Catherine F. LeGrand

Abstract The long-term expansion of keratinocytes under conditions that avoid xenogeneic components (i.e. animal serum- and feeder cell-free) generally causes diminished proliferation and increased terminal differentiation. Here we present a culture system free of xenogeneic components that retains the self-renewal capacity of primary human keratinocytes. In vivo the extracellular matrix (ECM) of the tissue microenvironment has a major influence on a cell’s fate. We used ECM from human dermal fibroblasts, cultured under macromolecular crowding conditions to facilitate matrix deposition and organisation, in a xenogeneic-free keratinocyte expansion protocol. Phospholipase A 2 decellularisation produced ECM whose components resembled the core matrix composition of natural dermis by proteome analyses. Keratinocytes proliferated rapidly on these matrices, retained their small size, expressed p63, lacked keratin 10 and rarely expressed keratin 16. The colony forming efficiency of these keratinocytes was enhanced over that of keratinocytes grown on collagen I, indicating that dermal fibroblast-derived matrices maintain the in vitro expansion of keratinocytes in a stem-like state. Keratinocyte sheets formed on such matrices were multi-layered with superior strength and stability compared to the single-layered sheets formed on collagen I. Thus, keratinocytes expanded using our xenogeneic-free protocol retained a stem-like state, but when triggered by confluence and calcium concentration, they stratified to produce epidermal sheets with a potential clinical use.

The production of nanofibrous materials for soft tissue repair that resemble extracellular matrices (ECMs) is challenging. Electrospinning uniquely produces scaffolds resembling the ultrastructure of natural ECMs. Herein, electrospinning was used to fabricate Bombyx mori silk fibroin (SF) and SF/halloysite nanotube (HNT) composite scaffolds. Different HNT loadings were examined, but 1 wt% HNTs enhanced scaffold hydrophilicity and water uptake capacity without loss of mechanical strength. The inclusion of 1 wt% HNTs in SF scaffolds also increased the scaffold’s thermal stability without altering the molecular structure of the SF, as revealed by thermogravimetric analyses and Fourier transform infrared spectroscopy (FTIR), respectively. SF/HNT 1 wt% composite scaffolds better supported the viability and spreading of 3T3 fibroblasts and the differentiation of C2C12 myoblasts into aligned myotubes. These scaffolds coated with decellularised ECM from 3T3 cells or primary human dermal fibroblasts (HDFs) supported the growth of primary human keratinocytes. However, SF/HNT 1 wt% composite scaffolds with HDF-derived ECM provided the best microenvironment, as on these, keratinocytes formed intact monolayers with an undifferentiated, basal cell phenotype. Our data indicate the merits of SF/HNT 1 wt% composite scaffolds for applications in soft tissue repair and the expansion of primary human keratinocytes for skin regeneration.

Summary The long-term expansion of keratinocytes under serum- and feeder free conditions generally results in diminished proliferation and an increased commitment to terminal differentiation. Here we present a serum and xenogeneic feeder free culture system that retains the self-renewal capacity of primary human keratinocytes. In vivo , the tissue microenvironment is a major contributor to determining cell fate and a key component of the microenvironment is the extracellular matrix (ECM). Accordingly, acellular ECMs derived from human dermal fibroblasts, cultured under macromolecular crowding conditions to facilitate matrix deposition and organisation, were used as the basis for a xenogeneic-free keratinocyte expansion protocol. A phospholipase A 2 decellularisation procedure produced matrices which, by proteomics analysis, resembled in composition the core matrix proteins of skin dermis. On these ECMs keratinocytes proliferated rapidly, retained their small size, expressed p63, did not express keratin 10 and rarely expressed keratin 16. Moreover, the colony forming efficiency of keratinocytes cultured on these acellular matrices was markedly enhanced. Collectively these data indicate that the dermal fibroblast-derived matrices support the in vitro expansion of keratinocytes that maintained stem-like characteristics under serum free conditions.

Fetal skin has an intrinsic regenerative capability to restore an injured site's architecture and functionality. This is preserved until the third trimester, when wound healing transitions to a scarring reparative response. This change coincides with the dynamic remodelling of dermal extracellular matrix (ECM). Here, we used primary human fetal or adult dermal fibroblast (fHDF and aHDF)-derived ECMs to demonstrate that different extrinsic signals from these ECMs dramatically altered gene expression in a primary human keratinocyte population grown on these matrices. Gene array data revealed keratinocytes grown on fHDF ECM markedly upregulated expression of cell-cycle genes, whereas on aHDF ECM expression of differentiation genes was favoured. Detailed proteomic analyses indicated compositionally distinct ECMs were deposited by aHDFs and fHDFs. Moreover, aHDFs and fHDFs contained subpopulation(s) that differentially expressed CD90, CD146 and CD26. On fHDFs the extracellular domain of CD26 was shed whereas on aHDFs full-length CD26 dominated. The proteomic and gene array data supported the fine-tuning of BMP/TGFβ/SMAD signalling pathways being a mechanism by which fetal matrices promote keratinocyte self-renewal. Collectively, these findings revealed that a fundamental aspect of skin development is dictated by the ECM of the dermis, specifically extrinsic signals from dermal fibroblast ECM direct keratinocyte self-renewal or differentiation.