This manuscript describes a FACS-based protocol for isolation of papillary and reticular fibroblasts from human skin. It circumvents in vitro culture which was inevitable with the commonly used isolation protocol via explant cultures. The emanating fibroblast subsets are functionally distinct and display differential gene expression and localization within the dermis.
Fibroblasts are a highly heterogeneous cell population implicated in the pathogenesis of many human diseases. In human skin dermis, fibroblasts have traditionally been attributed to the superficial papillary or lower reticular dermis according to their histological localization. In mouse dermis, papillary and reticular fibroblasts originate from two different lineages with diverging functions regarding physiological and pathological processes and a distinct cell surface marker expression profile by which they can be distinguished.
Importantly, evidence from explant cultures from superficial and lower dermal layers suggest that at least two functionally distinct dermal fibroblasts lineages exist in human skin dermis as well. However, unlike for mouse skin, cell surface markers enabling the discrimination of different fibroblast subsets have not yet been established for human skin. We developed a novel protocol for the isolation of human papillary and reticular fibroblast populations via fluorescence-activated cell sorting (FACS) using the two cell surface markers Fibroblast Activation Protein (FAP) and Thymocyte antigen 1 (Thy1)/CD90. This method enables the isolation of pure fibroblast subsets without in vitro manipulation, which was shown to affect gene expression, thus permitting accurate functional analysis of human dermal fibroblast subsets in regard to tissue homeostasis or disease pathology.
As the main cellular component of connective tissue, fibroblasts are primarily responsible for the deposition of collagen and elastic fibers that ultimately form the extracellular matrix1, and thus, their role in tissue homeostasis, regeneration and disease has been underestimated for a long time. However, fibroblasts have recently come under the spotlight of researchers, not only because they represent a prominent cellular source for induced pluripotent stem cells2 but also because of their high plasticity and implication in the pathogenesis of a wide number of diseases such as organ fibrosis3,4,5 or cancer6,7.
Human skin is composed of a multi-layered epithelium, the epidermis, and its underlying connective tissue, the dermis, which can be histologically subdivided into the upper papillary and the lower reticular dermis and is mainly composed of fibroblasts and extracellular matrix8 and the hypodermis. According to their location within the tissue, dermal fibroblasts have roughly been classified into papillary and reticular fibroblasts1.
Importantly, recent data indicate that these dermal fibroblast subpopulations are not only histologically distinguishable, but also that their function is considerably diverse. In mouse skin, papillary and reticular fibroblasts arise from two distinct lineages during embryogenesis9. Several lines of evidence suggest that the two lineages exert different roles not only in tissue homeostasis, hair follicle morphogenesis, wound repair and fibrosis7,9,10, but they also respond to different signals from neoplastic epidermal stem cells11, suggesting diverging roles in cancer pathogenesis. Conveniently, both lineages express a distinct set of mutually exclusive cellular markers in adult mouse skin, thus enabling the isolation of pure dermal fibroblast populations and subsequent extensive analysis of their specific functions in vitro9,11.
Correspondingly, at least two distinct fibroblast subsets with distinct morphology and functions, including diverging proliferation rates, tissue remodeling capacities12,13, as well as the ability to support the growth of epidermal stem cells in vitro, have been described for human skin dermis14,15. However, most of the published studies on human dermal fibroblasts have been conducted using mixed fibroblast populations isolated from explant cultures from dermatomed skin, since specific cell surface marker sets enabling the isolation of pure human papillary or reticular fibroblast subpopulations in analogy to mouse dermis were yet to be established.
We have recently demonstrated, that human skin papillary and reticular fibroblasts are characterized by specific cell surface markers that enable the isolation of the respective subpopulations via fluorescence-activated cell sorting (FACS)16: FAP+CD90– fibroblasts represent papillary fibroblasts primarily located in the upper dermis, presenting higher proliferation rates, a distinct gene signature but no adipogenic potential. FAP+CD90+ and FAP–CD90+ fibroblasts belong to the reticular lineage of the lower dermal compartments, which are less proliferative but readily undergo adipogenesis—a hallmark for reticular fibroblasts. This method enables to extensively study these distinct fibroblast subpopulations not only in regard to their specific functions under physiological conditions but also in the context of the pathogenesis of cutaneous diseases including skin cancer.
However, since fibroblasts alter their cell surface marker expression in two-dimensional in vitro culture16,17,19, the application of our protocol is limited to the isolation of primary fibroblasts from human dermis and does not permit the identification of papillary or reticular fibroblasts in mixed cell culture populations. Importantly, although the expression of cell surface markers changes in vitro, we have demonstrated that the fibroblast subsets isolated according to the protocol described below retain their specific functionality when cultivated16, thus enabling in vitro studies of subset-specific properties under physiological or pathological conditions.
In conclusion, we developed a protocol for the isolation of distinct fibroblast subsets via FACS that for the first time permits the isolation of pure fibroblast populations from human skin dermis in a naïve state.
In this article, we describe a method for the isolation of papillary and reticular fibroblasts from human skin. CD90 has been widely used for the identification or isolation of dermal fibroblasts18,20,21. However, we have demonstrated that besides CD90+ fibroblasts, human dermis also harbors a CD90– fibroblast population expressing FAP16, which has been established as a marker for activated fibroblasts and cancer-associated fibroblasts (CAFs)22,23,24,25. Importantly, we were able to identify three fibroblast subpopulations FAP+CD90–, FAP+CD90+ and FAP–CD90+ in skin biopsies from all healthy human donors. We therefore conclude that FAP is not only a marker for activated fibroblasts or CAFs but also normal tissue fibroblasts.
Of note, the FAP–CD90– cell population remaining after application of the above-described exclusion- and gating strategy does not contain fibroblasts, since these cells do not proliferate in fibroblast cultivation medium in vitro, but most likely a mixed cell population including lymphatic cells and pericytes amongst others16.
The cell yield obtained by use of the above-described protocol can vary depending on the body-part that the skin piece used for the isolation originates from. Dermis from different body parts differs regarding its structure, thickness as well as collagen composition. For example, skin from the face or the upper arm is much thinner than skin from the belly or the thigh, which also frequently display a thicker subcutaneous fat layer. Additionally, age and sex of the skin donors may further not only impact the tissue dissociation efficiency, but may also affect the distribution of the three fibroblast subpopulations (Figure 3) when isolated from full thickness skin. This results from the fact that the papillary dermis shrinks and that total fibroblast numbers decrease with age11,26,27,28. Furthermore, the cell pellet from papillary dermis will probably be larger than from reticular dermis, since the upper dermis is more densely populated by fibroblasts than the reticular dermis. Besides, the lower dermis is also tougher and more densely packed with collagen, making it harder to dissociate the tissue and to release the fibroblasts. Of note, the cell pellet may appear very red, which is why red blood cell lysis is recommended.
In addition to the identification of three subpopulations in intact human skin, we also show that in dermatomed skin, each fibroblast subset is enriched either in papillary or reticular dermis16. Precise slicing of the skin with the dermatome is critical to obtain a proper enrichment of each subpopulation from different dermal layers. Since the papillary dermis is very thin, the dermatomed slice representing it should not exceed a thickness of 300 µm. Upper reticular and lower reticular fibroblasts both represent the reticular lineage and display similar functions and gene signatures, therefore, one could also consider not separating them.
Importantly, all three fibroblasts populations are found throughout the dermis and are not exclusively present in one layer, which is why explant cultures from papillary or reticular dermis result in mixed fibroblast cultures. However, FAP+CD90– papillary fibroblast are most abundant in the papillary dermis and follow a gradient from superficial to lower dermal layers while FAP+CD90+ and FAP–CD90+ fibroblasts follow an inverse gradient from the lower to the superficial layers16. Furthermore, the majority of CD90+ fibroblasts of the papillary dermis are almost exclusively found surrounding blood vessels and express the perivascular fibroblast marker CD14629, and thus probably exhibit different functions than the remaining CD146– reticular fibroblasts16. CD146 could be used as an additional marker in the gating strategy to exclude this population.
Following the dissociation of dermal layers, the isolated cells are stained with a specially designed antibody cocktail containing various antibodies for the exclusion of immune cells, endothelial and lymphatic cells, epidermal cells, erythrocytes and MSCs to obtain pure fibroblast populations. Of note, choosing a marker for the identification and exclusion of MSCs may be tricky because of the high number of published MSC markers30,31. Since MSCs express CD90 like fibroblasts, additional MSC markers such as CD105 or CD271 could prove useful for their identification. However, MSCs only represent a very low percentage of all dermal cells and since CD90+ fibroblasts display typical morphological features of fibroblasts upon sorting, one could argue that the exclusion of MSCs by use of distinct cell surface markers might be unnecessary.
Importantly, we analyzed FAP and CD90 gene expression after keeping the cells in culture for 7-14 days after sorting (data not shown) and found that expression of both markers is upregulated in the respective sorted single positive (FAP+CD90– or FAP–CD90+) cells16. We therefore emphasize that the above-described marker sets and protocol permit the isolation of primary fibroblast subsets directly from the tissue but not from previously cultured mixed fibroblast populations.
Nevertheless, we demonstrate that the functionality of all three subpopulations is retained in cell culture regardless of the alteration of cell surface marker expression, since fibroblasts sorted as FAP+CD90– papillary fibroblasts do not acquire the ability to undergo adipogenesis after a longer period of culture, while fibroblasts sorted as FAP+CD90+ or FAP–CD90+ reticular fibroblasts maintain their ability to differentiate into adipocytes 16. Importantly, we also found that papillary and reticular-specific genes are still expressed to a higher extent in FAP+CD90– and CD90+ respectively.
In conclusion, we have established a protocol for the isolation of functionally distinct fibroblast subsets via FACS that for the first time permits the isolation and analysis of pure and naïve fibroblast subpopulations from human skin dermis. This method establishes a major advancement to the commonly used fibroblast explant culture isolation protocol from upper and lower dermis as (i) an opposing gradient of papillary and reticular fibroblasts exists from the skin surface to the hypodermis and (ii) fibroblasts change their gene signature in vitro.
The authors have nothing to disclose.
We gratefully acknowledge assistance in FACS-sorting by Bärbel Reininger and Wolfgang Bauer. This work was supported by grants to B. M. L. from the Austrian Science Fund (FWF: V 525-B28), and the Federation of European Biochemical Societies (FEBS, Follow-Up Research Fund). S. F. is recipient of a DOC Fellowship of the Austrian Academy of Sciences (OeAW). We gratefully acknowledge excellent support from the core facilities at the Medical University of Vienna. We thank Bernhard Gesslbauer, Christine Radtke and Martin Vierhapper for providing human skin material.
Material: | |||
3-isobutyl-1-methylxanthine | Sigma | I5879 | |
Ammonium chloride | Sigma | 9718 | used for selfmade ACK Lysis Buffer |
Amniomax-C100 (1x) Basal Medium | Gibco | 17001-074 | used for fibroblast growth medium |
β-Mercaptoethanol | Scharlau | ME0095 | ! CAUTION |
C100 Supplement | Thermo Scientific | 12556015 | used for fibroblast growth medium |
Collagenase I | Thermo Scientific | 17100017 | ! CAUTION |
Collagenase II | Gibco | 17101015 | ! CAUTION |
Collagenase IV | Sigma | C5138 | ! CAUTION |
DAPI | Thermo Scientific | 62248 | |
Dexamethasone | Sigma | D8893 | |
Dispase II | Roche | 4942078001 | ! CAUTION |
Dulbecco‘s Modified Eagle Medium + GlutaMAX | Gibco | 31966-021 | |
EDTA disodium salt | Sigma | E1644 | used for selfmade ACK Lysis Buffer |
Fetal bovine serum (heat inactivated) | Gibco | 10500-064 | |
Hyaluronidase | Sigma | H4272 | ! CAUTION |
Insulin | Sigma | I5500 | |
Isopropanol | Merck | 1,096,341,011 | |
OilRed O | Sigma | O-0625 | |
Paraformaldehyd | Sigma | 158127 | ! CAUTION Cancerogenic. Skin and eye irritant. Handle with care. |
Penicillin/Streptomycin | Gibco | 15070-063 | |
Phosphate-buffered saline without Ca++ & Mg++ | Lonza | BE17-512F | |
Potassium bicarbonate | Sigma | 237205 | used for selfmade ACK Lysis Buffer |
PureLink RNA MicroKit | Invitrogen | 12183-016 | |
SuperScript III First-Strand Synthesis SuperMix for qRT-PCR | Invitrogen | 11752 | |
Taqman 2xUniversal PCR Master Mix | Applied Biosystems | 4324018 | ! CAUTION Skin and eye irritant. |
Troglitazone | Sigma | T2573 | |
Name | Company | Catalog Number | Comments |
Flow cytometry Antibodies: | |||
anti human CD31-AF488 | Biolegend | 303109 | Dilution: 1:30, Lot: B213986, RRID: AB_493075 |
anti human CD45-Pacific blue | Biolegend | 304029 | Dilution: 1:20, Lot: B218608, RRID: AB_2174123 |
anit human CD49f/ITGA6-PE | Serotec | MCA699PE | Dilution: 1:20, Lot: 0109, RRID: AB_566833 |
anti human CD90/Thy-1-AF700 | Biolegend | 328120 | Dilution: 1:30, Lot: B217250, RRID: AB_2203302 |
anti human CD106-AF421 | BD | 744309 | Dilution: 1:100, Lot: 7170537, RRID: x |
anti human CD235ab-Pacific blue | Biolegend | 306611 | Dilution: 1:1000, Lot: B224563, RRID: AB_2248153 |
anti-human E-cadherin-PE | Biolegend | 147304 | Dilution: 1:20, Lot: B197481, RRID: AB_2563040 |
anti human FAP-APC | R&D | FAB3715A | Dilution: 1:20, Lot: AEHI0117111, RRID: x |
Human TruStain FcX | Biolegend | 422302 | Dilution: 1:20, Lot: B235080, RRID: x |
Name | Company | Catalog Number | Comments |
Equipment: | |||
1.4 mL micronic tubes | Thermo Scientific | 4140 | |
1.5 mL screw cap micro tube | Sarstedt | 72,692,405 | |
5 mL Polystyrene Round Bottom Tube with cell strainer cap | Falcon | 352235 | |
48-well cell culture cluster | Costar | 3548 | |
50 mL polypropylene canonical tubes | Falcon | 352070 | |
70 µm cell strainer nylon | Falcon | 352350 | |
Aesculap Acculan 3Ti Dermatome | VWR | AESCGA670 | |
Aesculap Dermatome blades | VWR | AESCGB228R | |
MicroAmp Fast Optical 96well | Applied Biosystems | 4346906 | |
Primary cell culture dish | Corning | 353803 | |
Scalpel blades | F.S.T | 10022-00 | |
Tea strainer | x | x | |
Name | Company | Catalog Number | Comments |
Fibroblast growth medium: | |||
AmnioMAX basal medium with AmnioMAX C-100 Supplement, 10 % FCS and 1 % P/S |