Sabine Eming / Maria Leptin - C 7

The role of TOR pathway components in skin function

A decline in skin regenerative capacity, increased skin fragility with disturbed barrier function and impaired wound healing are leading causes of increasing morbidity and mortality in the elderly. Understanding the underlying molecular and cellular mechanisms is important for the development of strategies to intervene in aging- and disease-associated loss of skin function.

The aim of this project is to understand the role of the nutrition-sensing pathway, and specifically of TOR signalling, in skin homeostasis, regeneration and aging.

Introduction

Rapamycin inhibits cell growth and is used in the clinic for treating diseases such as cancer. The molecular target of rapamycin, the Ser/Thr kinase TOR, senses and integrates a variety of environmental cues from nutrients and growth factors, acting as a nexus point for cellular signals to control growth and metabolism.

TOR interacts with several proteins to form two distinct complexes named TOR complex 1 (TORC1) and 2 (TORC2). Altering the activity of components of the TOR pathway either genetically or by pharmaceutical intervention can extend healthy lifespan in laboratory animals. It is not clear to what extent this is due to organ-specific or systemic effects, and indeed in some organs reduction of TOR signalling can be detrimental, and the specific roles of TOR at the cellular level are just beginning to emerge.

The effect on lifespan is conserved in evolution and can be studied in many laboratory model organisms. Here we make use of the advantages of two model organisms, Drosophila and mouse, to explore the function of TOR pathway components in skin homeostasis and regenerative capacity.

TOR signalling is involved in wound healing in Drosophila larvae

To test the roles of TOR in epidermal regeneration in flies we established a method for long-term immobilisation of Drosophila larvae and laser-mediated epithelial injury. We imaged wound healing in vivo over extended periods with high spatial and temporal resolution, and used the wide range of genetic tools available in Drosophila as well as pharmacological approaches to perturb TOR signalling.

To assay the role of TOR in wound healing, we first fed rapamycin to larvae. The animals carry markers that allow us to follow the wound healing process, such as fluorescently tagged markers for cell membranes, actin and other cellular components. To avoid general developmental effects of rapamycin treatment, larvae were initially raised on normal food and then given food supplemented with rapamycin for 22h prior to wounding.The treatment with rapamycin (1 to 20 µM) did not interfere with normal growth or development of the larvae. However, wound closure was significantly delayed. Whereas wounds had closed by 2 h in control animals, most wounds in animals treated with rapamycin were still open after 3 h. Thus, like in mammalian skin, wound healing in the Drosophila larval epidermis is also sensitive to rapamycin, pointing to a possible involvement of TOR signalling in epidermal regeneration in Drosophila.

TORC1 signalling regulates epidermal integrity and morphology in Drosophila

Rapamycin inhibits TOR signalling through binding and specific allosteric inhibition of TORC1. To test which of the TOR complexes was necessary for proper wound healing, we used RNA interference constructs against Raptor and Rictor, the specific core components of TORC1 and TORC2, respectively, which we expressed in the larval epidermis.

Knockdown of TORC2 had no effects on cell shape or morphology and wound healing occurred normally, showing that only the rapamycin-sensitive TORC1 is required during wound healing. Reduction of TORC1 led to serious epidermal defects and to larval or pupal lethality, consistent with an essential role of TORC1 in epidermal morphology, integrity and wound healing in Drosophila larvae.

Tissue specific activation of S6Kinase suppresses rapamycin-mediated delays of wound healing

TORC1 has two major downstream effectors, both involved in protein synthesis, S6 kinase (S6K) and its antagonist 4E-BP. To test which of these effectors are needed for wound healing we experimentally raised and lowered their levels, either alone, or in rapamycin-treated larvae.

Neither loss nor constitutive activity of 4E-BP affected wound healing , whereas reduction of S6K in the epidermis resulted in delayed wound healing. If rapamycin acts through S6K, then activation of S6K should at least partially rescue the rapamycin effect.

To test this we overexpressed a constitutively active version of S6K (S6KSTDETE) in the epidermis of rapamycin treated larvae. This completely suppressed the rapamycin-induced delay in wound healing (Figure 1). Thus, S6K activation downstream of TORC1 is sufficient to enable efficient wound healing, suggesting that TOR acts through S6K.

Both mTORC1 and mTORC2 are involved in epidermal morphogenesis

To distinguish the functions of mTORC1 and mTORC2 in epidermal morphogenesis, we generated mice with keratinocyte specific deletion of raptor or rictor, creating RaptorEKO mice which lack epidermal mTORC1 function, and RictorEKO mice depleted of epidermal mTORC2 function. We found that epidermal deletion of mTORC1 caused a similar phenotype as that of mTOREKO mice, characterized by loss of stratified epidermal layers, lack of epidermal barrier function and thus neonatal lethality, showing that the main function of TOR in epidermal morphogenesis is mediated by the mTORC1 complex (Figure 2).

In contrast, epidermal deletion of mTORC2 did not result in neonatal lethality. The epidermis in mTORC2 deficient mice was characterized by epidermal atrophy and disturbed barrier function.

Perspectives

We have shown that TOR signalling in Drosophila and in the mouse is critical for epidermal morphogenesis and regeneration. Both mTORC1 and mTORC2 mediate important functions in epidermal development and homeostasis.

Our findings in Drosophila indicate that TORC1 acts through S6K in these processes. We are currently investigating the underlying molecular and cellular mechanisms that mediate distinct functions of mTOR complexes on a cellular and tissue level in the epidermis. Findings in Drosophila will help to guide and focus the analysis on important cellular processes in mouse and human disease.

Selected publications

Kakanj P, Moussian B, Grönke S, Bustos V, Eming SA, Partridge L, Leptin M. Insulin and TOR signal in parallel through FOXO and S6K to promote epithelial wound healing. Nat Commun, 2016 Oct 7;7:12972. doi: 10.1038/ncomms12972.

Ding X, Bloch W, Iden S, Rüegg MA, Hall MN, Leptin M, Partridge L, Eming SA. mTORC1 and mTORC2 regulate skin morphogenesis and epidermal barrier formation. Nat Commun, in press

 


Prof. Dr. med. Sabine Eming

Dept. of Dermatology

Prof. Dr. med. Sabine Eming

Principal Investigator C 7

sabine.eming@uni-koeln.de

Work +49 221 478 3196

Fax (Work) +49 221 478 5949

Dept. of Dermatology and Venerology
Kerpener Str. 62
50937 Cologne

http://www.eming.uni-koeln.de/Sabine_Eming_Research_Group_-_Uni_Koln/Sabine_Eming_-_Uni_Koln.html

Publications - Sabine Eming

Link to PubMed


Prof. Dr. rer. nat. Maria Leptin

Institute for Genetics

Prof. Dr. rer. nat. Maria Leptin

Co-Principal Investigator C 7

mleptin@uni-koeln.de

Work +49 221 470 3401

Institute for Genetics
Zülpicher Str. 47
50674 Cologne

http://www.genetik.uni-koeln.de/groups/Leptin/lep_lab.htm

Publications - Maria Leptin

Link to PubMed

Group Members

Xiaolei Ding (PostDoc)
Parisa Kakanj (PostDoc)

Figure 1

Fig. 1. Time-lapse images of wound healing in rapamycin-treated larvae with or without constitutively active S6K. Green: Src-GFP; red: DsRed2-Nuc.

Figure 2

Fig. 2. Epidermis-specific Raptor (A) or Rictor (B) deletion impairs skin barrier function.