Patient-specific naturally gene-reverted induced pluripotent stem cells in recessive dystrophic epidermolysis bullosa

Key Points The skin, together with other epithelial-cell interfaces with a hostile environment, supports a range of passive and active immune defence mechanisms. Cutaneous immune responses serve as a model for the study of interactions between innate and acquired immune mechanisms. Adaptive immune surveillance addresses the logistical challenge of targeting naive, effector and memory T cells to their respective sites of function by using distinct homing mechanisms at different stages of the immune response, termed primary, secondary and tertiary immune surveillance. Primary immune surveillance involves the process by which tissue dendritic cells are induced to engulf foreign particles, undergo maturation and emigrate through the afferent lymphatics to the local draining lymph node, where they encounter naive T cells recruited from the peripheral circulation. This greatly increases the efficiency with which naive T cells are exposed to antigens presented by professional antigen-presenting cells. Secondary immune surveillance involves the production and distribution of antigen-specific effector memory T cells that express homing receptors that direct their migration back to the tissue draining the lymph node where activation occurred and their participation in tissue-based immune responses. The persistence of memory T cells with both antigen and tissue specificity also protects against possible future encounters with the same pathogen, by providing a population of antigen-specific effector cells pre-targeted to the site where exposure to that pathogen might most probably recur. Tertiary immune surveillance involves the production of central memory and effector cells potentially directed to lymph nodes and tissues other than the site of primary exposure, providing broad coverage in the event that the pathogen is encountered through a different route. These concepts have implications for the understanding of both inflammatory skin disorders and the development of antitumour and antipathogen vaccine strategies.

Since publication in 2000 of the Second International Consensus Report on Diagnosis and Classification of Epidermolysis Bullosa, many advances have been made to our understanding of this group of diseases, both clinically and molecularly. At the same time, new epidermolysis bullosa (EB) subtypes have been described and similarities with some other diseases have been identified. We sought to arrive at a new consensus of the classification of EB subtypes. We now present a revised classification system that takes into account the new advances, as well as encompassing other inherited diseases that should also be included within the EB spectrum, based on the presence of blistering and mechanical fragility. Current recommendations are made on the use of specific diagnostic tests, with updates on the findings known to occur within each of the major EB subtypes. Electronic links are also provided to informational and laboratory resources of particular benefit to clinicians and their patients. As more becomes known about this disease, future modifications may be needed. The classification system has been designed with sufficient flexibility for these modifications. This revised classification system should assist clinicians in accurately diagnosing and subclassifying patients with EB.

Embryonic stem cells (ESCs) have an unlimited proliferative capacity and extensive differentiation capability. They are an alternative source for regenerative therapies with a potential role in the treatment of several human diseases. The clinical use of ESCs, however, has significant ethical and biological obstacles related to their derivation from embryos and potential for immunological rejection, respectively. These disadvantages can be circumvented by the alternative use of induced pluripotent stem cells (iPSCs), which are generated from an individual's (autologous) somatic cells by exogenous expression of defined transcription factors and have biological characteristics similar to ESCs. In recent years, patient-specific iPSCs have been generated to study disease mechanisms and develop iPSC-based therapies. The development of iPSC-based therapies for skin diseases requires successful differentiation of iPSCs into cellular components of the skin, including epidermal keratinocytes. Here, we succeeded in generating iPSCs not only from normal human fibroblasts but also from fibroblasts isolated from the skin of two patients with recessive dystrophic epidermolysis bullosa. Moreover, we differentiated both of these iPSCs into keratinocytes with high efficiency, and generated 3D skin equivalents using iPSC-derived keratinocytes, suggesting that they were fully functional. Our studies indicate that autologous iPSCs have the potential to provide a source of cells for regenerative therapies for specific skin diseases.