Journal of Histochemistry and Cytochemistry, Vol. 46, 437-448, April 1998, Copyright © 1998, The Histochemical Society, Inc.


ARTICLE

Human TIMP-3 Is Expressed During Fetal Development, Hair Growth Cycle, and Cancer Progression

Kristiina Airolaa,b, Matti Ahonend, Nina Johanssond, Päivi Heikkiläc, Juha Kereb, Veli-Matti Kähärid, and Ulpu K. Saarialho–Kerea,b
a Department of Dermatology, Helsinki University Central Hospital, Helsinki, Finland
b Departments of Medical Genetics, Haartman Institute, University of Helsinki, Helsinki, Finland
c Pathology, Haartman Institute, University of Helsinki, Helsinki, Finland
d Department of Dermatology, Turku University Central Hospital, and Department of Medical Biochemistry and Medicity Research Laboratory, University of Turku, Turku, Finland

Correspondence to: Ulpu K. Saarialho–Kere, Dept. of Dermatology, Helsinki U. Central Hospital, Meilahdentie 2, 00250 Helsinki, Finland.


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We studied the expression and regulation of TIMP-3, a recently cloned member of the tissue inhibitor of the metalloproteinase family, during human fetal development and in various human tissues, with emphasis on epithelial structures. Expression of TIMP-3 mRNA was detected by in situ hybridization in developing bone, kidney, and various mesenchymal structures. At 16 weeks of gestation, ectoderm-derived cells of hair germs expressed TIMP-3 mRNA, and beginning from the twentieth week consistent expression was detected in epithelial outer root sheath cells of growing hair follicles. In normal adult human skin, expression of TIMP-3 mRNA was limited to hair follicles, starting at the early anagen (growing) phase and vanishing at the catagen (regressing) phase. TIMP-3 mRNA was not detected in benign hair follicle-derived tumors but was present in tumor cells of infiltrative basal cell carcinomas and in surrounding stromal cells in squamous cell carcinomas. Human primary keratinocytes in culture expressed TIMP-3 mRNAs, the levels of which were upregulated by transforming growth factor-ß (TGF-ß), whereas interleukin-1ß (IL-1ß) and tumor necrosis factor-{alpha} (TNF-{alpha}) had no effect. Our results suggest a role for TIMP-3 in connective tissue remodeling during fetal development, hair growth cycle, and cancer progression. (J Histochem Cytochem 46:437–447, 1998)

Key Words: carcinogenesis, extracellular matrix, hair, TGF-ß


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THE MATRIX metalloproteinases (MMPs, matrixins) are a family of structurally related neutral proteinases involved in the remodeling of extracellular matrix (ECM) in processes such as fetal development, wound healing, inflammation, and tumor invasion (Birkedal-Hansen 1995 ). These enzymes have overlapping specificities, being able to degrade important ECM macromolecules such as different types of collagens, laminin, proteoglycans, elastin, and fibronectin (Woessner 1991 ). The activity of metalloproteinases is regulated at several levels, including gene transcription, activation of secreted proenzymes, and inhibition by a class of natural inhibitors called TIMPs (tissue inhibitors of metalloproteinases). TIMPs are secreted proteins that inhibit MMPs by binding to their active site in a 1:1 stoichiometric ratio. Recently, two new members of the TIMP family have been cloned: TIMP-3 (Apte et al. 1994b ; Silbiger et al. 1994 ; Uria et al. 1994 ) and TIMP-4 (Greene et al. 1996 ; Leco et al. 1997 ). TIMP-3 shares an identity of 39% to TIMP-1, 46% to TIMP-2, and 45% to TIMP-4 in amino acid sequence (Silbiger et al. 1994 ; Leco et al. 1997 ), and inhibits interstitial collagenase (MMP-1), collagenase-3 (MMP-13), stromelysin-1 (MMP-3), 72-kD and 92-kD gelatinases (MMP-2 and -9), and membrane Type 1 MMP (MMP-14) (Apte et al. 1995 ; Knauper et al. 1996 ; Will et al. 1996 ). Instead of being soluble like TIMP-1 and -2, it is tightly bound to the extracellular matrix and has a distinctive pattern of expression compared to the other TIMPs (Leco et al. 1994 ).

TIMP-3 mRNA was first detected in human breast tumors (Uria et al. 1994 ), in metastatic melanoma cell lines (Silbiger et al. 1994 ), and in various normal adult tissues such as placenta, kidney, heart, prostate, small intestine, and lung, and in fetal tissues including heart, lung, and kidney by Northern blot hybridization (Apte et al. 1994b ; Wick et al. 1994 ; Wilde et al. 1994 ). With in situ hybridization, expression of murine TIMP-3 mRNA has been reported during mouse embryo implantation (Harvey et al. 1995 ; Reponen et al. 1995 ; Alexander et al. 1996 ; Leco et al. 1996 ) and in developing kidney, cartilage, and various epithelial structures, including epidermis and intestinal mucosa (Apte et al. 1994a ). Little is known, however, about the role of TIMP-3 in human tissues in vivo, because expression of TIMP-3 mRNA has only been localized to cells of early placental structures (Byrne et al. 1995 ; Higuchi et al. 1995 ; Hurskainen et al. 1996 ), fetal retinal epithelium (Ruiz et al. 1996 ), and fibroblastic cells within breast cancer stroma (Byrne et al. 1995 ). Furthermore, TIMP-3 protein has been found to be an extracellular matrix component of Bruch's membrane of the human eye (Fariss et al. 1997 ).

TIMP-3 is induced in response to mitogenic stimulation and is regulated during normal cell cycle progression (Wick et al. 1994 ). A potential role for TIMP-3 in carcinogenesis has been proposed. Chicken TIMP-3 promotes oncogenic transformation in cultured cells (Yang and Hawkes 1992 ), and TIMP-3 overexpression inhibits human colon carcinoma growth in vivo (Bian et al. 1996 ). A direct implication for a human disease is the presence of point mutations in the TIMP-3 gene in patients with Sorsby's fundic dystrophy, an autosomal dominant disorder leading to visual loss (Weber et al. 1994 ).

To explore the physiological role of TIMP-3 in human tissues, we have determined its spatial and temporal expression during fetal development. We have also examined its expression in adult skin and various organs of the body, with special emphasis on epithelial components based on previous data on mouse tissues (Apte et al. 1994a ). We report here that in early human fetus TIMP-3 is expressed in cartilage, bone, kidney, and in mesenchymal cells within the connective tissue. At 16 weeks of gestation, ectoderm-derived cells of hair germs express TIMP-3 mRNA, and beginning from the twentieth week consistent expression is detected in epithelial outer root sheath cells of growing hair follicles. In fully developed follicles, expression of TIMP-3 mRNA is cyclic, starting at the early anagen (growing) phase and vanishing at the catagen (regressing) phase. TIMP-3 mRNA is not detected in benign hair follicle-derived tumors but is present in tumor cells of infiltrative basal cell carcinomas and in surrounding stromal cells in squamous cell carcinomas. In vitro TIMP-3 gene expression in primary human epidermal keratinocytes is induced by TGF-ß, but not by IL-1ß or TNF-{alpha}. Our results substantiate the role of TIMP-3 in development, hair growth cycle, and tumor growth.


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Tissues
Formalin-fixed, paraffin-embedded specimens were obtained from the Departments of Dermatology and Pathology, University of Helsinki, Finland. All fetal material originated from medical abortions and was obtained from the Department of Pathology, University of Oulu, Finland. Fetal age was estimated by menstrual age and histological examination. This study was approved by the ethics committee of the Department of Dermatology, Helsinki, Finland. The following subgroups of histological sections were examined.

  1. Fetal tissues: complete fetus at gestational age of 7, 8–9, 10, and 12 weeks and biopsies of the scalp and trunk skin at gestational age of 16, 20, 21, and 23 weeks.

  2. Adult skin specimens: basal cell carcinoma n = 8 (infiltrative n = 5, keratotic n = 3), squamous cell carcinoma n = 5, trichofolliculoma n = 4, trichoepithelioma n = 4, blistering skin diseases n = 11 (dermatitis herpetiformis n = 5, pemphigus n = 2, pemphigoid n = 2, epidermolysis bullosa n = 2), and normal skin from various parts of the body n = 9.

  3. Various organs with epithelial components displaying normal histology: kidney n = 3, liver n = 3, pancreas n = 3, parotic gland n = 3, prostatic gland n = 3, mammary gland n = 3, testis n = 3, bronchus n = 3, normal gastric mucosa n = 3, normal duodenal mucosa n = 3, and normal colon mucosa n = 3.

  4. Carcinoma ductale mammae n = 4 and carcinoma adenomatosum coli n = 6.

Probes
A 518-BP fragment corresponding to positions 382–900 from the 5' end of the human TIMP-3 cDNA (Silbiger et al. 1994 ) was generated by PCR from a fetal cDNA library and was designed with a T7 RNA polymerase promoter at the 3' end and an SP6 RNA polymerase promoter at the 5' end. Probe transcribed from TIMP-3 cDNA in sense orientation was used as a control for nonspecific hybridization. For control purposes, another TIMP-3 cDNA fragment (positions 282–917) was generated with RT-PCR using the Gene Amp RNA PCR kit (Perkin–Elmer/Roche; Branchburg, NJ). Total cellular RNA from cultured normal human skin fibroblasts was used as template (manuscript in preparation) and the fragment was subcloned to pBluescript (Stratagene; La Jolla, CA). The production and specificity of the TIMP-1 RNA probe have been described (Sudbeck et al. 1992 ). By FASTA alignment, highest similarities between the TIMP-3 probes and TIMP-1 and -2 were 53–55% making cross-hybridization at high stringency unlikely.

In Situ Hybridization
In vitro transcribed anti-sense and sense RNA probes were labeled with {alpha}[35S]-UTP. Sections were hybridized with probes (2.5–4 x 104 cpm/µl of hybridization buffer) and were washed under stringent conditions, including treatment with RNase A, as described (Saarialho-Kere et al. 1993 ). After autoradiography for 10–35 days, the photographic emulsion was developed and the slides were stained with hematoxylin and eosin. Samples of breast carcinomas were used as positive controls (Uria et al. 1994 ). Each sample was hybridized in at least two experiments, and a sense probe was used as a negative control. The slides were independently analyzed by two investigators.

Keratinocyte Cultures
Primary cultures of normal human epidermal keratinocytes were established from skin specimens from a woman undergoing mammoplasty for nonmalignant disease, as described previously (Boyce and Ham 1985 ). The cells were maintained in Keratinocyte Growth Medium (Clonetics; San Diego, CA) supplemented with epidermal growth factor (0.2 ng/ml) and bovine pituitary extract (30 µg/ml) (both from Life Technologies; Paisley, UK). Cells were incubated for 24 hr with human recombinant IL-1ß (5 U/ml), TNF-{alpha} (20 ng/ml) (both from Boehringer Mannheim; Mannheim, Germany) and bovine TGF-ß2 (5 ng/ml) (kindly provided by Dr. David R. Olsen, Celtrix Co., Santa Clara, CA).

HaCaT cells, transformed human epidermal keratinocytes (obtained from Dr. Norbert Fusenig, DKFZ, Heidelberg, Germany) (Boukamp et al. 1988 ), were cultivated in Dulbecco's modified Eagle's medium (DMEM) containing 10% fetal calf serum. At confluence, cells were washed twice with PBS and incubated under serum-free conditions for 18–20 hr, followed by incubation with 5–50 ng/ml EGF (epidermal growth factor), 1–100 nM PMA (phorbol myristate acetate) (both from Sigma Chemical; St Louis, MO), or 0.1–10 ng/ml TGF-ß1 (R & D Systems; Minneapolis, MN) for 6 hr.

RNA Analysis
Total cellular RNA was isolated from primary keratinocyte cultures using the guanidine thiocyanate–cesium chloride method (Chirgwin et al. 1979 ), and from HaCaT cells using the guanidine thiocyanate–phenol–chloroform extraction (Parks et al. 1988 ). Fifteen µg of RNA was fractionated on formaldehyde–agarose gel and transferred to nylon membranes. Northern blot hybridizations were performed as described previously (Thomas 1980 ) with cDNAs labeled with [{alpha}-32P]-dCTP using random priming and [32P]-cDNA–mRNA hybrids were visualized by autoradiography. The mRNA levels were quantitated by densitometric scanning of the X-ray films on gray scale with background subtraction using MCID software (Imaging Research; St Catharines, Ontario, Canada), and corrected for the levels of rRNA visualized by ethidium bromide staining.


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TIMP-3 mRNA Is Expressed in Fetal Kidney, Cartilage, Bone, and Mesenchyme
The youngest fetal sample studied was an embryo 7 weeks of age whose main organ systems had developed. Epidermis, seen as a single layer of cells, showed no signal for TIMP-3 mRNA, but expression was detected in neuroepithelium (data not shown), in developing kidney, and in the adjacent gonadal ridge (Figure 1A, Figure 1B, and Figure 1D), and in cells within mesenchymal tissues (data not shown). Developing bone, heart, liver, and lungs, as well as bronchial epithelium, remained negative. At 8–9 weeks of gestation, chondrocytes of hand and foot plate cartilages (Figure 2A and Figure 2B) and vertebral bodies (data not shown) expressed TIMP-3 mRNA. In other organs the distribution of TIMP-3 mRNA remained the same. At 10 weeks, signal was again detected in chondrocytes of ribs and limbs, and surrounding mesenchymal cells were positive (data not shown). At 12 weeks of gestation, expression of TIMP-3 mRNA was seen in hypertrophic chondrocytes of developing ribs and in surrounding mesenchymal cells that become osteoblasts (Figure 2C and Figure 2D). In the same sample, bones that were already undergoing ossification had TIMP-3-expressing osteoblasts within the newly formed bone matrix (data not shown). Unlike in mouse embryos (Apte et al. 1994a ), TIMP-3 mRNA was not detected in developing epidermis or in the epithelium of gastrointestinal tract or bronchial trees (data not shown).



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Figure 1. Expression of TIMP-3 mRNA in fetal and adult kidney. Samples were hybridized with TIMP-3 cRNA antisense (A,B,D–F) or TIMP-3 sense (C) probe as described in Materials and Methods. (A) Darkfield image of embryonal kidney (K) and gonadal ridge (GD) at 7 weeks of gestation. TIMP-3 mRNA is detected in cells of developing kidney (arrows) and gonadal ridge (small arrows). (B) Corresponding brightfield image. (C) A sense control. (D) High-power image of TIMP-3 mRNA in cells of developing kidney (arrows). In adult kidney, cortex expression of TIMP-3 mRNA is detected in both glomeruli and tubules, as seen in darkfield (E) and high power brightfield (F) images. Glomerular cells (arrows) and tubule epithelial cells (small arrows) express TIMP-3 mRNA. Bars: AE = 34 µm; D,F = 8 µm.



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Figure 2. Fetal hypertrophic chondrocytes express TIMP-3, but not TIMP-1 mRNA. Samples were hybridized with TIMP-3 (A–D) and TIMP-1 (E,F) anti-sense probes. (A,B) A sample of a fetus at 8–9 weeks of gestation with TIMP-3-expressing chondrocytes of foot plates. (C,D) Expression of TIMP-3 mRNA in a developing rib at 12 weeks. Both hypertrophic chondrocytes (arrows) and mesenchymal cells (small arrows) that became osteoblasts express TIMP-3 mRNA. (E,F) TIMP-1 expression is limited to the mesenchymal cells (small arrows). A, C, and E are darkfield images. Bars: A,C,E = 34 µm; B,D,F = 17 µm.

At 7 and 8–9 weeks of gestation, no expression of TIMP-1 mRNA was detected. However, at 12 weeks mesenchymal cells surrounding hypertrophic cartilage (Figure 2E and Figure 2F) were positive. In addition, osteoblasts within the bone matrix showed intense signal, as described earlier (Nomura et al. 1989 ). Chondrocytes remained negative.

Outer Root Sheath Cells of Hair Follicles Express TIMP-3 mRNA at the Anagen Phase
Biopsies of armpit and scalp skin at 16 weeks of gestation showed hair germs and early hair buds penetrating the underlying dermis. Epidermis was devoid of signal, but epithelial cells of the hair germs showed expression of TIMP-3 mRNA (Figure 3A, Inset a). By 20 weeks, follicles of the scalp showed established morphology, with epithelial cells forming the outer root sheath and mesenchymal cells forming the dermal papilla. Cells of the outer root sheath were consistently positive for TIMP-3 mRNA (Figure 3B, Inset b). In trunk skin, signal was again detected in hair germs and buds, and some follicles already in a more advanced stage of development showed signal in the outer root sheath cells (data not shown). In skin biopsies at 21 and 23 weeks of gestation, outer root sheath cells of each follicle were positive for TIMP-3 mRNA in the biopsies of both scalp and trunk (data not shown).



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Figure 3. TIMP-3 is expressed during the hair growth cycle. In situ hybridizations with TIMP-3 (A–C, Inset d) and TIMP-1 anti-sense probe (D) were performed as described in Materials and Methods. (A) Skin of a fetus at 16 weeks of gestation shows expression of TIMP-3 mRNA in the epithelial cells of a hair germ (Inset a). (B) At 20 weeks of gestation, fetal scalp has many structurally complete hair follicles. Expression of TIMP-3 is detected in the outer root sheath cells of epidermal origin (arrows). Lower magnification shows a brightfield image of fetal scalp (Inset b). (C, Inset c) Outer root sheath cells of adult anagen hair follicles express TIMP-3 mRNA consistently. A few pale-staining cells in the middle of the hair matrix are also positive for TIMP-3 (arrows). (D) TIMP-1 mRNA is occasionally detected in outer root sheath cells (arrows) of anagen follicles. (Inset d) Lower magnification of adult scalp. A–D are darkfield images. Bars: A = 17 µm; BD = 34 µm; a,c = 8 µm; b,d = 170 µm.

In adult hair follicles, TIMP-3 gene was activated during the early anagen (growing) phase and the expression persisted until the follicle entered the catagen phase and started to regress. TIMP-3 mRNA localized mainly to basal cell layer of the outer root sheath in the lower portion of the follicle (Figure 3C, Inset c). In some anagen follicles, a few pale-staining medulla cells within the hair matrix were also positive (Figure 3C). No expression was seen in telogen (resting) follicles (data not shown).

TIMP-3 was not upregulated during re-epithelialization of blistering skin diseases, and expression was not detected in normal epidermis or in sebaceous and sweat glands. However, expression was often seen in fibroblast-like stromal cells surrounding sweat glands and some blood vessels (data not shown). TIMP-1 mRNA was commonly detected in sebaceous glands and in perivascular cells (data not shown) but only occasionally in some outer root sheath cells of anagen hair follicles (Figure 3D). Expression was not detected in fetal hair follicles.

TIMP-3 Expression Is Induced by TGF-ß in Primary Human Keratinocytes
Because TIMP-3 was expressed in hair follicles, we studied its expression in keratinocytes treated with various growth factors known to influence hair growth cycle. Primary human epidermal keratinocytes were treated with TGF-ß2, IL-1ß, and TNF-{alpha}, and levels of TIMP-3 mRNAs were assayed by Northern blot hybridizations. As shown in Figure 4, epidermal keratinocytes expressed clearly detectable levels of three distinct TIMP-3 mRNAs (2.4, 2.8, and 4.8 KB), and the TIMP-1 probe detected a single 0.9-KB mRNA. Interestingly, treatment of epidermal keratinocytes with TGF-ß2 (5 ng/ml) markedly (4.3-fold) enhanced TIMP-3 mRNA abundance in these cells. In contrast, IL-1ß (5 U/ml) and TNF-{alpha} (20 ng/ml) had no marked effect (Figure 4). It has previously been shown that epidermal keratinocytes in culture express TIMP-1 (Petersen et al. 1992 ). However, none of the treatments markedly altered the levels of TIMP-1 mRNA (Figure 4). HaCaT cells, transformed human epidermal keratinocytes, expressed basally low levels of TIMP-3 mRNA. Treatment with EGF, PMA, or TGF-ß1 did not alter the levels of TIMP-3 mRNA (data not shown).



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Figure 4. Expression of TIMP-3 mRNAs in epidermal keratinocytes is enhanced by TGF-ß. Human primary epidermal keratinocytes were maintained as described in Materials and Methods and treated for 24 h with IL-1ß (5 U/ml), TNF-{alpha} (20 ng/ml), and TGF-ß2 (5 ng/ml). TIMP-1 and -3 mRNA levels were examined by Northern blot hybridizations of 15 µg of total RNA, and 18S and 28S rRNAs were visualized by ethidium bromide staining. IL-1ß and TNF-{alpha} had no marked effect on TIMP-3 mRNA expression, whereas TGF-ß2 induced the expression by 4.3-fold. None of these cytokines markedly altered TIMP-1 mRNA levels.

TIMP-3 Is Expressed in Cancer Tissues
To determine whether TIMP-3 also plays a role in the behavior of benign and malignant skin tumors, samples of hair follicle-derived tumors, trichofolliculomas and trichoepitheliomas, and epidermal skin cancers were examined. Interestingly, no signal for TIMP-3 mRNA was detected in the benign tumors (data not shown). Basal cell carcinomas with keratotic (hair-like) differentiation were also negative, whereas in four of five infiltrative basal cell carcinomas TIMP-3 mRNA was detected in tumor cells at the margins of this aggressively growing tumor. In these samples, TIMP-3 mRNA was also detected in areas showing nodular tumor growth (Figure 5A, Inset a) but not in stromal cells. In squamous cell carcinomas, all of which were well- or rather well-differentiated, some stromal cells located diffusively adjacent to the tumor expressed TIMP-3 mRNA (Figure 5C and Figure 5D, Inset c), while malignant cells were negative. There was no correlation between the number of cells expressing TIMP-3 mRNA and the histopathology of the tumor. As in the samples representing normal skin, TIMP-3 mRNA was present in fibroblast-like cells surrounding sweat glands deeper in the dermis.



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Figure 5. Expression of TIMP-3 mRNA in malignant tumor tissues. Samples were hybridized with TIMP-3 anti-sense and sense probes as described. (A,a) A basal cell carcinoma. Tumor cells at the margins of tumor nodules express TIMP-3 mRNA. No expression is detected in stromal cells. (B) Serial section hybridized with a sense probe. (C) Edge of a well-differentiated squamous cell carcinoma of the skin. (c) Lower magnification of the tumor. (D) TIMP-3 mRNA is not expressed by tumor cells but by fibroblastic stromal cells adjacent to the tumor. (E,F) Intraductal mammary carcinoma. TIMP-3 mRNA is expressed by myoepithelial cells (arrows) surrounding tumor cells and by some adjacent fibroblasts (small arrow). A, B, and E are darkfield images. Bars: AC = 34 µm; a,DF = 17 µm; c = 170 µm.

Normal gastrointestinal mucosa and mammary gland showed no signal for TIMP-3 mRNA. However, in samples of colon carcinoma intense expression was detected in both macrophages and spindle-like fibroblasts adjacent to the tumor tissue (data not shown). In agreement with the results of Byrne et al. 1995 , myoepithelial cells as well as some fibroblasts surrounding tumor nodules of intraductal mammary carcinoma consistently expressed TIMP-3, whereas tumor cells remained negative (Figure 5E and Figure 5F). In both colon and mammary carcinomas expression of TIMP-1 co-localized with that of TIMP-3 (data not shown).

Constitutive expression of TIMP-3 mRNA was also studied in some other organs with epithelial structures. In normal adult kidney, tubule epithelial and glomerular cells expressed TIMP-3 mRNA (Figure 1E and Figure 1F). However, the glandular epithelia of liver, pancreas, parotid gland, testis, and prostate were negative. In addition, bronchial epithelium and adult bronchial cartilage were devoid of signal. The abundance of mRNA in Northern blot hybridizations of these organs (Apte et al. 1994b ; Wick et al. 1994 ; Wilde et al. 1994 ) can be explained by the presence of various amounts of TIMP-3-expressing stromal cells, especially if any inflammation is present.


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The controlled physiological degradation of the ECM requires a fine balance between MMPs and their inhibitors, whereas in processes such as arthritis and tumor invasion MMP activity predominates, leading to excessive tissue degradation. There are accumulating data on the role of TIMPs and synthetic MMP inhibitors in suppressing tumor growth and invasion. Additional functions independent of metalloproteinase inhibitory activity have also been reported: TIMP-1 and -2 are anti-angiogenic (Moses et al. 1990 ; Johnson et al. 1994 ) and they possess growth-promoting activity towards a number of cell types (Hayakawa et al. 1992 , Hayakawa et al. 1994 ) . The role of TIMP-3 in development and connective tissue turnover has thus far been studied mostly in cell cultures, in animal models, and by analyzing mRNA from tissues by Northern hybridization. In the present study we have extended the analysis of TIMP-3 in vivo by examining its expression in human tissues. We also show that the levels of TIMP-3 transcripts are induced in human primary keratinocytes by TGF-ß.

Various metalloproteinases and their inhibitors are involved in mammalian development. During the murine peri-implantation period, interstitial collagenase and stromelysin-1 mRNAs are produced by the embryo (Brenner et al. 1989 ). In later stages of murine embryogenesis, collagenase expression is restricted to hypertrophied chondrocytes, osteoblasts, endothelial cells, and osteoclasts of developing bones (Mattot et al. 1995 ). Rodent collagenase is suggested to be analogous to human collagenase-3, and these findings are consistent with our recent report on the expression of human collagenase-3 in hypertrophic chondrocytes and osteoblasts during human fetal bone development (Johansson et al. 1997 ). The 72-kD gelatinase is expressed widely in murine mesenchymal tissues, whereas 92-kD gelatinase mRNA production is limited to osteoclastic cells (Reponen et al. 1994 ). TIMP-1 and -2 are also predominantly expressed in osteogenic tissues, with some expression of TIMP-1 mRNA also in kidney, lung, ovary, and amnion (Nomura et al. 1989 ; Flenniken and Williams 1990 ; Mattot et al. 1995 ). TIMP-3 transcripts were found at sites of active matrix remodeling, such as developing bone and hair follicles. Co-localization of MMPs and their inhibitors in these areas suggests a coordinate process of ECM formation and degradation in the development and maintenance of normal tissue architecture. TIMP-3 does not appear to have a major role in the epithelial folding and branching during human fetal development, in contrast to the results of Apte et al. (Apte et al. 1994a ) in mouse embryos. However, their samples represented murine embryos of 12.5 to 14.5 days of gestation as well as newborn mice, and we cannot exclude the possibility that in human development TIMP-3 is very transiently expressed during a time period that is not covered by our samples.

Expression of TIMP-3 was detected throughout fetal hair development, starting from the hair germ stage. Hair germ formation begins in the scalp and face during the third month of gestation and gradually extends in a cephalocaudal direction. The germ consists of a group of epidermal basal cells that protrude into the dermis, forming a hair bud. Mesenchymal cells beneath each bud give rise to the dermal papilla. Further differentiation leads to the formation of the hair cuticle with the surrounding layers of inner and outer root sheath. From the beginning of the fifth month of gestation, different developmental stages are found, ranging from mature follicles to new developing ones (Lever and Schaumburg-Lever 1990 ). The factors that regulate the process of follicle development and growth cycle are not well understood, but they include epithelial–mesenchymal interactions and cytokines, such as epidermal growth factor (EGF), transforming growth factor-{alpha} (TGF-{alpha}), and members of the TGF-ß family (Messenger 1993 ). The expression of TIMP-3 is stimulated in mouse cells by various agents, including PMA, EGF, TGF-ß, dexamethasone, and TNF-{alpha} (Leco et al. 1994 ; Sun et al. 1995 ). However, in human primary keratinocytes only TGF-ß induced expression of TIMP-3, while IL-1ß and TNF-{alpha} had no effect. None of these cytokines markedly affected TIMP-1 expression. TGF-ß2 mRNA co-localizes with TIMP-3 in the basal cells of the outer root sheath (Schmid et al. 1996 ), and since TGF-ß inhibits growth of cultured hair follicles (Philpott et al. 1990 ) it may induce TIMP-3 to control follicle growth and degradation of the surrounding ECM.

Immunoreactivity for interstitial collagenase and matrilysin (MMP-7) has been detected in human hair follicles (Karelina et al. 1994 ; McGowan et al. 1994 ). Cultured hair follicles synthesize and secrete various MMPs, including interstitial collagenase, stromelysin-1, and gelatinases (Weinberg et al. 1990 ; Goodman and Ledbetter 1992 ; Paus et al. 1994 ). Cyclic expression of TIMP-1 in the inner root sheath of mouse hair follicles has been reported, with gene activation during mid-anagen phase (Kawabe et al. 1991 ). Our results demonstrate constitutive expression of TIMP-3 in both fetal and adult anagen follicles. TIMP-3 appears to contribute to the inhibition of proteolysis associated with degradation of the dermal matrix during the initial hair follicle formation, and later during the early anagen phase as the cells proliferate and invade the deeper dermis. On the basis of our studies, TIMP-1 does not have a consistent role in the growth cycle of human hair follicle. Our findings on the expression patterns of TIMP-1 and -3 in human tissues indicate that there are differences among species, and therefore the results obtained using animal models can not be directly applied to humans.

In cutaneous squamous cell carcinomas as well as mammary and intestinal carcinomas, TIMP-3 mRNA was detected in stromal cells adjacent to the malignant tumor, which is a common expression pattern for both MMPs and TIMPs. TIMP-3 was not expressed in the benign tumors and the nonaggressive keratotic basal cell carcinomas, but the signal was distinct in the infiltrative subtype and was localized to the malignant cells at the margins of tumor islands. In contrast, both TIMP-1 and -2 are detected only in the stromal cells of surrounding basal cell carcinoma (Childers et al. 1987 ; Wagner et al. 1996 ). Furthermore, expression of TIMP-2 mRNA is lower in cutaneous squamous cell carcinomas and infiltrative subtypes of basal cell carcinoma, compared to less infiltrative subtypes (Poulsom et al. 1993 ; Wagner et al. 1996 ). In cutaneous malignant melanomas, induction of both TIMP-1 and -3 mRNA expression in vivo correlates with increased depth of invasion (manuscript in preparation). Therefore, malignant transformation appears to induce the TIMP-3 gene, and in skin tumors invasive growth is associated with enhanced TIMP-3 expression, concomitantly with increased expression of matrix metalloproteinases (Ray and Stetler-Stevenson 1994 ). This suggests a role for TIMP-3 in the inhibition of metalloproteinase-mediated basement membrane and matrix degradation required for malignant growth.

In this study, TIMP-3 and -1 were differentially expressed during human fetal development. Furthermore, they were differently regulated in keratinocyte cultures by various growth factors. Further studies are needed to determine the level and specific functions of TIMP-3 protein in various human tissues. On the basis of the expression pattern of TIMP-3 mRNA, TIMP-3 appears to protect the matrix from proteolytic activity and thus regulate normal tissue turnover and inhibit malignant growth. Our results demonstrate a role for TIMP-3 in human fetal development and in remodeling processes of the extracellular matrix.


  Acknowledgments

Supported by the Sigrid Jusélius Foundation, the Academy of Finland, the Finnish Cancer Foundation, the Paulo Foundation, the Finska Läkaresällskapet, and grants from Helsinki and Turku University Central Hospitals.

We thank Dr David Carmichael for the TIMP-1 cDNA, Dr Jorma Keski–Oja for the HaCaT cells and TGF-ß1, Dr Juha Peltonen for primary keratinocytes, Dr Riitta Herva for pathology expertise, and Ms Alli Tallqvist for excellent technical assistance.

Received for publication December 26, 1996; accepted May 15, 1997.


  Literature Cited
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Summary
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Materials and Methods
Results
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Literature Cited

Alexander CM, Hansell EJ, Behrendtsen O, Flannery ML, Kishnani NS, Hawkes SP, Werb Z (1996) Expression and function of matrix metalloproteinases and their inhibitors at the maternal-embryonic boundary during mouse embryo implantation. Development 122:1723-1736[Abstract/Free Full Text]

Apte SS, Hayashi K, Seldin MF, Mattei MG, Hayashi M, Olsen BR (1994a) Gene encoding a novel murine tissue inhibitor of metalloproteinases (TIMP), TIMP-3, is expressed in developing mouse epithelia, cartilage, and muscle, and is located on mouse chromosome 10. Dev Dyn 200:177-197[Medline]

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