Abstract
Membrane-bound proteases are essential for epidermal integrity. Human airway trypsin-like protease 4 (HAT-L4) is a type II transmembrane serine protease. Currently, its biochemical property, cellular distribution and physiological function remain unknown. Here we examined HAT-L4 expression and function in vitro and in vivo. In Western analysis, HAT-L4 expressed in transfected CHO cells appeared as a 48-kDa protein. Flow cytometry confirmed HAT-L4 expression on the cell surface with the expected membrane topology. RT-PCR and immunostaining experiments indicated that HAT-L4 was expressed in epithelial cells and exocrine glands in tissues including skin, esophagus, trachea, tongue, eye, bladder, testis and uterus. In the skin, HAT-L4 expression was abundant in keratinocytes and sebaceous glands. We generated HAT-L4 knockout mice by disrupting the Tmprss11f gene encoding HAT-L4. HAT-L4 knockout mice were viable and fertile. No defects were found in HAT-L4 knockout mice in hair growth, wound healing, water repulsion and body temperature regulation. Compared with wild-type controls, HAT-L4-deficient newborn mice had greater body fluid loss and higher mortality in a trans-epidermal body fluid loss test. In metabolic studies, HAT-L4-deficient adult mice drank water more frequently than wild-type controls did. These results indicate that HAT-L4 is important in epidermal barrier function to prevent body fluid loss.
Similar content being viewed by others
Introduction
Proteolysis is essential in biology. More than 2% of genes in the human genome encode proteolytic enzymes1, among which trypsin-like serine proteases represent a major superfamily. It is well established that trypsin-like proteases are important for many physiological processes such as food digestion, blood coagulation, wound healing, and inflammatory responses2,3. Recently, a subgroup of type II transmembrane serine proteases (TTSPs) have been identified within the trypsin superfamily4,5. All TTSPs consist of an N-terminal cytoplasmic tail, a single-span transmembrane domain and an extracellular region that contains various protein modules and a C-terminal serine protease domain. Unlike trypsin, which is a secreted protein, TTSPs are anchored on the cell surface via their transmembrane domains.
In humans, there are 17 TTSPs identified to date4. Based on their extracellular protein domain arrangements, human TTSPs can be divided into four subgroups, i.e. human airway trypsin (HAT)-like protease/differentially expressed in squamous cell carcinoma (DESC), hepsin/TMPRSS (transmembrane protease/serine), matriptase, and corin subgroups4. Many of these TTSPs have been reported to play important roles in health and disease6,7,8,9,10,11. For example, matriptase is critical for epithelial integrity and function12. Matriptase-2 is indispensable for iron metabolism13. Corin is essential for sodium homeostasis and normal blood pressure14,15. Hepsin and TMPRSS3 are important for normal hearing16,17. Defects in these TTSPs may lead to major diseases such as skin disorders18,19, congenital or inflammatory diarrheal diseases20,21,22, iron-deficiency anaemia23,24,25, hypertension26,27,28,29, and hearing loss16.
The HAT/DESC subgroup of human TTSPs has five members, i.e. HAT, DESC, TMPRSS11A, HAT-like 4 (HAT-L4) and HAT-like 5, all of which share a similar overall domain arrangement: a cytoplasmic tail of 18–28 amino acids, a transmembrane domain and an extracellular stem region containing a SEA (sea urchin sperm protein/enteropeptidase/agrin) domain and a C-terminal serine protease domain4. The genes encoding these proteases reside in tandem at human chromosome 4q13.2, suggesting that these genes may be evolved from gene duplication. To date, the functional significance of this subgroup of TTSPs remains poorly understood. HAT, for example, was identified in human airway epithelial tissues30. In biochemical and cellular studies, HAT was shown to cleave different substrates such as protease activated receptor-2, the urokinase receptor and pro-gamma-melanotropin31,32,33. In mice, however, disrupting the Tmprss11d gene encoding HAT did not reveal any detectable abnormalities in embryonic development and post-natal survival34. It is unknown if the TTSPs of the HAT/DESC subgroup are redundant or their functions are required only upon specific environmental challenges.
HAT-L4 is a TTSP of the HAT/DESC subgroup4. In PCR studies, HAT-L4 mRNA was found in tissues including skin, esophagus, tongue, testis, stomach and bladder34. The biological function of HAT-L4 has yet to be defined. In this study, we expressed and analyzed recombinant human HAT-L4 by Western blotting and flow cytometry. We also did immunohistochemistry (IHC) to examine cellular distribution of HAT-L4 expression in human tissues. Moreover, we generated and characterized the knockout (KO) mice, in which the Tmprss11f gene encoding HAT-L4 was disrupted by CRISPR/Cas9-based techniques. Our data show that HAT-L4 is expressed in epithelial cells and exocrine glands in multiple tissues including the skin and that HAT-L4 is important for epidermal barrier function to prevent body fluid loss in newborn mice.
Results
Analysis of Recombinant Human HAT-L4 Protein
Human HAT-L4 is a polypeptide of 438 amino acids4. Figure 1A shows the predicted protein domain structure of HAT-L4. We expressed a human HAT-L4 fragment, consisting of the protease domain, in Escherichia coli and purified it with affinity chromatography. In SDS-PAGE analysis, the purified HAT-L4 fragment migrated as a band of ~28 kDa (Fig. 1B). The HAT-L4 fragment was used as an immunogen to make anti-HAT-L4 monoclonal antibodies. We next expressed the full-length human HAT-L4 in Chinese hamster ovary (CHO) cells. The recombinant HAT-L4 contained a C-terminal V5 tag. In Western blotting analysis, both anti-V5 and anti-HAT-L4 antibodies recognized a dominant band of ~48 kDa in lysates from the transfected CHO cells expressing the full-length HAT-L4 protein (Fig. 1C). Such a band was not detected in control lysates from vector-transfected CHO cells. In flow cytometric analysis, both the anti-V5 and anti-HAT-L4 antibodies detected recombinant human HAT-L4 on the transfected CHO cell surface (Fig. 1D, lower panels). The results are consistent with the predicted cell membrane topology of HAT-L4 with its C-terminus located extracellularly.
HAT-L4 Expression in Human and Mouse Tissues
Previously, HAT-L4 mRNA expression was detected by RT-PCR in human and mouse tissues, including skin, tongue, esophagus, testis, placenta and cervix34. To understand cellular distributions of HAT-L4, we examined HAT-L4 protein in selected human tissues by IHC (Fig. 2). In skin sections, positive HAT-L4 staining was observed in the stratum corneum and epidermal keratinocytes (Fig. 2A) and in sebaceous (Fig. 2B) and sweat (Fig. 2C) glands. In addition, HAT-L4 staining was detected in esophageal squamous epithelial cells, tracheal cilia and submucosal glands, seminiferous epithelium, and placental chorionic villi (Fig. 2D). In contrast, HAT-L4 was not detected in the thymus (Fig. 2D). These data indicate that HAT-L4 is expressed in epithelial cells and exocrine glands in different human tissues. We next did an RT-PCR survey of HAL-L4 expression in 32 mouse tissues. HAL-L4 mRNA was detected in multiple tissues including eye, trachea, tongue, esophagus, ureter, bladder, testis, placenta, uterus, vagina and skin (Fig. 3).
Generation of Tmpress11f KO Mice
The mouse Tmprss11f gene consists of 11 exons. To generate Tmprss11f KO mice, a CRISPR/Cas9-based targeting RNA was designed to delete a 20 bp-nucleotide sequence in Tmprss11f exon 4 (Fig. 4A), which encodes amino acids 68–73 (Val-Thr-Ser-Ile-Lys-Tyr) in the extracellular SEA domain of mouse HAT-L4. The deletion is expected to shift the downstream protein coding sequence, thereby resulting in a null Tmprss11f−/− allele. The guide and targeting RNAs were injected into C57BL/6 fertilized oocytes to generate Tmprss11f+/− mice, which were bred to produce Tmprss11f+/+, Tmprss11f+/− and Tmprss11f−/− mice, as indicated by PCR genotyping with oligonucleotide primers flanking the exon 4 deletion site (Fig. 4A and B). The PCR fragments representing the Tmprss11f+/+ and Tmprss11f−/− alleles were verified by DNA sequencing to confirm the intended deletion (Fig. 4C). To examine HAT-L4 mRNA expression in WT and Tmprss11f KO mice, total RNAs were isolated from tongues, one of the tissues in which HAT-L4 mRNA expression was abundant (Fig. 3). RT-PCR detected HAT-L4 mRNA in Tmprss11f+/+ mice but not Tmprss11f−/− mice (Fig. 4D).
Embryonic Development, Post-natal Growth, Fertility and Long-term Survival of Tmprss11f KO Mice
To examine the functional importance of HAT-L4, we bred Tmprss11f+/− mice and genotyped offspring by PCR. Of 151 offspring from 18 litters genotyped at birth, 38 (25.2%) were Tmprss11f+/+, 73 (48.3%) were Tmprss11f+/− and 40 (26.5%) were Tmprss11f−/− (Fig. 5A), which was in line with the expected Mendelian ratio of inheritance. A similar Mendelian ratio was observed when the genotyping was done at the weaning (post-natal day 21). Of 168 offspring from 20 litters, 38 (22.6%) were Tmprss11f+/+, 77 (45.8%) were Tmprss11f+/− and 53 (31.6%) were Tmprss11f−/− (Fig. 5B). In mice of all three genotypes, male to female ratio was approximately 1:1. Both Tmprss11f−/− males and females were fertile and produced viable offspring. We compared litter sizes from Tmprss11f+/+ and Tmprss11f−/− females that were mated with males of the same genotype. Litter sizes were 7.6 ± 3.1 from Tmprss11f+/+ females (n = 11) and 7.2 ± 2.3 from Tmprss11f−/− females (n = 23) (P = 0.7) (Fig. 5C). Tmprss11f−/− male and female mice grew normally, as indicated by similar body weight gains to those in Tmprss11f+/+ male and female littermates (Fig. 5D and E). Tmprss11f+/+ and Tmprss11f−/− mice also had similar long-term survival rates when monitored over 600 days (Fig. 5F). These results indicate that HAT-L4 is dispensable for embryonic development, post-natal growth, fertility and long-term survival in mice.
Histological Examination and Blood Chemistry Analysis
Tmprss11f−/− mice did not exhibit apparent physical abnormalities. In 2–4-month-old Tmprss11f−/− mice, necropsies did not find gross abnormalities in major organs such as heart, liver, lung, kidney, esophagus and spleen. Histological analysis was done in tissues where HAT-L4 expression was detected, including skin, trachea, tongue, esophagus, testis and eye. Tissue morphologies in hematoxylin and eosin (H&E)-stained sections from Tmprss11f−/− mice were indistinguishable from those from Tmprss11f+/+ mice (Fig. 6). In blood chemistry analysis, values for total bilirubin, total protein, albumin, globulin, alanine aminotransferase, alkaline phosphatase, glucose and cholesterol were similar in gender-matched Tmprss11f+/+ and Tmprss11f−/− mice (data not shown). In blood cell analysis, no significant differences between Tmprss11f+/+ and Tmprss11f−/− mice were found in red blood cell, white blood cell, and platelet counts (data not shown).
Analysis of Hair Growth, Wound Healing, Water Repulsion and Thermoregulation
Membrane-bound serine proteases play important roles in skin integrity and function12,35. Like other members of the HAT/DESC subgroup, HAT-L4 is expressed in human and mouse skins (Figs 2 and 3). Histologically, no apparent differences were observed in H&E-stained sections between Tmprss11f+/+ and Tmprss11f−/− mice (Fig. 6). To test the effect of HAT-L4-deficiency on skin functions, we analyzed hair growth in Tmprss11f+/+ and Tmprss11f−/− mice. No significant difference in hair growth rates was found between the two groups of mice (Fig. 7A). Similar rates of wound healing were also observed in Tmprss11f+/+ and Tmprss11f−/− mice (Fig. 7B and C). These results indicate that HAT-L4-deficiency does not impair hair growth and wound healing in mice.
We next examined the effect of HAT-L4-deficiency on water repulsion and thermoregulation. Adult Tmprss11f+/+ and Tmprss11f−/− male mice were placed in a water tank at 30 °C. After 2 min, the mice were taken out, and hair drying rates and rectum temperature changes were monitored. Similar rates of hair drying and body temperature recovering were observed in Tmprss11f+/+ and Tmprss11f−/− mice (Fig. 7D and E), indicating that HAT-L4 is not critical for water repulsion and body temperature regulation in adult mice under our experimental conditions.
Trans-epidermal Fluid Loss and Water Drinking
The skin serves as a barrier to prevent body fluid loss. This function is particularly important in newborn mice that are prone to dehydration. In a trans-epidermal fluid loss test performed at 37 °C, Tmprss11f−/− newborn mice had more body fluid loss compared with that in Tmprss11f+/+ controls, as indicated by greater body weight decreases over a 5-h period (Fig. 8A). The dehydration caused >60% mortality in Tmprss11f−/− pups, whereas no death occurred in similarly treated Tmprss11f+/+ pups in 8 h (Fig. 8B). In histological analysis, we did not detect morphological differences in skin sections between Tmprss11f+/+ and Tmprss11f−/− pups (Fig. 8C). Stratum corneum thicknesses in the sections from Tmprss11f+/+ and Tmprss11f−/− pups were 48.6 ± 9.8 μm (n = 7) and 49.4 ± 7.9 μm (n = 8), respectively (P = 0.876). In Western analysis, major cornified envelop proteins, including loricrin, filagrrin, and keratins 1, 5, 10 and 14, from Tmprss11f+/+ and Tmprss11f−/− mice were similar in expression levels and molecular sizes (Fig. 8D). In metabolic studies, water-drinking in adult Tmprss11f−/− mice was more frequent than that in Tmprss11f+/+ controls (166.6 ± 37.9 vs. 124.4 ± 33.0 times in 5 days; P = 0.033) (Fig. 8E). The total water intake by Tmprss11f−/− mice was more than that by Tmprss11f+/+ mice (18.6 ± 6.0 vs. 15.4 ± 5.5 mL in 5 days). The difference, however, did not reach statistical significance (P = 0.282) (Fig. 8F). No significant differences in food intake, oxygen consumption and energy expenditure were found between Tmprss11f+/+ and Tmprss11f−/− mice (Supplemental Table 1). These results indicate that HAT-L4 is important in epidermal barrier function to prevent body fluid loss, especially in newborn mice.
Discussion
TTSPs are distinct members in the trypsin superfamily4,5. Increasing evidence supports the idea that TTSPs play key roles in physiological homeostasis6,10. HAT-L4 is a TTSP identified by genomic sequence analysis4. To date, its biochemical property, cellular distribution and physiological function remain unknown. In this study, we expressed and analyzed human HAT-L4 in CHO cells. In SDS-PAGE and Western blotting, recombinant HAT-L4 migrated predominantly as a band of ~48 kDa, consistent with the calculated mass of human HAT-L4 protein that lacks predicted N-glycosylation sites. The predominant single protein band on Western blots under reducing conditions indicates that HAT-L4 expressed in the CHO cells remained primarily as a one-chain zymogen. By flow cytometry, recombinant HAT-L4 protein was found on the surface of the transfected CHO cells, confirming the expected cell membrane topology of HAT-L4 as a type II transmembrane protein.
To examine HAT-L4 tissue distribution, we surveyed 32 mouse tissues by RT-PCR. HAT-L4 mRNA was detected in multiple tissues, including skin, eye, trachea, tongue, esophagus, bladder, testis, uterus and vagina. Our results are in agreement with findings of a previous study, in which HAT-L4 mRNA was identified by RT-PCR in mouse tissues such as tongue, testis, skin, and bladder34. By IHC, we found HAT-L4 protein expression in epithelial cells and exocrine glands in human tissues such as skin, esophagus, trachea, testis and placenta. In skin sections, HAT-L4 staining was positive in the stratum corneum, epidermal keratinocytes, sebaceous glands and sweat glands. To date, several TTSPs, including matriptase, HAT, TMPRSS11A, TMPRSS13 and corin, have been found in skin tissues, mostly in squamous epithelium and/or hair follicles34,36,37,38. The abundant HAT-L4 expression in sebaceous and sweat glands appears distinct among the human TTSP family members.
To determine the physiological importance of HAT-L4 in vivo, we generated HAT-L4-deficient mice by disrupting the Tmprss11f gene. The intended gene targeting was verified by PCR genotyping, DNA sequencing, and RT-PCR analysis of HAT-L4 mRNA expression. Although HAT-L4 is expressed in the testis and uterus, HAT-L4-deficient male and female mice were fertile and had similar litter sizes to that of WT mice. HAT-L4-deficient mice also had a seemingly normal lifespan. In blood chemistry analysis, all parameters tested were normal in Tmprss11f−/− mice. In necropsy and histological analysis, no abnormalities were identified in major organs from these mice. Particularly, in organs where HAT-L4 expression was detected, including skin, trachea, tongue, esophagus, testis and eye, tissue morphology was indistinguishable between Tmprss11f+/+ and Tmprss11f−/− mice. These data indicate that HAT-L4 is not essential for embryonic development, post-natal growth and long-term survival in mice.
Extracellular proteolysis mediated by membrane-bound serine proteases is critical for epidermal differentiation and maturation12,35,39,40. In mice, deficiency in matriptase, prostasin and TMPRSS13 impairs stratum corneum formation and epidermal barrier function38,39,41,42,43,44,45. Mutations in the ST14 gene encoding matriptase have been identified in patients with a skin disorder, called autosomal recessive ichthyosis with hypotrichosis18,19,46,47. In our study, we found no obvious differences between Tmprss11f+/+ and Tmprss11f−/− mice in hair color and skin histology. There were no apparent defects in hair growth and wound healing in the KO mice. Similar results of hair drying and body temperature recovery were observed in adult Tmprss11f+/+ and Tmprss11f−/− mice in a water bath test, indicating that HAT-L4 is not critical for the skin function to repel external water and regulate body temperature in adult mice.
By IHC, we found abundant HAT-L4 expression in sebaceous glands. The primary function of sebaceous glands is to produce a surface lipid layer consisting of triglycerides, wax esters, squalene, free fatty acids, and cholesterol48,49. Such a lipid layer is essential for preventing trans-epidermal body fluid loss. In histological analysis, we did not find significant differences between Tmprss11f+/+ and Tmprss11f−/− mice in sebaceous gland morphology and number. In a trans-epidermal fluid loss test performed at 37 °C, greater body fluid loss and mortality were found in Tmprss11f−/− newborn pups that had no access to milk-drinking. Previously, excessive body fluid loss was reported in matriptase-, prostasin- and TMPRSS13-deficient newborn mice that had impaired stratum corneum formation19,38,43,45. In our study, the epidermal structure was similar in Tmprss11f+/+ and Tmprss11f−/− newborn mice. Western analysis found similar expression levels of major cornified envelop proteins, including loricrin, filaggrin and keratins 1, 5, 10 and 14 in these mice. These data indicate that HAT-L4 deficiency did not significantly alter the epidermal structure. Given the abundant HAT-L4 expression in sebaceous glands, it is possible that HAT-L4 deficiency may impair sebaceous gland function, thereby compromising the epidermal barrier function to prevent body fluid loss in newborn mice in a high-temperature environment. Notably, we found no excessive loss of Tmprss11f−/− pups between the birth and weaning, indicating that the role of HAT-L4 in the epidermal barrier function is less critical in a room-temperature environment where milk-drinking is readily accessible. We also noticed in our metabolic studies that adult Tmprss11f−/− mice drank water more frequently than Tmprss11f+/+ mice did. Conceivably, more frequent water drinking may compensate the extra trans-epidermal body fluid loss caused by HAT-L4 deficiency.
In summary, our study reveals a role of HAT-L4 in the epidermal barrier function to prevent body fluid loss, providing another example of cell membrane-bound serine proteases in epidermal development and function. Currently, the molecular basis underlying the role of HAT-L4 in the epidermal barrier function remains unknown. The zymogen activation mechanism and substrate specificity of HAT-L4 have not been determined. In principle, HAT-L4 deficiency could impair sebaceous gland excretion and/or lipid composition, which may compromise the epidermal barrier function but are difficult to be detected by the methods used in this study. Our findings should encourage further investigations to understand how HAT-L4 participates in the epidermal barrier function. Such studies may provide new insights into protease-mediated pathways in skin biology and disease.
Methods
Anti-HAT-L4 Antibodies
A cDNA fragment encoding human HAT-L4 protease domain (amino acids 196–433 based on NCBI accession number NP_997290.2) was amplified from the human leukemia cell line MEG-01 by RT-PCR. The PCR fragment was sequenced and inserted into pQE30 expression vector encoding a C-terminal His tag (Qiagen). Recombinant HAT-L4 protein was expressed in Escherichia coli, purified with a Ni-NTA agarose column (GE Healthcare Life Sciences), and verified by SDS-PAGE and Coomassie blue staining. The purified HAT-L4 protein was used to immunize BALB/c mice to make monoclonal antibodies. Positive hybridoma cells were identified by ELISA using the purified recombinant HAT-L4 protein and used to produce ascites in mice. Monoclonal antibodies were purified from the ascites using a protein-G-Sepharose 4B column (GE Healthcare Life Sciences) and analyzed by Western blotting, immunostaining and flow cytometry. In Western blotting and immunohistochemical analyses, the antibodies recognized human HAT-L4 protein but not mouse HAT-L4 protein.
Transfection, Western Blotting, and Flow Cytometry
A cDNA encoding the full-length human HAT-L4 amplified from MEG-01 cells was inserted into pcDNA expression plasmid that encodes a C-terminal V5 tag. The resultant plasmid pcDNA-HAT-L4 and control pcDNA vector were transfected into CHO cells with FuGENE reagents (Roche Diagnostics). After 24 h at 37 °C, the cells were lysed in a solution containing 50 mmol/L Tris-HCl, pH 8.0, 150 mmol/L NaCl, 1% (v/v) Triton X-100 and a protease inhibitor cocktail (1:100 dilution, Sigma)50. HAT-L4 protein was analyzed by SDS-PAGE and Western blotting under reducing conditions using an anti-V5 antibody (Invitrogen) and an anti-HAT-L4 antibody described above. To analyze HAT-L4 protein on the cell surface, the transfected CHO cells were detached with EDTA and incubated with the anti-V5 and anti-HAT-L4 antibodies or mouse IgG control. After washing and incubation with a phycoerythrin-conjugated secondary antibody, the cells were analyzed by flow cytometry (FACSCalibur, BD Biosciences), as described previously51.
Immunohistochemistry
All anonymous human tissues were from a biobank from the Department of Pathology of Soochow University. The study was conducted in accordance with the Soochow University’s ethics committee guidelines. Sections were made from formalin-fixed and paraffin-embedded human tissues, de-paraffinized with xylene, and rehydrated with graded ethanol solutions. The sections were boiled in 10 mM citrate buffer (pH 6. 0) for 2 min for antigen retrieval, treated with 5% (w/v) bovine serum albumin (BSA) in phosphate buffered solution (PBS) at 37 °C for 1 h to block non-specific binding, and then incubated with an anti-HAT-L4 antibody (1:450 dilution) at 4 °C overnight. In negative controls, the primary antibody was replaced by 5% BSA. After washing with PBS, an HRP-conjugated secondary antibody was added. After incubation and washing, an HRP substrate solution containing 3, 3′-diaminobenzidine was added. The sections were examined under a light microscope (Olympus, DP73).
HAT-L4 mRNA Expression in Mouse Tissues
All animal procedures were carried out in accordance with the guidelines for the ethical treatment and handling of animals in research and approved by the Animal Care and Use Committees at the Soochow University. In RT-PCR experiments, tissues from wild-type (WT) mice (C57BL/6; 10 males and 6 females; 2 months old) were used to isolate total RNAs using the Trizol reagent (Invitrogen). The RNAs were used as templates to make cDNAs using the RevertAid First Strand cDNA Synthesis kit (Fermentas). PCR amplification of Tmprss11f transcripts was performed using forward (5′-ACC TAA AAC AAG TGT GTT CG-3′) and reverse (5′-TCG ATA CTT AGT TAC TCT GG-3′) primers in a protocol of 35 cycles with 1 min denaturation at 95 °C, 30 s annealing at 55 °C, and 30 s elongation at 72 °C. PCR products were analyzed by agarose gel electrophoresis.
Generation of Tmprss11f KO Mice
Mice with a disrupted Tmprss11f allele were generated by CRISPR/Cas9-based techniques at the Model Animal Research Center of Nanjing University, China52. Briefly, a guide RNA (gRNA) sequence targeting exon 4 of the mouse Tmprss11f gene was ligated to pUC57-T7-gRNA vector and transcribed by the MEGAshortscript kit (Ambion). The pST1374-Cas9-N-NLS-flag-linker vector was linearized by Age1 enzyme and in vitro transcribed using the T7 Ultra kit (Ambion). A mixture of the Cas9 mRNA and gRNA was injected into mouse zygotes that were cultured in Hamster Embryo Culture Medium-10 with 10% fetal bovine serum (Hyclone) at 37 °C in an incubator with 5% CO2. The cleaved embryos at two-cell to blastocyst stages were transferred into recipient mice. The offspring was genotyped by PCR with forward (5′-GTC ATG TAA ACC AAG TGT GTG ATG-3′) and reverse (5′-GAG ATA TAG ACT GCC AGC ATA GC-3′) primers. The PCR products were verified by DNA sequencing. Positive mice with the disrupted Tmprss11f gene were identified and bred with C57BL/6 mice. Heterozygous offspring was identified by PCR genotyping with the primers TMPRSS11fT85F (5′-CAA GTC ATT TTA TTA CCT CGC CTC T-3′) and TMPRSS11fT85R (5′-AAA CTC CCT TGA TGA CCT GAT TCC A-3′). The heterozygous mice were bred to produce Tmprss11f null mice and littermates for further analysis.
RT-PCR Analysis of HAT-L4 mRNA in KO Mice
Tongue tissues were collected from adult male Tmprss11f+/+ and Tmprss11f−/− mice and homogenized in Trizol reagent (Invitrogen). Total RNAs were isolated and used for RT-PCR using the forward (5′-GCC CTC GGA TTT GGT AGG C-3′) and reverse (5′-CCG TGT GTG TGA CCT TGT CT-3′) primers in 35 cycles of 1 min denaturation at 95 °C, 30 s annealing at 55 °C, and 1 min elongation at 72 °C. PCR products were analyzed by agarose gel electrophoresis.
Blood Chemistry Analysis
Blood samples were collected from 2–4 month-old male and female Tmprss11f+/+ and Tmprss11f−/− mice. Blood chemistry analysis was done at the Clinic Laboratory of the Second Affiliated Hospital of Soochow University. Blood cell counts were examined using a hematology analyzer (Siemens, ADVIA 2120i).
Histological Analysis of Mouse Tissues
Tissues from 2–4 month-old Tmprss11f+/+ and Tmprss11f−/− mice were dissected, fixed with formalin, and embedded in paraffin. Sections (5 μm in thickness) were cut and stained with H&E. Histological examination was done under a light microscope (Olympus, DP73).
Hair Growth and Wound Healing
A dorsal area was depilated in 3–4 month-old male mice. Hair growth was inspected daily and pictures were taken at days 1, 10 and 20. To study wound healing, an excisional round wound of 1 cm in diameter was created. Wound healing was inspected daily and recorded by a camera (Canon, 500D). Wound areas were analyzed using Image-Pro Plus (Media Cybernetics) and wound healing rates were calculated.
Water Repulsion Test
A water repulsion test was performed to assess the skin function in water repulsion and thermoregulation, based on a published protocol53. Briefly, 3-month-old male mice were placed in a water tank at 30 °C. After 2 min, the mice were taken out and placed on paper towels at room temperature to eliminate excessive water. Body weight and rectal temperature were measured before and after the water bathing. The water remained in hairs was calculated by comparing the body weight before and after the water bathing.
Trans-epidermal Fluid Loss Test
A trans-epidermal fluid loss test was performed in newborn mice to assess the skin barrier function to prevent excessive body fluid loss, based on a published protocol37. Briefly, <12-h-old newborn pups were taken away from their mothers and placed in a 37 °C incubator. Body weights of individual pups were measured hourly over a period of 5 h. The trans-epidermal fluid loss was calculated based on body weight decrease over time.
Water Intake
Twenty-week-old male mice were placed in a comprehensive laboratory animal monitoring system (Columbus Instruments, Oxymax) and fed a regular chow diet and drinking water ad libitum. After the mice were acclimated to the system for >24 h, water intake and drinking frequency were recorded.
Western Analysis of Skin Proteins
To analyze epidermal proteins in mice, skin tissues from newborn (<12 h old) mice were homogenized in a lysis solution38. Protein samples were analyzed by SDS-PAGE and Western blotting, as described previously51. Western blots were incubated with primary antibodies against loricrin (Abcam, ab85679), filaggrin (BioLegend, 905804), and keratins 1 (Abcam, ab185628), 5 (Abcam, ab52635), 10 (Abcam, ab76318) and 14 (Abcam, ab181595). A horseradish-peroxidase (HRP)-conjugated antibody (Shunshine Bio, SN134) was used as a secondary antibody.
Statistical Analysis
The analysis was done using the Prism 6 (GraphPad) and SPSS18 software. All data are presented as mean ± S.D. Comparisons between two groups were done using Student’s t test. χ2 test was used to examine genotype distribution among offspring from heterozygous mating. The Mantel–Cox test was used to compare long-term survival rates between WT and KO mice. A P value of <0.05 was considered to be statistically significant.
Additional Information
How to cite this article: Zhang, Z. et al. The Transmembrane Serine Protease HAT-like 4 Is Important for Epidermal Barrier Function to Prevent Body Fluid Loss. Sci. Rep. 7, 45262; doi: 10.1038/srep45262 (2017).
Publisher's note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Change history
10 April 2020
An amendment to this paper has been published and can be accessed via a link at the top of the paper.
References
Overall, C. M. & Blobel, C. P. In search of partners: linking extracellular proteases to substrates. Nat Rev Mol Cell Biol 8, 245–257 (2007).
Lopez-Otin, C. & Overall, C. M. Protease degradomics: a new challenge for proteomics. Nat Rev Mol Cell Biol 3, 509–519 (2002).
Neurath, H. Evolution of proteolytic enzymes. Science 224, 350–357 (1984).
Bugge, T. H., Antalis, T. M. & Wu, Q. Type II transmembrane serine proteases. J Biol Chem 284, 23177–23181 (2009).
Hooper, J. D., Clements, J. A., Quigley, J. P. & Antalis, T. M. Type II transmembrane serine proteases. Insights into an emerging class of cell surface proteolytic enzymes. J Biol Chem 276, 857–860. (2001).
Antalis, T. M., Bugge, T. H. & Wu, Q. Membrane-anchored serine proteases in health and disease. Prog Mol Biol Transl Sci 99, 1–50 (2011).
Antalis, T. M., Buzza, M. S., Hodge, K. M., Hooper, J. D. & Netzel-Arnett, S. The cutting edge: membrane-anchored serine protease activities in the pericellular microenvironment. Biochem J 428, 325–346 (2010).
Choi, S. Y., Bertram, S., Glowacka, I., Park, Y. W. & Pohlmann, S. Type II transmembrane serine proteases in cancer and viral infections. Trends Mol Med 15, 303–312 (2009).
Murray, A. S., Varela, F. A. & List, K. Type II transmembrane serine proteases as potential targets for cancer therapy. Biol Chem(2016).
Szabo, R. & Bugge, T. H. Membrane-anchored serine proteases in vertebrate cell and developmental biology. Annu Rev Cell Dev Biol 27, 213–235 (2011).
Webb, S. L., Sanders, A. J., Mason, M. D. & Jiang, W. G. Type II transmembrane serine protease (TTSP) deregulation in cancer. Front Biosci (Landmark Ed) 16, 539–552 (2011).
Miller, G. S. & List, K. The matriptase-prostasin proteolytic cascade in epithelial development and pathology. Cell Tissue Res 351, 245–253 (2013).
Ramsay, A. J., Hooper, J. D., Folgueras, A. R., Velasco, G. & Lopez-Otin, C. Matriptase-2 (TMPRSS6): a proteolytic regulator of iron homeostasis. Haematologica 94, 840–849 (2009).
Wang, W. et al. Impaired sodium excretion and salt-sensitive hypertension in corin-deficient mice. Kidney Int 82, 26–33 (2012).
Zhou, Y. & Wu, Q. Corin in natriuretic peptide processing and hypertension. Curr Hypertens Rep 16, 415 (2014).
Guipponi, M., Antonarakis, S. E. & Scott, H. S. TMPRSS3, a type II transmembrane serine protease mutated in non-syndromic autosomal recessive deafness. Front Biosci 13, 1557–1567 (2008).
Guipponi, M. et al. Mice deficient for the type II transmembrane serine protease, TMPRSS1/hepsin, exhibit profound hearing loss. Am J Pathol 171, 608–616 (2007).
Basel-Vanagaite, L. et al. Autosomal recessive ichthyosis with hypotrichosis caused by a mutation in ST14, encoding type II transmembrane serine protease matriptase. Am J Hum Genet 80, 467–477 (2007).
List, K. et al. Autosomal ichthyosis with hypotrichosis syndrome displays low matriptase proteolytic activity and is phenocopied in ST14 hypomorphic mice. J Biol Chem 282, 36714–36723 (2007).
Buzza, M. S. et al. Membrane-anchored serine protease matriptase regulates epithelial barrier formation and permeability in the intestine. Proc Natl Acad Sci USA 107, 4200–4205 (2010).
Netzel-Arnett, S. et al. Matriptase protects against experimental colitis and promotes intestinal barrier recovery. Inflamm Bowel Dis 18, 1303–1314 (2012).
Wu, C. J., Feng, X., Lu, M., Morimura, S. & Udey, M. C. Matriptase-mediated cleavage of EpCAM destabilizes claudins and dysregulates intestinal epithelial homeostasis. J Clin Invest 127, 623–634 (2017).
Cui, Y., Wu, Q. & Zhou, Y. Iron-refractory iron deficiency anemia: new molecular mechanisms. Kidney Int 76, 1137–1141 (2009).
Du, X. et al. The serine protease TMPRSS6 is required to sense iron deficiency. Science 320, 1088–1092 (2008).
Finberg, K. E. et al. Mutations in TMPRSS6 cause iron-refractory iron deficiency anemia (IRIDA). Nat Genet 40, 569–571 (2008).
Chen, S. et al. PCSK6-mediated corin activation is essential for normal blood pressure. Nat Med 21, 1048–1053 (2015).
Cui, Y. et al. Role of corin in trophoblast invasion and uterine spiral artery remodelling in pregnancy. Nature 484, 246–250 (2012).
Dong, N. et al. Corin mutation R539C from hypertensive patients impairs zymogen activation and generates an inactive alternative ectodomain fragment. J Biol Chem 288, 7867–7874 (2013).
Dong, N. et al. Corin mutations K317E and S472G from preeclamptic patients alter zymogen activation and cell surface targeting. J Biol Chem 289, 17909–17916 (2014).
Yamaoka, K. et al. Cloning and characterization of the cDNA for human airway trypsin-like protease. J Biol Chem 273, 11895–11901 (1998).
Beaufort, N. et al. The human airway trypsin-like protease modulates the urokinase receptor (uPAR, CD87) structure and functions. Am J Physiol Lung Cell Mol Physiol 292, L1263–1272 (2007).
Hansen, I. A. et al. The adrenal secretory serine protease AsP is a short secretory isoform of the transmembrane airway trypsin-like protease. Endocrinology 145, 1898–1905 (2004).
Matsushima, R. et al. Human airway trypsin-like protease stimulates human bronchial fibroblast proliferation in a protease-activated receptor-2-dependent pathway. Am J Physiol Lung Cell Mol Physiol 290, L385–395 (2006).
Sales, K. U. et al. Expression and genetic loss of function analysis of the HAT/DESC cluster proteases TMPRSS11A and HAT. PLoS One 6, e23261 (2011).
Ovaere, P., Lippens, S., Vandenabeele, P. & Declercq, W. The emerging roles of serine protease cascades in the epidermis. Trends Biochem Sci 34, 453–463 (2009).
Enshell-Seijffers, D., Lindon, C. & Morgan, B. A. The serine protease Corin is a novel modifier of the Agouti pathway. Development 135, 217–225 (2008).
List, K. et al. Matriptase/MT-SP1 is required for postnatal survival, epidermal barrier function, hair follicle development, and thymic homeostasis. Oncogene 21, 3765–3779 (2002).
Madsen, D. H., Szabo, R., Molinolo, A. A. & Bugge, T. H. TMPRSS13 deficiency impairs stratum corneum formation and epidermal barrier acquisition. Biochem J 461, 487–495 (2014).
Frateschi, S. et al. PAR2 absence completely rescues inflammation and ichthyosis caused by altered CAP1/Prss8 expression in mouse skin. Nat Commun 2, 161 (2011).
Zeeuwen, P. L. Epidermal differentiation: the role of proteases and their inhibitors. Eur J Cell Biol 83, 761–773 (2004).
Chen, L. M. et al. Prostasin is a glycosylphosphatidylinositol-anchored active serine protease. J Biol Chem 276, 21434–21442 (2001).
Frateschi, S. et al. Mutations of the serine protease CAP1/Prss8 lead to reduced embryonic viability, skin defects, and decreased ENaC activity. Am J Pathol 181, 605–615 (2012).
Leyvraz, C. et al. The epidermal barrier function is dependent on the serine protease CAP1/Prss8. J Cell Biol 170, 487–496 (2005).
Netzel-Arnett, S. et al. Evidence for a matriptase-prostasin proteolytic cascade regulating terminal epidermal differentiation. J Biol Chem 281, 32941–32945 (2006).
Peters, D. E. et al. The membrane-anchored serine protease prostasin (CAP1/PRSS8) supports epidermal development and postnatal homeostasis independent of its enzymatic activity. J Biol Chem 289, 14740–14749 (2014).
Avrahami, L. et al. Autosomal recessive ichthyosis with hypotrichosis syndrome: further delineation of the phenotype. Clin Genet 74, 47–53 (2008).
Desilets, A. et al. Mutation G827R in matriptase causing autosomal recessive ichthyosis with hypotrichosis yields an inactive protease. J Biol Chem 283, 10535–10542 (2008).
Shi, V. Y. et al. Role of sebaceous glands in inflammatory dermatoses. J Am Acad Dermatol 73, 856–863 (2015).
Thody, A. J. & Shuster, S. Control and function of sebaceous glands. Physiol Rev 69, 383–416 (1989).
Zhang, Y. et al. A corin variant identified in hypertensive patients that alters cytoplasmic tail and reduces cell surface expression and activity. Sci Rep 4, 7378 (2014).
Qi, X., Jiang, J., Zhu, M. & Wu, Q. Human corin isoforms with different cytoplasmic tails that alter cell surface targeting. J Biol Chem 286, 20963–20969 (2011).
Niu, Y. et al. Generation of gene-modified cynomolgus monkey via Cas9/RNA-mediated gene targeting in one-cell embryos. Cell 156, 836–843 (2014).
Westerberg, R. et al. Role for ELOVL3 and fatty acid chain length in development of hair and skin function. J Biol Chem 279, 5621–5629 (2004).
Acknowledgements
We thank Zegen Wang, Ce Zhang, Can Wang, Zhuqiu Zhang, Wenjuan Wu and Jingwen Zhu for helping with experiments. This work was supported in part by grants from the National Natural Science Foundation of China (91639116, 81671485, 81370718, 81301844 and 31500636) and the Priority Academic Program Development of Jiangsu Higher Education Institutions.
Author information
Authors and Affiliations
Contributions
Z.Z., Y.H., R.Y., N.D. and Q.W. conceived and designed the experiments. Z.Z., Y.H., R.Y., L.D., Y.J., Z. Zhou, M.L. and T.Z. performed the experiments. Z.Z., Y.H., R.Y., L.D., Z. Zhou, M.L., T.Z., N.D. and Q.W. analyzed the data. Z.Z., N.D. and Q.W. wrote the paper. All authors reviewed and commented on the manuscript.
Corresponding authors
Ethics declarations
Competing interests
The authors declare no competing financial interests.
Supplementary information
Rights and permissions
This work is licensed under a Creative Commons Attribution 4.0 International License. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in the credit line; if the material is not included under the Creative Commons license, users will need to obtain permission from the license holder to reproduce the material. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/
About this article
Cite this article
Zhang, Z., Hu, Y., Yan, R. et al. The Transmembrane Serine Protease HAT-like 4 Is Important for Epidermal Barrier Function to Prevent Body Fluid Loss. Sci Rep 7, 45262 (2017). https://doi.org/10.1038/srep45262
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/srep45262
Comments
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.