Analysis of Proteins with Caseinolytic Activity in a Human Stratum Corneum Extract Revealed a Yet Unidentified Cysteine Protease and Identified the So-Called “Stratum Corneum Thiol Protease” as Cathepsin L2

Bernard, Dominique; Méhul, Bruno; Thomas-Collignon, Agnès; Simonetti, Lucie; Remy, V.; Bernard, M.A.; Schmidt, Rainer

doi:10.1046/j.1523-1747.2003.12086.x

Cited by 80 publications

(57 citation statements)

References 26 publications

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“…77 Furthermore, cathepsin L2 has been detected in stratum corneum extracts. 78 This protease seems to be activated during epidermal differentiation and secreted into the intercellular space. Schematic structure of procaspase-14 as compared to other short-prodomain caspases (human).…”

Section: Cathepsinsmentioning

confidence: 99%

Death penalty for keratinocytes: apoptosis versus cornification

et al. 2005

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Homeostasis implies a balance between cell growth and cell death. This balance is essential for the development and maintenance of multicellular organisms. Homeostasis is controlled by several mechanisms including apoptosis, a process by which cells condemned to death are completely eliminated. However, in some cases, total destruction and removal of dead cells is not desirable, as when they fulfil a specific function such as formation of the skin barrier provided by corneocytes, also known as terminally differentiated keratinocytes. In this case, programmed cell death results in accumulation of functional cell corpses. Previously, this process has been associated with apoptotic cell death. In this overview, we discuss differences and similarities in the molecular regulation of epidermal programmed cell death and apoptosis. We conclude that despite earlier confusion, apoptosis and cornification occur through distinct molecular pathways, and that possibly antiapoptotic mechanisms are implicated in the terminal differentiation of keratinocytes.

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Section: Cathepsinsmentioning

confidence: 99%

Death penalty for keratinocytes: apoptosis versus cornification

et al. 2005

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“…Alternatively, binding to ␣2ML1 could protect KLK7 either from hydrolysis by other proteases or from inhibitors such as the serine protease inhibitor SPINK5, which plays a pivotal role in controlling KLK5-and KLK7-like activities in the upper epidermis (48,49). Beside KLK7, cathepsin L2, also called stratum corneum thiol protease and cathepsin L-like are papain-like cysteine proteases that are thought to be involved in desquamation (50). The high efficient inhibition of papain by ␣2ML1 suggests that cathepsin L2 and cathepsin L-like may also be physiological targets of ␣2ML1 in vivo.…”

Section: Inhibitormentioning

confidence: 99%

A Novel Protease Inhibitor of the α2-Macroglobulin Family Expressed in the Human Epidermis

Galliano

Toulza

Gallinaro

et al. 2006

Journal of Biological Chemistry

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In the course of a large scale analysis of late-expressed genes in the human epidermis, we identified a new member of the ␣ 2 -macroglobulin (␣2M) protease inhibitor family, A2ML1 (for ␣ 2 -macroglobulin-like 1). Like A2M and PZP, A2ML1 is located on chromosome 12p13.31. A2ML1 encodes a protein of 1454 amino acids, which fits the characteristics of ␣2Ms: 1) strong conservation in amino acid sequence including most of cysteine positions with ␣2M; 2) a putative central bait domain; 3) a typical thiol ester sequence. Northern blot and reverse transcriptase-PCR studies revealed a single 5-kb A2ML1 mRNA, mainly in the epidermis granular keratinocytes. A2ML1 is also transcribed in placenta, thymus, and testis. By Western blot analysis, ␣2ML1 is detected as a monomeric, ϳ180-kDa protein in human epidermis. In vitro keratinocyte differentiation is associated with increased expression levels. By immunohistochemistry, ␣2ML1 was detected within keratinosomes in the granular layer of the epidermis, and as a secreted product in the extracellular space between the uppermost granular layer and the cornified layer. Recombinant ␣2ML1 displayed inhibitory activity toward chymotrypsin, papain, thermolysin, subtilisin A, and to a lesser extent, elastase but not trypsin. Incubation with chymotrypsin and the chymotrypsin-like kallikrein 7 protease indicated that ␣2ML1 binds covalently to these proteases, a feature shared with other members of the family. Therefore, ␣2ML1 is the first ␣2M family member detected in the epidermis. It may play an important role during desquamation by inhibiting extracellular proteases.Regulation of proteolytic enzyme activity is essential for cell and tissue homeostasis. In epidermis, proteolysis of adhesive structures is a prerequisite for desquamation. Several members of the four protease classes with suggested roles in desquamation have been described in epidermis (reviewed in Ref. 1). A wide variety of protease inhibitors is also present in the intercellular spaces of the stratum corneum and participates in the regulation of desquamation-associated proteolysis. Disturbance of the protease-antiprotease balance may have dramatic consequences as demonstrated by the discovery of the serine protease inhibitor Kazal type 5 (SPINK5) also known as lymphoepithelial Kazal type-related inhibitor (LEKTI) as the defective gene in Netherton syndrome (2). The importance of regulated proteolysis in epidermis has also been reported in mouse models. Targeted epidermal overexpression of the serine protease kallikrein 7 (KLK7), 2 also known as stratum corneum chymotryptic enzyme (SCCE), results in a severe phenotype (3). Conversely, a null mutation in the mouse cystatin M/E gene (Cst6), encoding a cysteine protease inhibitor, induces neonatal lethality and abnormalities in cornification and desquamation, highlighting the essential role for protease inhibitors during the final stages of epidermal differentiation (4).In the course of a large scale search for genes specifically expressed by the last transcriptionally activ...

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“…Most of these processes involve the creation of gradients of ions across the SC that influence water permeation through lipid layers. For example, changes in the pH and calcium gradient across the SC alter the permeability of the skin, and affect barrier recovery after disruption (Menon et al, 1994;Bernard et al, 2003;Fluhr et al, 2004a,b). Despite the variety of biological mechanisms known to modify the performance of the permeability barrier in the skin, no studies have attempted to separate the contribution of physical and biological factors in the formation of the epidermal water barrier.…”

mentioning

confidence: 99%

Cutaneous water loss and lipids of the stratum corneum in house sparrowsPasser domesticusfrom arid and mesic environments

Muñoz‐Garcia¹,

Williams²

2005

Journal of Experimental Biology

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·SC·dry·mass in Ohio), and a lower percentage of cholesterol (4.1±3.6% in Saudi Arabia; 5.4±2.5% in Ohio) in their SC.Although CWL was lower in sparrows from Arabia, and lipid composition of their SC differed, we could not detect differences between rates of water loss through non-living skin attached to glass vials (46.0±15.7·mg·H 2 O·cm -2 ·day -1 for sparrows in Saudi Arabia; 45.8±27.2·mg·H 2 O·cm -2 ·day -1 for sparrows in Ohio). These results suggest that biological control mechanisms interact with layers of lipids in the stratum corneum to adjust CWL to the environment.

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Analysis of Proteins with Caseinolytic Activity in a Human Stratum Corneum Extract Revealed a Yet Unidentified Cysteine Protease and Identified the So-Called “Stratum Corneum Thiol Protease” as Cathepsin L2

Cited by 80 publications

References 26 publications

Death penalty for keratinocytes: apoptosis versus cornification

Death penalty for keratinocytes: apoptosis versus cornification

A Novel Protease Inhibitor of the α2-Macroglobulin Family Expressed in the Human Epidermis

Cutaneous water loss and lipids of the stratum corneum in house sparrowsPasser domesticusfrom arid and mesic environments

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