Filaggrin-2 (FLG2), a member of the S100-fused type protein family, shares numerous features with filaggrin (FLG), a key protein implicated in the epidermal barrier functions. Both display a related structural organization, an identical pattern of expression and localization in human epidermis, and proteolytic processing of a large precursor. Here, we tested whether FLG2 was a substrate of calpain 1, a calcium-dependent protease directly involved in FLG catabolism. In addition, deimination being critical for FLG degradation, we analyzed whether FLG2 deimination interfered with its proteolytic processing. With this aim, we first produced a recombinant form of FLG2 corresponding to subunits B7 to B10 fused to a COOH-terminal His tag. Incubation with calpain 1 in the presence of calcium induced a rapid degradation of the recombinant protein and the production of several peptides, as shown by Coomassie Blue-stained gels and Western blotting with anti-FLG2 or anti-His antibodies. MALDI-TOF mass spectrometry confirmed this result and further evidenced the production of non-immunoreactive smaller peptides. The degradation was not observed when a calpain 1-specific inhibitor was added. The calpain cleavage sites identified by Edman degradation were regularly present in the B-type repeats of FLG2. Moreover, immunohistochemical analysis of normal human skin revealed colocalization of FLG2 and calpain 1 in the upper epidermis. Finally, the FLG2 deiminated by human peptidylarginine deiminases was shown to be more susceptible to calpain 1 than the unmodified protein. Altogether, these data demonstrate that calpain 1 is essential for the proteolytic processing of FLG2 and that deimination accelerates this process.In the epidermis, the program of keratinocyte terminal differentiation is an oriented process during which cells of the basal layer undergo a series of metabolic and structural changes throughout their migration to the surface of the tissue. The stratum corneum, the outermost layer of the epidermis, is formed by the stacking of so-called corneocytes, the end products of the process. The stratum corneum functions as an effective barrier between the body and its outside environment, limiting skin dehydration and preventing the penetration of outside pathogens, UV radiation, and exogenous chemicals. It also contributes to mechanical protection of the body. So that this function can be achieved, peculiar structures are formed, such as the cornified cell envelope, a resistant and insoluble protein shell that replaces the plasma membrane, and the intracorneocyte fibrous matrix made by the aggregation of keratin intermediate filaments.
