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17ß-Hydroxysteroid Dehydrogenase Type 1 in Normal Breast Tissue during the Menstrual Cycle and Hormonal Contraception¹

Department of Woman and Child Health, Division for Obstetrics and Gynecology (G.S., B.v.S.), Department of Plastic Surgery (M.W.), and Department of Pathology, Division for Clinical Cytology (L.S.), Karolinska Hospital, S-171 76 Stockholm, Sweden; and Biocenter Oulu and Department of Clinical Chemistry, University of Oulu (M.P., R.V.), FIN-90220 Oulu, Finland

Address all correspondence and requests for reprints to: Gunnar Söderqvist, M.D., Ph.D., Department of Woman and Child Health, Division for Obstetrics and Gynecology, Karolinska Hospital, S-171 76 Stockholm, Sweden.

Abstract

Our purpose was to assess 17ß-hydroxysteroid dehydrogenase (17HSD) type 1 protein expression in normal breast tissue during the menstrual cycle and hormonal contraception. We analyzed 17HSD type 1 protein expression by immunohistochemistry during the regular menstrual cycle (n = 12) and hormonal contraception (n = 7) in women undergoing reduction mammoplasty. 17HSD type 1 protein was detected in normal breast epithelial cells throughout the menstrual cycle and in all women using hormonal contraception. Mean 17HSD type 1 staining intensity was higher in alveolar epithelial cells in women using hormonal contraception (2.14) than in untreated women (1.25; P < 0.04). For ducts, this difference approached significance (2.29 vs. 1.41; P = 0.06). There was a negative correlation between serum estradiol (E₂) levels and 17HSD type 1 protein expression for both alveolar (r_s = -0.68; P = 0.004) and ductal (r_s = -0.75; P = 0.002) breast epithelial cells.

Enhanced 17HSD type 1 protein expression might increase the conversion to E₂ in normal breast tissue during hormonal contraception. The negative correlation between serum E₂ levels and 17HSD type 1 suggests this enzyme to be one of the regulatory mechanisms of intratissue E₂ concentration in normal breast tissue.

ESTROGEN is generally accepted to be a promoter of breast epithelial cell proliferation and to be involved in the development and growth of breast cancer (1, 2). Recent data have indicated that estrogen action can be strongly affected by hormone metabolism and biosynthesis in peripheral target tissues (3). Thus, plasma concentrations of estrogens do not totally reflect their biological potency at the target tissue level. One of the key enzymes regulating estrogen action is 17ß-hydroxysteroid dehydrogenase (17HSD), which catalyzes the interconversion between the low active estrone (E₁) and the highly active estradiol (E₂). In the endometrium, the reaction is mainly oxidative, favoring the inactivation of E₂ to E₁ (4). However, in the granulosa cells of the ovary, 17HSD activity is an essential step in E₂ biosynthesis, thereby favoring the activation of E₁ to E₂. It was for a long time obscure why the enzyme was favoring E₂ formation in some and E₁ formation in other organs and conditions (5). Some clarification has been achieved by the recent characterization of four human 17HSD type 1–4 enzymes, each with specific properties (6, 7, 8). Current data suggest that from the characterized 17HSD enzymes, types 1 and 2 are most closely associated with estrogen metabolism (3). The human type 1 enzyme is cytosolic and prefers E₁ as a substrate, whereas 17HSD type 2 is a membrane-bound enzyme capable of using both estrogens and androgens (6) and, to a lesser extent, progestogens as substrates. These two enzymes predominantly catalyze opposite reactions: type 1 converts E₁ to E₂, and type 2 converts E₂ to E₁ (6, 9).

In the present study, 17HSD type 1 protein expression was assessed in apparently normal breast tissue from women undergoing reduction mammoplasties during the menstrual cycle and hormonal contraception. In addition, estrogen (ER) and progesterone receptor (PR) content and sex steroid serum levels were analyzed.

Experimental Subjects

The clinical material comprised 19 premenopausal women (mean age, 34 yr; range, 21–50 yr) undergoing reduction mammoplasty for inconvenient breast size. Twelve of the women of fertile age (mean age, 38 yr; range, 22–50 yr) had regular menstrual cycles, and seven women (mean age, 26 yr; range, 21–38 yr) were subject to hormonal contraception. None of the normally cycling women had taken any sex steroid-containing drugs during the last 6 months preceding the study. In addition, three untreated healthy postmenopausal women, aged 52, 52, and 59 yr were investigated.

Venous blood samples and anamnestic menstrual cycle data were collected on the day of surgery. E₂, progesterone, and PRL were analyzed by routine hospital methods. The study was approved by the local ethics committee, and all women gave informed consent.

Materials and Methods

Immediately after surgical removal, the tissue samples were washed with saline and frozen at -70 C until analyzed.

Immunohistochemistry

17HSD type 1. The breast specimens were sectioned to 5–7 µm at -20 C and thaw-mounted on poly-L-lysine-coated glass slides. Tissue sections were treated with 0.01 mol/L phosphate-buffered saline (PBS)-10% FCS (pH 7.4) for 30 min at room temperature to block nonspecific binding. The polyclonal antibody used in this study has been characterized in detail previously (10, 11, 12).

The antiserum raised against 17HSD type 1 (1:200 dilution in PBS-10% FCS) was added to the slides, and they were incubated overnight at 4 C. The slides were washed three times for 5 min each time with PBS. Thereafter, the sections were incubated at room temperature for 2 h with a 1:50 dilution of biotinylated goat antirabbit antibody (Dako Laboratories, Copenhagen, Denmark). The slides were washed three times for 5 min each time with PBS, and a 1:50 dilution of fluorescein isothiocyanate-conjugated streptavidin (Dako Laboratories, Copenhagen, Denmark) was added. After incubation for 1 h at room temperature, the sections were washed five times with PBS, 5 min each time, and mounted (Immu-Mount, Shandon, PA). Specific staining was controlled by staining the sections with preimmune serum or by preabsorbing the antiserum with highly purified 17HSD type 1 before staining.

Sex steroid receptors. Staining was performed on formalin-fixed, paraffin-embedded tissues. The basic staining procedure applies an avidin-biotin-peroxidase method modified for antigen retrieval from paraffin-embedded tissue (13). The ER and PR analyses were performed with reagents supplied by Abbott Laboratories (North Chicago, IL).

Quantification of immunohistochemical staining

Immunostained cells were quantified by cell counting in sections by an observer blinded to treatments. Epithelial cells lining the alveoli/terminal ducts and major ducts were considered separately. Labeled cell cytoplasm for 17HSD type 1, and nuclei for steroid receptors were graded as unlabeled (0), weakly labeled (1+), moderately labeled (2+), or intensely labeled (3+). At least 100 cells/slide were counted at 3 different sites for each combination of tissue site and stain type.

Statistical analysis

Differences were assessed by the Wilcoxon rank sum test for unpaired observations. For correlation analyzes, Spearman’s rank correlation coefficient was calculated.

Results

The summary of the results for 17HSD type 1, ER, and PR stainings is given in Table 1. The data showed that in breast tissue, 17HSD type 1 was detected exclusively in epithelial cells throughout the menstrual cycle, and that the staining intensity was similar in alveoli and ducts, with no statistical differences between the two structures. Typical stainings for the enzyme in the normal breast are illustrated in Fig. 1. In specimens taken during the follicular phase, weak to moderate 17HSD type 1 staining was observed. Luteal phase staining varied from weak to strong, and staining for the enzyme was also found in the late luteal phase. Furthermore, staining for 17HSD type 1 was observed in two of the three postmenopausal women.

View larger version (135K): [in this window] [in a new window]   Figure 1. Staining for 17HSD type 1 in normal breast tissue. Left, Cycle day 9; right, cycle day 23.

View larger version (15K): [in this window] [in a new window]   Figure 2. Line plot of the correlation between the serum E2 level and ductal 17HSD type 1 staining intensity.

ER content was lower in the luteal phase in untreated premenopausal women. PR ranged from low to high in both phases. There was a significantly positive correlation between ductal 17HSD type 1 staining intensity and the percentage of ER-positive cells (r_s = 0.59; P < 0.05) and a tendency for a positive correlation in alveoli (r_s = 0.53; P = 0.09). No significant correlations were seen between 17HSD type 1 and PR levels.

There were significantly negative correlations between serum progesterone levels and the proportion of alveolar ER-positive cells in untreated premenopausal women (r_s = -0.68; P = 0.03), all premenopausal women (r_s = -0.48; P = 0.05), and the whole study group (r_s = -0.61; P < 0.01). For ducts, this correlation was significant only for the whole study group (r_s = -0.49; P = 0.03).

Discussion

17HSD type 1 protein was readily detected in normal breast epithelial cells, in ducts and alveoli, during both follicular and luteal phases of the menstrual cycle, and the staining was also observed in postmenopausal women. These data indicate that the regulation of 17HSD type 1 in normal breast is different from that previously shown in endometrial epithelial cells. In the endometrium, the enzyme is absent during the follicular phase. Maximal protein expression was observed during the early and midluteal phase of the cycle and gradually disappeared during the late luteal phase (11). In the endometrium, the increase in staining intensity for 17HSD type 1 was associated with increased serum progesterone levels.

A difference between the endometrium and breast was also suggested by the present results indicating a negative correlation between serum E₂ levels and the enzyme protein expression. The present data indicate a greater tissue conversion from E₁ to E₂ in subjects with low endogenous E₂ levels. However, it should be recalled that the regulation and expression of oxidative 17HSD type 2 also should be studied before conclusions about intratissue E₂ concentrations are made (3, 5).

There was also a tendency for a negative correlation between serum progesterone levels and the expression of 17HSD type 1 in normal breast tissue of untreated women. Previously, in breast cancer tissue a positive correlation was found between 17HSD type 1 and serum progesterone levels (12). This may be a mechanism by which high intratissular E₂ levels are retained in malignant breast tissue. In the T47D breast cancer cell line, which is rich in PR, treatment of the cells with the synthetic progestogen ORG 2058 increased the 1.3-kilobase 17HSD type 1 messenger ribonucleic acid (14).

In this study, 17HSD type 1 was detected in 9 of 12 (75%) premenopausal women with regular cycles and in 2 of 3 postmenopausal women. This is in line with previous findings in benign breast disease, where 71% of samples had positive 17HSD type 1 staining (14). The corresponding value in malignant breast tissue was 47%. Here, strong and moderate 17HSD type 1 staining was related to the presence of PR. In normal breast tissue we found no correlation between 17HSD type 1 staining intensity and PR. However, a significant positive correlation was found between 17HSD type 1 staining and ER. This is in line with the negative correlation between 17HSD type 1 staining intensity and serum E₂ levels found in this study and with a negative correlation between the ER level and serum E₂ levels found recently (13).

Previously, a decline in PR number was found in the epithelial cells of the endometrium during the luteal phase, whereas in the breast, the number of PR remained unchanged throughout the cycle (15).

As expected, there was a negative correlation between serum progesterone levels and ER content. Women using hormonal contraception showed a significantly higher 17HSD type 1 expression than untreated women. This up-regulation of the reductive enzyme indicates a potential for increased formation of highly potent E₂ from E₁ in hormonal contraceptive users. The present results indicate a difference between progestogens used for contraception and physiological progesterone with regard to 17HSD type 1 protein expression in normal breast tissue. Previously, discrepant effects were also found for sulfatase activity. Although there was a positive correlation between serum progesterone levels and sulfatase activity in untreated women, the conversion of E₁ sulfate to E₁ was suppressed during hormonal contraception (16).

In conclusion, the negative correlation between serum E₂ levels and 17HSD type 1 protein expression indicates a potential for greater tissue conversion from E₁ to E₂ in subjects with low endogenous E₂ serum levels. This may be important for the estrogenic stimulation of the breasts and could be one of the regulatory mechanisms of intratissue E₂ concentration in normal breast tissue.

Acknowledgments

We gratefully acknowledge the efforts of Tuula Eklöf, Torsten Hägerström, Birgitta Byström, Eva Segersten, Siv Rydås, Ulrika Olsson, Mia Karlsson, and Liisa Karela.

Footnotes

¹ This work was supported by the Swedish Medical Research Council (Project 5982), Karolinska Institute Research Funds, the Swedish Cancer Society, the Research Council for Health, the Academy of Finland (Project 1051135), and the Ministries of Education, Social Affairs and Health and of Foreign Affairs, Finland.

Received March 21, 1997.

Revised November 21, 1997.

Accepted December 23, 1997.

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