Karin List

Matriptase/MT-SP1 is required for postnatal survival, epidermal barrier function, hair follicle development, and thymic homeostasis

Matriptase/MT-SP1 is a novel tumor-associated type II transmembrane serine protease that is highly expressed in the epidermis, thymic stroma, and other epithelia. A null mutation was introduced into the Matriptase/MT-SP1 gene of mice to determine the role of Matriptase/MT-SP1 in epidermal development and neoplasia. Matriptase/MT-SP1-deficient mice developed to term but uniformly died within 48 h of birth. All epidermal surfaces of newborn mice were grossly abnormal with a dry, red, shiny, and wrinkled appearance. Matriptase/MT-SP1-deficiency caused striking malformations of the stratum corneum, characterized by dysmorphic and pleomorphic corneocytes and the absence of vesicular bodies in transitional layer cells. This aberrant skin development seriously compromised both inward and outward epidermal barrier function, leading to the rapid and fatal dehydration of Matriptase/MT-SP1-deficient pups. Loss of Matriptase/MT-SP1 also seriously affected hair follicle development resulting in generalized follicular hypoplasia, absence of erupted vibrissae, lack of vibrissal hair canal formation, ingrown vibrissae, and wholesale abortion of vibrissal follicles. Furthermore, Matriptase/MT-SP1-deficiency resulted in dramatically increased thymocyte apoptosis, and depletion of thymocytes. This study demonstrates that Matriptase/MT-SP1 has pleiotropic functions in the development of the epidermis, hair follicles, and cellular immune system.

Evidence for a Matriptase-Prostasin Proteolytic Cascade Regulating Terminal Epidermal Differentiation

Recent gene ablation studies in mice have shown that matriptase, a type II transmembrane serine protease, and prostasin, a glycosylphosphatidylinositol-anchored membrane serine protease, are both required for processing of the epidermis-specific polyprotein, profilaggrin, stratum corneum formation, and acquisition of epidermal barrier function. Here we present evidence that matriptase acts upstream of prostasin in a zymogen activation cascade that regulates terminal epidermal differentiation and is required for prostasin zymogen activation. Enzymatic gene trapping of matriptase combined with prostasin immunohistochemistry revealed that matriptase was co-localized with prostasin in transitional layer cells of the epidermis and that the developmental onset of expression of the two membrane proteases was coordinated and correlated with acquisition of epidermal barrier function. Purified soluble matriptase efficiently converted soluble prostasin zymogen to an active two-chain form that formed SDS-stable complexes with the serpin protease nexin-1. Whereas two forms of prostasin with molecular weights corresponding to the prostasin zymogen and active prostasin were present in wild type epidermis, prostasin was exclusively found in the zymogen form in matriptase-deficient epidermis. These data suggest that matriptase, an autoactivating protease, acts upstream from prostasin to initiate a zymogen cascade that is essential for epidermal differentiation.

Epithelial Integrity Is Maintained by a Matriptase-Dependent Proteolytic Pathway

A pericellular proteolytic pathway initiated by the transmembrane serine protease matriptase plays a critical role in the terminal differentiation of epidermal tissues. Matriptase is constitutively expressed in multiple other epithelia, suggesting a putative role of this membrane serine protease in general epithelial homeostasis. Here we generated mice with conditional deletion of the St14 gene, encoding matriptase, and show that matriptase indeed is essential for the maintenance of multiple types of epithelia in the mouse. Thus, embryonic or postnatal ablation of St14 in epithelial tissues of diverse origin and function caused severe organ dysfunction, which was often associated with increased permeability, loss of tight junction function, mislocation of tight junction-associated proteins, and generalized epithelial demise. The study reveals that the homeostasis of multiple simple and stratified epithelia is matriptase-dependent, and provides an important animal model for the exploration of this membrane serine protease in a range of physiological and pathological processes.

Matriptase inhibition by hepatocyte growth factor activator inhibitor-1 is essential for placental development

Hepatocyte growth factor activator inhibitor-1 (HAI-1) is a Kunitz-type transmembrane serine protease inhibitor that forms inhibitor complexes with several trypsin-like serine proteases and is required for mouse placental development and embryo survival. Here we show that the essential function of HAI-1 in placentation and all other embryonic processes is to restrict the activity of the type II transmembrane serine protease, matriptase. Enzymatic gene trapping of matriptase combined with HAI-1 immunohistochemistry revealed that matriptase is co-expressed with HAI-1 in both extraembryonic and embryonic tissues. As early as embryonic day 8.5, matriptase and HAI-1 were expressed in a population of chorionic trophoblasts. Ablation of HAI-1 disrupted the epithelial integrity of this cell population, causing disorganized laminin deposition and altered expression of E-cadherin and β-catenin. This led to a complete loss of undifferentiated chorionic trophoblasts after embryonic day 9.5 and prevented the formation of the placental labyrinth. Genetic ablation of matriptase activity in HAI-1-deficient embryos, however, restored the integrity of chorionic trophoblasts and enabled placental labyrinth formation and development to term. Furthermore, matriptase/HAI-1 double-deficient mice were phenotypically indistinguishable from matriptase single-deficient littermates.

Matriptase initiates activation of epidermal pro-kallikrein and disease onset in a mouse model of Netherton syndrome

Deficiency in the serine protease inhibitor LEKTI is the etiological origin of Netherton syndrome, which causes detachment of the stratum corneum and chronic inflammation. Here we show that the membrane protease matriptase initiates Netherton syndrome in a LEKTI-deficient mouse model by premature activation of a pro-kallikrein cascade. Auto-activation of pro-inflammatory pro-kallikrein-related peptidases that are associated with stratum corneum detachment was either low or undetectable, but they were efficiently activated by matriptase. Ablation of matriptase from LEKTI-deficient mice dampened inflammation, eliminated aberrant protease activity, prevented detachment of the stratum corneum, and improved the barrier function of the epidermis. These results uncover a pathogenic matriptase–pro-kallikrein pathway that could operate in several human skin and inflammatory diseases.

Autosomal ichthyosis with hypotrichosis syndrome displays low matriptase proteolytic activity and is phenocopied in ST14 hypomorphic mice

Human autosomal recessive ichthyosis with hypotrichosis (ARIH) is an inherited disorder recently linked to homozygosity for a point mutation in the ST14 gene that causes a G827R mutation in the matriptase serine protease domain (G216 in chymotrypsin numbering). Here we show that human G827R matriptase has strongly reduced proteolytic activity toward small molecule substrates, as well as toward its candidate epidermal target, prostasin. To further investigate the possible contribution of low matriptase activity to ARIH, we generated an ST14 hypomorphic mouse strain that displays a 100-fold reduction in epidermal matriptase mRNA levels. Interestingly, unlike ST14 null mice, ST14 hypomorphic mice were viable and fertile but displayed a spectrum of abnormalities that strikingly resembled ARIH. Thus, ST14 hypomorphic mice developed hyperproliferative and retention ichthyosis with impaired desquamation, hypotrichosis with brittle, thin, uneven, and sparse hair, and tooth defects. Biochemical analysis of ST14 hypomorphic epidermis revealed reduced prostasin proteolytic activation and profilaggrin proteolytic processing, compatible with a primary role of matriptase in this process. This work strongly indicates that reduced activity of a matriptase-prostasin proteolytic cascade is the etiological origin of human ARIH and provides an important mouse model for the exploration of matriptase function in ARIH, as well as multiple other physiological and pathological processes.

Co‐localization of the channel activating protease prostasin/(CAP1/PRSS8) with its candidate activator, matriptase

Prostasin (CAP1/PRSS8) is a glycosylphosphatidylinositol‐anchored membrane serine protease believed to be critical for the regulation of epithelial sodium channel (ENaC) activity. Prostasin is synthesized as an inactive zymogen that requires a site‐specific endoproteolytic cleavage to be converted to an active protease. We have recently reported that the tumor‐associated type II transmembrane serine protease, matriptase is necessary and sufficient for prostasin activation in the epidermis. In this study, the interrelationship between the two membrane serine proteases was investigated further by using enzymatic gene trapping combined with immunohistochemistry to delineate the spatial expression of matriptase and prostasin in mouse tissues. We utilized a knock‐in mouse with a promoterless β‐galactosidase marker gene inserted into the matriptase locus, as a unique tool for precise assessment of endogenous matriptase expression. The spatial expression of matriptase and prostasin in mouse tissues was delineated by combining in situ β‐galactosidase matriptase staining with immunohistochemical detection of prostasin. We report that prostasin displays a near‐ubiquitous co‐localization with its candidate activator matriptase in a variety of normal epithelial tissues. These include simple, stratified, and pseudo‐stratified epithelium of the integumentary system, digestive tract, respiratory tract, and urogenital tract. However, matriptase and prostasin expression segregates during epithelial multi‐stage carcinogenesis to eventually become localized in separate compartments of the tumor. These data suggest that a matriptase‐prostasin zymogen activation cascade may be functionally operative in multiple epithelial tissues, but matriptase promotes epithelial carcinogenesis independent of prostasin. J. Cell. Physiol. 213: 237–245, 2007.

Potent Inhibition and Global Co-localization Implicate the Transmembrane Kunitz-type Serine Protease Inhibitor Hepatocyte Growth Factor Activator Inhibitor-2 in the Regulation of Epithelial Matriptase Activity

Hepatocyte growth factor activator inhibitors (HAI)-1 and -2 are recently identified and closely related Kunitz-type transmembrane serine protease inhibitors. Whereas HAI-1 is well established as an inhibitor of the serine proteases matriptase and hepatocyte growth factor activator, the physiological targets of HAI-2 are unknown. Here we show that HAI-2 displays potent inhibitory activity toward matriptase, forms SDS-stable complexes with the serine protease, and blocks matriptase-dependent activation of its candidate physiological substrates proprostasin and cell surface-bound pro-urokinase plasminogen activator. To further explore the potential functional relationship between HAI-2 and matriptase, we generated a transgenic mouse strain with a promoterless β-galactosidase marker gene inserted into the endogenous locus encoding HAI-2 protein and performed a global high resolution mapping of the expression of HAI-2, matriptase, and HAI-1 proteins in all adult tissues. This analysis showed striking co-localization of HAI-2 with matriptase and HAI-1 in epithelial cells of all major organ systems, thus strongly supporting a role of HAI-2 as a physiological regulator of matriptase activity, possibly acting in a redundant or partially redundant manner with HAI-1. Unlike HAI-1 and matriptase, however, HAI-2 expression was also detected in non-epithelial cells of brain and lymph nodes, suggesting that HAI-2 may also be involved in inhibition of serine proteases other than matriptase.

Matriptase-dependent cell surface proteolysis in epithelial development and pathogenesis

Matriptase is an epithelial type II transmembrane serine protease with a complex modular structure and sophisticated activation mechanism. Reduced matriptase activity in mice or humans is associated with incomplete terminal differentiation of epidermis, epidermal appendages, oral epithelium, and, likely, other epithelial structures. Preliminary evidence indicates that matriptase is part of a serine protease zymogen activation cascade that regulates epithelial cell proliferation and fate. Matriptase activity must be tightly controlled in epithelial tissues by transcriptional and posttranslational mechanisms, as matriptase dysregulation can cause embryonic demise as well as malignant transformation.

Matriptase-Deficient Mice Exhibit Ichthyotic Skin with a Selective Shift in Skin Microbiota

Suppressor of tumorigenicity 14 (St14) encodes matriptase, a serine protease, which regulates processing of profilaggrin to filaggin in vivo. Here, we report that transgenic mice with 1% of wild-type St14 levels (St14(hypo/-)) display aberrant processing of profilaggrin and model human ichthyotic skin phenotypes. Scaling of the skin appears at 1 week of age with underlying epidermal acanthosis and orthohyperkeratosis as well as a CD4+ T-cell dermal infiltrate. Upregulation of antimicrobial peptides occurs when challenged by exposure to the postnatal environment. Direct genomic sequencing of bacterial 16S rRNA genes to query microbial diversity identifies a significant shift in both phylogeny and community structure between St14(hypo/-) mice and control littermates. St14(hypo/-) mice have a selective shift in resident skin microbiota with a decrease of the dominant genus of skin bacteria, Pseudomonas and an accompanying increase of Corynebacterium and Streptococcus. St14(hypo/-) mice provide early evidence that the cutaneous microbiome can be specifically altered by genetic state, which may play an important role in modulating skin disease.