Fibroblasts as Target Cells for DEB Gene Therapy

Histological and molecular restoration of type VII collagen in Recessive dystrophic epidermolysis bullosa mouse skin by topical injection of keratinocyte-like cells differentiated from human adipose-derived mesenchymal stromal cells

BACKGROUND

Recessive dystrophic epidermolysis bullosa (RDEB) is a severe skin fragility disorder caused by mutations in the COL7A1 gene, which encodes type VII collagen (COL7), the main constituent of anchoring fibrils for attaching the epidermis to the dermis. Persistent skin erosions frequently result in intractable ulcers in RDEB patients. Adipose-derived mesenchymal stromal cells (AD-MSCs) are easily harvested in large quantities and have low immunogenicity. Therefore, they are suitable for clinical use, including applications involving allogeneic cell transplantation. Keratinocyte-like cells transdifferentiated from AD-MSCs (KC-AD-MSCs) express more COL7 than undifferentiated AD-MSCs and facilitate skin wound healing with less contracture. Therefore, these cells can be used for skin ulcer treatment in RDEB patients.

OBJECTIVE

We investigated whether KC-AD-MSCs transplantation ameliorated the RDEB phenotype severity in the grafted skin of a RDEB mouse model (col7a1-null) on the back of the immunodeficient mouse.

METHODS

KC-AD-MSCs were intradermally injected into the region surrounding the skin grafts, and this procedure was repeated after 7 days. After a further 7-day interval, the skin grafts were harvested.

RESULTS

Neodeposition of COL7 and generation of anchoring fibrils at the dermal-epidermal junction were observed, although experiments were based on qualitative.

CONCLUSION

KC-AD-MSCs may correct the COL7 insufficiency, repair defective/reduced anchoring fibrils, and improve skin integrity in RDEB patients.

Medical cell technologies for treatment of patients suffering from recessive dystrophic epidermolysis bullosa. Method of intracutaneous administration of fibroblasts

Recessive dystrophic epidermolysis bullosa (RDEB) is a severe inherited disease developing due to genetic abnormalities in the synthesis of Type VII collagen by fibroblasts. A low production rate of Type VII collagen and abnormalities related to the formation of anchoring fibrils weaken the epidermis and derma adhesion strength, which results in the formation of blisters or erosions in case of any mechanical injury. Fibroblasts and keratinocytes belong to the key sources of Type VII collagen in the skin. Application of allogeneic fibroblasts is a promising cell technique for treating RDEB patients. The therapeutic effect of fibroblasts intradermal administration is stipulated by high stability of newly synthesized Type VII collagen and its ability to form anchoring fibrils in the area of the dermoepidermal junction. According to experimental and clinical studies, it is possible to boost the content of Type VII collagen in the dermoepidermal junction area and heal long-term skin defects in RDEB patients by means of intradermal administration of allogeneic fibroblasts.

Fibroblast-based cell therapy strategy for recessive dystrophic epidermolysis bullosa

Dystrophic epidermolysis bullosa (DEB) is a severe skin fragility disorder associated with trauma-induced blistering, progressive soft tissue scarring, and increased risk of skin cancer. DEB is caused by mutations in the COL7A1 gene which result in reduced, truncated, or absent type VII collagen, and anchoring fibrils at the dermal-epidermal junction (DEJ). Because no topical wound-healing agents have shown unequivocal benefit in the treatment of DEB, alternative approaches are needed. The purpose of cell therapy for recessive DEB is to increase the amount of collagen VII in the basement membrane zone in order to heal wounds and prevent further wound formation. Fibroblast-based cell therapy is safe and easy to work with, has few side effects, can dramatically restore stable collagen VII at the DEJ, and can normalize the substructure changes of DEB for at least a few months. Even though the mechanism and the duration of newly produced collagen VII at the DEJ are still unknown, this form of cell therapy provides a new effective approach to the treatment of recessive DEB.

Transient anti-CD40L co-stimulation blockade prevents immune responses against human bullous pemphigoid antigen 2: implications for gene therapy

Skin grafts from mice expressing human bullous pemphigoid antigen 2 (hBPAG2) in epidermal basement membrane elicit hBPAG2-specific IgG and graft loss in wild-type (Wt) recipients. Graft loss was dependent on CD4+ T cells and correlated with the production and tissue deposition of hBPAG2-specific IgG. To explore the role of CD40/CD40 ligand (CD40L) interaction in this model, Wt mice grafted with transgenic (Tg) skin were treated with hamster anti-CD40L mAb MR1. In contrast to grafted Wt mice treated with equivalent doses of control IgG, 22 of 23 MR1-treated Wt mice did not develop hBPAG2-specific IgG or graft loss for >or=60 days. MR1-treated mice also accepted a second Tg skin graft without durable production of hBPAG2-specific IgG or graft loss. Moreover, splenocytes and enriched CD4+ T cells from MR1-treated graft recipients transferred un- or hyporesponsiveness to hBPAG2 to other mice and demonstrated a dominant tolerant effect over cotransferred naive splenocytes following adoptive transfer to Rag2-/- mice. Successful inhibition of hBPAG2-specific IgG production and Tg graft loss following CD40:CD40L co-stimulatory blockade in this model provides opportunities to study mechanisms of peripheral tolerance and generate antigen-specific regulatory CD4+ cells-issues of relevance to patients with pemphigoid as well as individuals undergoing gene replacement therapy for epidermolyis bullosa.

Epidermolysis bullosa: prospects for cell-based therapies

Heritable forms of epidermolysis bullosa (EB) are characterized by chronic, lifelong blistering and erosions due to mutations in 10 distinct genes expressed at the cutaneous basement membrane zone. No specific treatment for this group of intractable diseases is currently available. Recent progress in molecular therapies has indicated that cell-based approaches may potentially offer amelioration--and perhaps even cure--for afflicted individuals. In this issue, Wong et al. (2008) demonstrate the feasibility of direct intradermal injection of allogeneic fibroblasts to the lesional skin of patients with recessive dystrophic EB, with improvement in skin fragility.

Bone marrow cell transfer into fetal circulation can ameliorate genetic skin diseases by providing fibroblasts to the skin and inducing immune tolerance

Recent studies have shown that skin injury recruits bone marrow-derived fibroblasts (BMDFs) to the site of injury to accelerate tissue repair. However, whether uninjured skin can recruit BMDFs to maintain skin homeostasis remains uncertain. Here, we investigated the appearance of BMDFs in normal mouse skin after embryonic bone marrow cell transplantation (E-BMT) with green fluorescent protein-transgenic bone marrow cells (GFP-BMCs) via the vitelline vein, which traverses the uterine wall and is connected to the fetal circulation. At 12 weeks of age, mice treated with E-BMT were observed to have successful engraftment of GFP-BMCs in hematopoietic tissues accompanied by induction of immune tolerance against GFP. We then investigated BMDFs in the skin of the same mice without prior injury and found that a significant number of BMDFs, which generate matrix proteins both in vitro and in vivo, were recruited and maintained after birth. Next, we performed E-BMT in a dystrophic epidermolysis bullosa mouse model (col7a1(-/-)) lacking type VII collagen in the cutaneous basement membrane zone. E-BMT significantly ameliorated the severity of the dystrophic epidermolysis bullosa phenotype in neonatal mice. Type VII collagen was deposited primarily in the follicular basement membrane zone in the vicinity of the BMDFs. Thus, gene therapy using E-BMT into the fetal circulation may offer a potential treatment option to ameliorate genetic skin diseases that are characterized by fibroblast dysfunction through the introduction of immune-tolerated BMDFs.

Potential of fibroblast cell therapy for recessive dystrophic epidermolysis bullosa

Recessive dystrophic epidermolysis bullosa (RDEB) is a severe inherited skin-blistering disorder caused by mutations in the COL7A1 gene that lead to reduced type-VII collagen and defective anchoring fibrils at the dermal-epidermal junction (DEJ). Presently there are no effective treatments for this disorder. Recent mouse studies have shown that intradermal injections of normal human fibroblasts can generate new human type-VII collagen and anchoring fibrils at the DEJ. To assess potential clinical benefits in humans, we gave single intradermal injections of allogeneic fibroblasts to five subjects with RDEB. We noted increased type-VII collagen at the DEJ at 2 weeks and at 3 months following injection and increased anchoring fibrils, although none of these had normal morphology. No adverse effects, clinical or immunopathologic, were noted. We believe the major effect of allogeneic fibroblasts is to increase the recipients' own COL7A1 mRNA levels with greater deposition of mutant type-VII collagen at the DEJ and formation of additional rudimentary anchoring fibrils. Nevertheless, this mutant protein may be partially functional and capable of increasing adhesion at the DEJ. This is the first study demonstrating that intradermal injections of allogeneic fibroblasts have therapeutic potential in human subjects with RDEB.