASCCmouse model 16, 17. Six weeks after Pten deletion in Lgr5-Ptenmice, DMBA was applied to the dorsal skin of mice after hair shaving, followed by TPA treatment (Figure 2A). Lgr5-Pten received equal treatment of DMBA/TPA were used as control. Four weeks after the DMBA treatment, the dorsal skin of mice showed hyperplasia in both Lgr5-Ptenmice and Lgr5-Ptenmice, whereas the epidermal layer of the skin was much thicker in Lgr5-Ptenmice (Figure 2B). Nine weeks after DMBA treatment, significant hyperplasia was observed in both groups, but the lesion was more severe in Lgr5-Ptenmice (Figure 2B). Importantly, skin papillomata were observed in Lgr5-Ptenmice early in the 5th week after DMBA treatment, whereas in Lgr5-Ptenmice papillomata were found 8 weeks after DMBA treatment. In addition, the incidence of mice developing papillomata was higher in Lgr5-Ptenmice (100%, n=8) than in Lgr5-Ptenmice (85.7%, n=7) 25 weeks after TPA treatment (Figure 2C, D). Together, these data indicate that Pten knockout in Lgr5+ HFSCs greatly promotes skin papilloma formation.
Figure 2
A schematic diagram of the two-step DMBA/TPA carcinogenesis assay. 3 weeks old Lgr5-CreER;Pten mice were treated with (Lgr5-Pten, n=8) or without (Lgr5-Pten, n=7) tamoxifen (TAM), followed by treatments with DMBA/TPA. (B) Skin tissues were harvested at different time points for histological analysis. HE staining of tissue sections showed changes of the skin. (C) The incidence of mice with skin papillomata. (D) The average number of papillomata per mouse in of the two groups. Scale bars, 100 μm. W, weeks.
Pten loss in Lgr5+ HFSCs promotes SCC development
We next examined whether Pten knockout in Lgr5+ HFSCs promoted skin SCC development. We found that some papillomata in Lgr5-Ptenmice developed into invasive lesions 18 weeks after DMBA treatment, where proliferating cells in the epidermis- and follicle-like structures invaded into the space between them in histology, exhibiting the feature of SCC; by contrast, similar lesions were found in much later in Lgr5-Ptenmice (26 weeks after DMBA treatment) (Figure 3A-B). 26 weeks after DMBA treatment, 62.5% of Lgr5-Ptenmice developed SCC lesions compared to 14.3% in Lgr5-Ptenmice (Figure 3 A). These data indicate that Pten deletion in Lgr5+ HFSCs contributes to the development of SCC.
Figure 3
Lgr5-Pten mice and Lgr5-Pten mice were subjected to DMBA/TPA treatment, and the incidence of SCC in mice were examined. (B) Tumor tissues were harvested at different time points and subjected to histological analysis. HE staining of tissue sections showed invasion lesions. Lgr5-Pten mice, n=8; Lgr5-Ptenmice, n=7. Scale bars, 100 μm.
Lineage tracing of Lgr5+ HFSCs and their progeny in tumor development
To further examine the contribution of Lgr5+ HFSCs with Pten loss and their progeny to skin tumor development, we used Lgr5-CreER; Pten (Lgr5-Pten) and Lgr5-CreER;Rosa-mTmG (Lgr5-mTmG) mice (control). The mice were treated with DMBA/TPA as indicated in Figure 2A. The result showed that an increased amount of cells were progenies of Lgr5+ stem cells (membrane tdTomato-/membrane GFP+, mT-/mG+) in hyperplastic HFs and epidermis in Lgr5-Ptenmice, whereas in Lgr5-mTmG mice the HF and epidermis did not show hyperplasia and contained fewer mT-/mG+ cells (Figure 4A, B). With progression of the disease, we found mT-/mG+ cells in papillomata and in SCC, which formed colonies, in Lgr5-Ptenmice, but not in Lgr5-mTmG mice (Figure 4C, D). To verify the contribution of Lgr5+ cells (with Pten loss) in papilloma and SCC, we performed IF staining of tissue sections of these tumors derived from Lgr5-Ptenmice and Lgr5-Ptenmice for the expression of Lgr5, and we did not detect the presence of Lgr5-expressing cells (Figure S3). These data suggest that the progeny of Lgr5+ HFSCs with Pten loss contribute to skin papilloma and SCC.
Figure 4
Lineage tracing of Lgr5
Lgr5-Pten mice (n=8) and Lgr5-mTmG mice (n=7) received treatment of DMBA/TPA. Lgr5-Pten mice developed HF and epidermal hyperplasia, which contained increased amount of mT-/mG+ cells derived from Lgr5+ HFSCs. With progression of the disease, mT-/mG+ cells were found in papillomata and in SCC in Lgr5-Pten mice, but not in Lgr5-mTmG mice. SCC, squamous cell carcinoma. Scale bars, 100 μm.
β-catenin effects at the downstream of Pten/Akt signaling
To elucidate the molecular mechanisms underlying the role of Pten loss in Lgr5+ HFSCs in SCC development, we performed in vitro and in vivo experiments. Immunostaining of the skin tissue of Lgr5-Ptenmice showed elevated expression levels of p-β-catenin (Ser552) in the HF and epithelial cells (Figure 5A), indicating increased β-catenin signaling after Pten loss. To gain more insight into the crosstalk between Pten/Akt and β-catenin in epidermal stem cells (Epi-SCs), Epi-SCs were isolated from Ptenmice and the cells were treated with Ad-Cre virus (Figure S4) to induce the knockout of Pten. Western blot showed that the expression of Pten decreased markedly at the 48 h and 72 h after Ad-Cre virus treatment, meanwhile the level of p-Akt increased, but the level of total Akt unchanged. In addition, increased levels of p-Gsk-3β (Ser9) and p-β-catenin (Ser552), but unchanged levels of p-β-catenin (Ser675) were also detected (Figure 5B, C). Consistently, elevated level of p-Akt and p-β-catenin (Ser552) were detected in papillomata (Figure 5D, E). Taken together, these data suggest Pten loss activates β-catenin possibly through the Akt mediated phosphorylation of β-catenin (Ser552). We detected more Ki67-expressing cells in papillomata of mice with Pten loss in Lgr5+ cells (Figure S5). To verify the role of β-catenin in Pten loss induced SCC formation, we generated Lgr5-CreER;Ptenmice, whose Pten and β-catenin were deficient in Lgr5+ cells upon induction with tamoxifen (Lgr5-Ptenmice); we found that less severe HF and epidermal hyperplasia in the mice compared to Lgr5-Ptenmice (Figure 6A, C). Moreover, the incidence of tumor formation and the average number of papillomata per mouse also decreased markedly in Lgr5-Ptenmice (Figure 6B, D, E). These data suggest that the loss of Pten in Lgr5+ HFSCs is likely through β-catenin signaling to promote SCC development.
Figure 5
β-catenin activity after 15 days after injection of tamoxifen for three times, marked p-β-catenin (Ser552) was detected in Lgr5+ HFSCs in Lgr5-Ptenmice. (B) Western blot analysis showed that Pten expression decreased in cultured epidermal stem cells derived from Pten mice, 48 and 72 h after infection with Ad-Cre viruses. There were no obvious changes in total Akt, total β-catenin, and p-β-catenin (Ser675), but significantly increased levels of p-β-catenin (Ser552), p-Akt, p-Gsk-3β (Ser9). Data were representative of 3~5 independent experiments. (C) The bands were subjected to densitometry analysis and normalized to GAPDH, *P <0.05; **P < 0.01. (D, E) Representative images of immunofluorescence analysis showed high levels of p-β-catenin (Ser552) and p-Akt in papillomata in Lgr5-Pten mice and Lgr5-Ptenmice. Scale bars, 100 μm.
Figure 6
The effect of β-catenin in 40 days after injection tamoxifen for three times, histological analysis (HE staining) of the dorsal skin (in telogen phase) showed less severe HF hyperplasia in Lgr5-Pten mice compared to Lgr5-Pten mice. (B)
Lgr5-Ptenmice developed fewer skin papillomata than Lgr5-Ptenmice. Images were taken 5 weeks and 8 weeks after DMBA/TPA treatment. (C) Histological analysis of the dorsal skins of Lgr5-Pten mice and Lgr5-Pten mice 4 and 9 weeks after DMBA/TPA treatment, respectively. (D) The incidence of papilloma formation in Lgr5-Pten mice and Lgr5-Pten mice. (E) The average number of papillomata in Lgr5-Ptenmice (n=8) and Lgr5-Ptenmice (n=9). Scale bars, 100 μm. W, weeks.
TNF plays a crucial role in Pten loss induced tumor formation
TNF is a potent proinflammatory cytokine 23, 24. Previous studies have provided evidence that TNF is required for carcinogenesis 15, 25. We found that TNF was abundantly expressed in skin papillomata in immunostaining (Figure 7A), largely in the cells in the stroma, co-localizing to CD11b+ (Figure 7A) and MHC-II+ (Figure S6) expressing cells, probably macrophages. To evaluate the role of the TNF in Lgr5+ stem cells with Pten loss induced SCC development, Lgr5-CreER;Ptenmice were generated and subjected to skin tumor induction using the DMBA/TPA protocol. The results showed that less severe HF hyperplasia in Lgr5-CreER;Ptenmice treated with tamoxifen (Lgr5-Pten) compared to Lgr5-Ptenmice (Figure 7B). After DMBA/TPA treatment, Lgr5-Ptenmice displayed more severe epidermal hyperplasia compared to TNFmice (Figure 7C). Consistently, reduced incidence of papillomata was found in Lgr5-Ptenmice than in Lgr5-Ptenmice (Figure 2C, Figure 7D-E). Moreover, the average number of papillomata per mouse in Lgr5-Ptenmice was much lower compared to that in Lgr5-Ptenmice (Figure 2D, Figure 7F), and TNFmice did not develop papilloma when receiving the same DMBA /TPA treatment (Figure 7E-F). These data indicate that TNF has a crucial role in Lgr5+ HFSCs with Pten loss induced papilloma formation.
Figure 7
TNF is necessary for TNF expression was detected in papillomata and was largely present in CD11b+ cells. (B) 40 days after injection tamoxifen for three times, histological analysis (HE staining) of the dorsal skin of Lgr5-Ptenmice and Lgr5-Ptenmice showed HF hyperplasia (telogen phase). (C) 4 and 9 weeks after DMBA/TPA treatment, epidermal hyperplasia in the dorsal skin of Lgr5-Pten mice was more obvious than in TNFmice. (D) Representative images showing papillomata in Lgr5-Pten mice 5 weeks and 8 weeks after DMBA/TPA treatment. (E) The incidence of skin tumor development in TNF mice and in Lgr5-Pten mice. (E) The average number of papillomata per mouse in TNF mice (n=8) and in Lgr5-Ptenmice (n=8). Scale bars, 100 μm. W, weeks.
Discussion
Lgr5-expressing cells have been found in many tumors, such as colon cancer 26, 27, papillary thyroid cancer 28, breast cancer 29, and gastric cancer 30. Recently, Lgr5 has been found to induce epithelial-mesenchymal transition (EMT) in humanhepatocellular carcinoma cells and inhibit their apoptosis, resulting in drug resistance 31. In humanskin SCC, high levels of Lgr5 have been found in immunohistological analysis 32. In the skin of mice, Lgr5+ stem cells in the HF undergo active cyclic proliferation, and contribute to epidermal cells after wounding to the skin 3, 4; but lineage tracing of Lgr5+ cells did not show their direct contribution to skin SCC, nor their progeny 33, 34. White and colleagues found that gain of oncogene Ras or the loss of tumor suppressors p53 or Pten in HFSCs are unable to initiate tumors during the telogen phase of the HF in adult mice, suggesting that the mechanisms that keep HFSCs quiescent are dominant over the oncogenic influences. However, gain of Kras, accompanied with loss of both Pten and p53 was sufficient to induce skin malignancies in quiescent HFSCs. These data support that Pten has a crucial role in maintaining quiescence in the presence of tumorigenic stimuli 22. While it would be interesting to explore the role of Pten loss in skin malignancy development without other tumorigenic stimuli, Pten-only deletion in Keratin 15+ cells during HFSC quiescence did not result in hyperplasia in adult mice 28. However, in this study, we found that Pten deletion in Lgr5+ HFSCs at the telogen/anagen transition of 3 weeks old mice induced hyperplasia in HFs, and the mice showed more severe hyperplasia in the epidermis, larger number of papillomata and increased incidence of SCC. These data support that Pten deletion alone in the activated HFSCs is sufficient to drive these stem cell into hyperplasia. Our data further support that Pten loss induced SCC development is dependent on the activation of HFSCs. Lgr5+ HFSCs are the first activated stem cell population in response to anagen-initiating signals, whereas keratin 15+ HFSCs remain quiescent even in anagen phase 3. This may explain, at least in part, why Pten deletion alone in Lgr5+ HFSCs is sufficient to drive HFs to hyperplasia, whereas a combination of Kras and the loss of both Pten and p53 are needed to derive the Keratin 15+ HFSCs into hyperplasia. However, more concrete studies should be performed to deeply uncover the differential response of stem cells in activation and in quiescence to tumorigenic stimuli.Wnt/β-catenin exhibits complicated effect on both the development of stem cells and cancers 35-38. In the HF, the transit-amplifying matrix compartment appears to be the target for malignant transformation by mutational activation of the Wnt cascade 39. Constitutive activation of β-catenin in HFs induces pilomatricoma-like lesions, where the exterior zone of the tumor is composed of densely packed cells resembling the matrix of HFs 40. Another HF tumor, namely trichofolliculoma, was developed in tamoxifen-inducible β-catenin transgene mice 41. Notably, the most spontaneous pilomatricomas in humans are featured with activating mutations in β-catenin 42. Recent evidence has shown that in many organs, such as the HF, resident adult stem cells can be the initiating cells for cancers 43, 44. In this study, deletion of both Pten and β-catenin in Lgr5+ HFSCs result in reduced HF hyperplasia and SCC development. Together with the in vitro data, our study support that the effect of β-catenin is downstream of Pten/Akt signaling in the initiation and development of SCC. However, more studies with gain and lose function of β-catenin and Pten/Akt signaling in HFSCs are desired, to further explore the crosstalk between Pten/Akt and β-catenin and its role in skin cancer development. In addition, our data suggest that TNF plays an essential role in Pten loss in HFSCs induced hyperplasia and SCC development. However, the relationship between TNF and Pten/Akt signaling in HFSCs activation and SCC development was still largely unknown. Given the evidence of TNF as a key component of HFSCs activation 4, 45, TNF and Pten/Akt signaling pathways possibly exhibit synergistic effect on SCC development via activating and transforming HFSC, respectively.Conclusively, our study provide evidence that Pten loss in activating Lgr5+ HFSCs was sufficient to drive HFs into hyperplasia, and the Pten loss in Lgr5+ HFSCs plays an important role in subsequent SCC formation. Moreover, we found both β-catenin and TNF play essential roles in HFSCs with Pten loss induced hyperplasia and SCC development. Together, these data indicate that Pten loss in HFSCs is a key driver in SCC initiation and development, where active interaction of Pten/Akt signaling with other signals such as β-catenin and TNF are required.Supplementary figures.Click here for additional data file.
Authors: Viljar Jaks; Nick Barker; Maria Kasper; Johan H van Es; Hugo J Snippert; Hans Clevers; Rune Toftgård Journal: Nat Genet Date: 2008-10-12 Impact factor: 38.330
Authors: Chih-Chiang Chen; Lei Wang; Maksim V Plikus; Ting Xin Jiang; Philip J Murray; Raul Ramos; Christian F Guerrero-Juarez; Michael W Hughes; Oscar K Lee; Songtao Shi; Randall B Widelitz; Arthur D Lander; Cheng Ming Chuong Journal: Cell Date: 2015-04-09 Impact factor: 41.582
Authors: A C White; J K Khuu; C Y Dang; J Hu; K V Tran; A Liu; S Gomez; Z Zhang; R Yi; P Scumpia; M Grigorian; W E Lowry Journal: Nat Cell Biol Date: 2013-12-15 Impact factor: 28.824
Authors: M T Fernández-Figueras; C Carrato; X Saenz-Sardà; E Musulén; M J Fuente; L Puig Journal: Arch Dermatol Res Date: 2021-10-13 Impact factor: 3.033
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