mTORC1 feedback to AKT modulates lysosomal biogenesis through MiT/TFE regulation
Kaushal Asrani, … , Michael Skaro, Tamara L. Lotan
Kaushal Asrani, … , Michael Skaro, Tamara L. Lotan
Published December 2, 2019; First published September 17, 2019
Citation Information: J Clin Invest. 2019;129(12):5584-5599. https://doi.org/10.1172/JCI128287.
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Categories: Research Article Metabolism Oncology

mTORC1 feedback to AKT modulates lysosomal biogenesis through MiT/TFE regulation

Abstract

The microphthalmia family of transcription factors (MiT/TFEs) controls lysosomal biogenesis and is negatively regulated by the nutrient sensor mTORC1. However, the mechanisms by which cells with constitutive mTORC1 signaling maintain lysosomal catabolism remain to be elucidated. Using the murine epidermis as a model system, we found that epidermal Tsc1 deletion resulted in a phenotype characterized by wavy hair and curly whiskers, and was associated with increased EGFR and HER2 degradation. Unexpectedly, constitutive mTORC1 activation with Tsc1 loss increased lysosomal content via upregulated expression and activity of MiT/TFEs, whereas genetic deletion of Rheb or Rptor or prolonged pharmacologic mTORC1 inactivation had the reverse effect. This paradoxical increase in lysosomal biogenesis by mTORC1 was mediated by feedback inhibition of AKT, and a resulting suppression of AKT-induced MiT/TFE downregulation. Thus, inhibiting hyperactive AKT signaling in the context of mTORC1 loss-of-function fully restored MiT/TFE expression and activity. These data suggest that signaling feedback loops work to restrain or maintain cellular lysosomal content during chronically inhibited or constitutively active mTORC1 signaling, respectively, and reveal a mechanism by which mTORC1 regulates upstream receptor tyrosine kinase signaling.

Authors

Kaushal Asrani, Sanjana Murali, Brandon Lam, Chan-Hyun Na, Pornima Phatak, Akshay Sood, Harsimar Kaur, Zoya Khan, Michaël Noë, Ravi K. Anchoori, C. Conover Talbot Jr., Barbara Smith, Michael Skaro, Tamara L. Lotan

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Figure 1

Epidermal-specific mTORC1 gain-of-function models have skin defects reminiscent of epidermal EGFR or TGF-α loss.

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Epidermal-specific mTORC1 gain-of-function models have skin defects remi...
(A) Genotyping PCR of genomic tail DNA from WT and Tsc1-cKO mice showing presence of Tsc1fl/fl alleles and Krt14-Cre in Tsc1-cKO mice. (B) Immunoblotting of WT and Tsc1-cKO epidermal and keratinocyte lysates for Tsc1. (C) Tsc1-cKO pups show curly whiskers at birth (top panel) and wavy fur at 4 weeks (middle, bottom panels), indicated by arrows. (D) Tsc1-cKO mice show thickened epidermis on histology (top panel) and increased mTORC1 activity as seen by p-S6 immunofluorescence (bottom panel). Scale bar: 150 μm. (E) Tsc1-cKO mice develop severe dermatitis in the facial region by 6 months. (F) Genotyping PCR of genomic tail DNA from WT and Rheb1 S16H Tg mice showing presence of Rheb1 S16Hfl/fl alleles, Rheb1 S16H excision alleles, and Krt14-Cre in Rheb1 S16H Tg mice. Rheb1 S16H transgenic mice show increased mTORC1 activity as seen by (G) p-S6 immunofluorescence. Scale bar: 150 μm. (H) Rheb1 S16H transgenic mice show presence of wavy fur, similar to Tsc1-cKO mice.