Changes with senescence in the fine structure of the granular convoluted tubule of the submandibular gland of the mouse

Cells of the granular convoluted tubules (GCTs) of the submandibular glands of senescent male mice show structural changes indicative of functional decline. In order to define the nature of these age-related changes more clearly, the fine structure of GCT cells of 12- and 28-month-old males was compared. In old mice, there was cell-to-cell variation in the extent of these changes, with some cells of senescent males appearing no different from those of young adults. In affected cells the most striking alterations were seen in secretion granules and lysosomal elements. Secretion granules varied greatly in size, with some GCT cells having only very fine apical granules. Secondary lysosomes and large lipofuscin granules were frequent in the basal cytoplasm. Very large dense bodies (3-5 μm) occurred in many cells. These possibly represent intracellular pools of released secretory materials, as they were occasionally seen in continuity with the luminal contents. Structures whose appearance was intermediate between the very large dense bodies and lipofuscin granules were common, suggesting crinophagic activity. There was an apparent decrease in numbers of polysomes and in the extent of the Golgi apparatus. These fine structural changes are consistent with impairments with advanced age in synthesis and posttranslational processing of secretory products by affected GCT cells. In addition to cell-to-cell variation in any one male, there was also interanimal variation in the degree and extent of these senescent changes.     

Immunocytochemical localization of epidermal growth factor during the postnatal development of the submandibular gland of the mouse

The time of appearance and the pattern of localization of epidermal growth factor (EGF) in submandibular glands of mice was studied during postnatal development immunocytochemically. EGF was first detectable in the granular convoluted tubule (GCT) cells in the glands of males at 20 days of age and of females at 30 days of age. Development of GCT cells containing EGF was rapid in males, approaching adult conditions by 45 days of age. In females EGF-containing GCTs developed more slowly and irregularly, and did not reach adult status by 45 days of age. It is concluded that EGF is restricted during postnatal development to the GCT cells, and that these cells and the distribution of EGF are represented dimorphically from their first appearance in the submandibular glands of both sexes.     

Immunocytochemical localization of nerve growth factor,epidermal growth factor,renin and protease A in the submandibular glands of Tfm/Y mice

The submandibular glands of mice with testicular feminization (Tfm/Y) and their normal adult male littermates (Ta/Y) were studied by immunocytochemical techniques for the demonstration of epidermal growth factor (EGF), nerve growth factor (NGF), renin and protease A. In the glands of both the affected and normal males, these polypeptides were restricted to cells of the granular convoluted tubules (GCT), with the exception of protease A, which was also found in small amounts in striated duct cells. Compared to those of Ta/Y males, GCTs were narrower in the glands of Tfm/Y mice and contained a markedly reduced number of cells immunoreactive for EGF, NGF and renin. However, the number of GCT cells that stained for protease A in the glands of Tfm/Y males was not as drastically decreased.     

Epidermal growth factor, renin, and protease in hormonally responsive duct cells of the mouse sublingual gland

In the striated ducts of the sublingual glands of normal adult male, but not female, Swiss-Webster mice a few scattered cells have apical secretion granules. These sublingual duct cells resemble the granular convoluted tubule (GCT) cells of the submandibular glands of adult female mice, in that they are smaller than submandibular GCT cells of adult males, and contain fewer apical granules, and prominent basal striations. These cells stain immunocytochemically for epidermal growth factor (EGF), renin, and protease A. Such granular striated duct cells could be induced in the sublingual glands of adult female mice by treatment with either testosterone propionate or thyroxine; the two hormones given simultaneously acted synergistically in this induction.     

Acute and chronic adrenergic stimulation of submandibular salivary glands. Effects on the endocrine function of epidermal growth factor in mice

Submandibular salivary glands are the major source of epidermal growth factor (EGF) in mice. Acute secretion of EGF from these glands protects the heart against catecholamine-induced injury. Little is known about chronic adrenergic stimulation of salivary glands and the contribution of accumulated EGF to the adaptive hypertrophic response of the heart to such chronic adrenergic stimulation. Here we show that the EGF content of submandibular glands did not recover to normal values 24 h after a single phenylephrine injection or an aggressive encounter. Repeated (twice a day for 2 days) adrenergic stimulation resulted in an almost 90% decrease in EGF content in the submandibular glands. In these conditions, new adrenergic stimulation did not result in an increase in plasma EGF concentration, or in the activation of liver ErbB1 (the EGF receptor). Chronic isoproterenol or phenylephrine administration (7 days) induced atrial natriuretic factor expression in the heart and an increase in both ventricular weight and protein. The surgical removal of submandibular glands (sialoadenectomy) did not affect these adaptive responses of the heart. We conclude that EGF from submandibular glands does not contribute to heart hypertrophy, one of the adaptive responses induced by chronic adrenergic stimulation.     

Epidermal growth factor in the submandibular glands of inbred mice

Epidermal growth factor (EGF), an androgen-dependent polypeptide, occurs in high concentration in male mouse submandibular gland. Glands of adult male and female mice of six inbred strains (129/J, C57BL/6J, C58/J, SWR/J, RF/J, A/J) were assayed for EGF by radioimmunoassay. In all strains, the glands of males contained 30 to 500-fold more EGF than those of females. Furthermore, significant differences in EGF content were found among the various strains in both sexes; the highest amount of EGF was present in RF/J and the lowest in C57BL/6J, with a ratio of three in the males and four in the females of the two strains, respectively. Factors that effect EGF levels were analyzed further, using these two strains. EGF was measurable in the glands of mice of both strains at 21 days of age and increased rapidly thereafter, up to 14 weeks of age. Throughout postnatal development, the level of EGF was greater in the glands of RF/J mice than in those of the C57BL/6J animals. Thirty days after castration, the EGF levels were reduced by about 98% in both strains, but the strain difference was not abolished. Testosterone implants (1 mg in Silastic tube) in castrated mice induced EGF levels six- to ten-fold compared to castrates. Even in induced animals, which had similar plasma testosterone levels, as measured by radioimmunoassays, the difference in EGF levels between the two strains was manifest. Such a difference, however, was not seen after the daily administration of 5-alpha-dihydrotestosterone for 3–14 days. Immunocytochemical staining for EGF also indicated a higher concentration of the polypeptide in the glands of RF/J mice than in those of C57BL/6J animals, and confirmed the exclusive localization of EGF in the cells of the granular convoluted tubules (GCT). According to our morphometric analysis, in the glands of male RF/J mice the GCT compartment occupied a greater portion (8% greater, P<0.001) of the gland volume than in C57BL/6J mice. The difference in the relative GCT volumes in the glands of female mice of the two strains was, however, statistically not significant. There was no direct correlation between the amount of EGF and the relative volume of the GCTs in the two strains. The evidence obtained implies that strain differences in submandibular-gland EGF levels are determined genetically.     

Regulation of epidermal growth factor receptor by androgens in human endometrial cells in culture

Women with polycystic ovaries (PCO) have a thicker endometrium than women with normal ovaries. This cannot be due to unopposed oestrogen, as it occurs in ovulatory cycles. Androgens may be involved, as these are raised in women with PCO. The effects of steroids are partly mediated by growth factors and their receptors. The aim of this study was to investigate the effect of androgens on epidermal growth factor (EGF) receptor in human endometrium. Endometrium was enzymatically dispersed and glands and stromal cells separated. Cells were incubated in Ham's F10 medium supplemented with 5% charcoal-stripped fetal calf serum and either androgens or vehicle. Specific binding of [125I]- labelled EGF was measured. Testosterone and dihydrotestosterone (DHT) (10 micromol/l) increased EGF receptor concentration (control 100 +/- 9%, testosterone 196 +/- 23% control; control 100 +/- 1%, DHT 244 +/- 6% control) but did not alter receptor affinity. The effect of testosterone was inhibited by the anti-androgen hydroxyflutamide, but not by the antioestrogen ICI182780 nor the aromatase inhibitor 4- hydroxyandrostenedione. EGF receptor levels were increased by androstenediol (control 100 +/- 2%, androstenediol 120 +/- 10% control) but not by androstanediol, dehydroepiandrosterone (DHA), DHA sulphate or androstenedione. Testosterone and DHT increased EGF receptor concentrations in glandular epithelium (control 100 +/- 24%, testosterone 147 +/- 5%, DHT 185 +/- 30% control). These data suggest that androgens may have an effect on the endometrium via an increase in EGF receptor concentrations.      

Phenotypic expression of human epidermal growth factor in foetal submandibular gland and pleomorphic adenoma of salivary gland

Summary The phenotypic expression of the human epidermal growth factor (EGF) was investigated immunohistochemically in human foetal submandibular glands from the 5th to 10th month of gestation, adult normal submandibular glands and 48 cases of pleomorphic adenomas. In foetal submandibular glands, both the terminal buds and primary ducts at the intermediate stage of gestation were positive for EGF, and in particular, the outer layer cells of primary ducts showed strong EGF-immunoreactivity. EGF-positive cells decreased as the gestational stage advanced and only ductal cells were weakly positive for EGF at the terminal stage of gestation. In the adult normal submandibular gland, weak immunoreactivity for EGF was restricted to ductal cells. However, 41 (86%) of the 48 pleomorphic adenomas had EGF-positive cells which were distributed among the ductal, chondroid and myxoid portion. No EGF-immunoreactivity was detected in the solid portion of pleomorphic adenomas. These results suggest that EGF may play an important role in the growth and differentiation of foetal cells as well as the proliferation of tumour cells in pleomorphic adenomas.     

Role of thyroid hormone in the initiation of EGF (epidermal growth factor) expression in the sublingual gland of the postnatal mouse

The effect of triiodo-L-thyronine (T3) and propylthiouracil (PTU) on the initiation of epidermal growth factor (EGF) expression in the sublingual glands (SLGs) of postnatal mice was investigated by indirect enzyme-labeled and immunogold antibody methods for light and electron microscopy, respectively. In normal males, EGF immunoreactivity first appeared in a few scattered granular cells of striated ducts (SDs) at 5 weeks of age, and the immunoreactive cells had increased in number at 6 weeks of age. No EGF expression was observed in the glands of females at any ages examined. When T3 (1 mg/kg body weight) was given to males every other day for 2 weeks before examination, EGF expression began earlier; the immunoreactive granular cells were first detected at 4 weeks of age, and at later ages they were markedly increased in number compared to those of normal males. Moreover, T3 was capable of inducing EGF in the female glands. After T3 was administered to females in the same manner as in males, a few immunoreactive cells were first detected at 5 weeks of age, and increased numbers were detected at later ages. By contrast, when PTU (1 mg/kg body weight) was given to male mice every other day for 2 weeks before examination, the EGF-immunoreactive cells were markedly decreased in number compared to those of normal males of the same age. Electron microscopy revealed that many SD cells contained secretory granules, and that these cells constituted the granular striated tubule (GST) in a portion of SDs, but they were undetectable by light microscopy, because their secretory granules were minimal in size and few in number. Gold-labeling of EGF was confined to the secretory granules of scattered granular cells, whose secretory granules were far larger in size and more abundant than those of the GST cells. These results suggest that thyroid hormone is essential to differentiation of the cellular phenotype of GST precursor cells into typical granular cells (detectable by light microscopy) that express EGF in the mouse SLG, showing a close resemblance to the submandibular granular convoluted tubule cells.     

Electron microscopic immunostaining of nerve growth factor: secretagogue stimulated submandibular glands

Immunocytochemical localization of nerve growth factor (NGF) was assessed on thin sections of plastic-embedded male mouse submandibular glands by electron microscopy. Both control and secretagogue-stimulated glands were examined. NGF was localized in granules of both granular convoluted tubule (GCT) cells and transition cells. The latter were intermediate in morphology between GCT cells and striated duct cells. Both large and small granules were immunostained in GCT cells; however, considerable variability in immunostaining intensity was observed in both sizes of granules but especially in the small granules of transition cells. Rough endoplasmic reticulum (RER) in both cell types exhibited NGF immunoreactivity. No Golgi-associated immunostaining was observed. Following alpha-adrenergic stimulation with phenylephrine, NGF-containing granules were sharply reduced because of extensive degranulation. Pools of immunostained secretory material suggested intracellular fusion of NGF-containing granules. Immunostaining was also observed on membrane fragments found within large vacuoles in GCT cells. Evidence of NGF secretion after beta-adrenergic or cholinergic stimulation was less dramatic. In isoproterenol-stimulated GCT cells there was evidence of fusion of small, apical, NGF-stained granules. These cells also possessed heavily immunostained apical membrane blebs. Pilocarpine-stimulated cells exhibited pleomorphic immunostained apical granules but less apical membrane immunostaining. Abundant basal lysosomes appearing in GCT cells after pilocarpine stimulation did not stain for NGF.     

Immunocytochemical localization of renin in the submandibular gland of the mouse during postnatal development

The localization of renin in the developing mouse submandibular gland was studied immunocytochemically using the unlabelled antibody-enzyme method of Sternberger (1974). Bouin-fixed submandibular glands of mice of both sexes were examined at 5-day-intervals from birth (day 0) to 50 days of age. At all stages studied, only granular convoluted tubule (GCT) cells stained immunocytochemically for renin; such cells were first seen in glands of 30-day-old males and of 30-day-old females. The size and number of renin-containing GCT cells increased rapidly in males, attaining adult status by 50 days of age. In females, differentiation of GCT cells immunoreactive for renin was slower and less regular than in males, and at 50 days of age the GCT segment had not yet reached adult conditions with respect to the distribution of renin. Renin appears in GCT cells at later ages than other GCT cell products (e.g., EGF and amylase), suggesting the existence of independent developmental control for the expression of various biologically active substances in the GCTs.     

Spontaneous development of autoimmune sialadenitis in aging BDF1 mice.

This study reports that spontaneous autoimmune sialadenitis developed in aging female, rather than male, BDF1 mice. The lesions first appeared in 6-month-old female BDF1 mice and were aggravated with advancing age, especially in 24-month-old and 30-month-old senescent mice. In contrast, significant inflammatory changes did not develop in aging male BDF1 mice. The presence of antisalivary duct antibody was found in sera from mice with sialadenitis. The infiltrating cells in the lesions of submandibular salivary glands were mainly composed of T cells, especially Lyt 1+ and L3T4+ cells. Moreover, mild inflammatory lesions were observed in parotid, sublingual salivary glands, pancreas, or kidneys in some mice that developed spontaneously occurring sialadenitis.     

Cellular and subcellular colocalization of nerve growth factor and epidermal growth factor in mouse submandibular glands

Immunocytochemical methods have been used to compare the cellular and subcellular distribution of nerve growth factor (NGF) and epidermal growth factor (EGF) in mouse submandibular glands. Rabbit antisera raised against purified proteins were characterized by immunoblot methods and were used to stain sections of salivary glands embedded in plastic. For light microscopy, antibodies were visualized by indirect immunofluorescence. For electron microscopy, thin sections were treated simultaneously with IgG against NGF and EGF coupled to colloidal gold particles of different size. Data indicate that NGF and EGF are present in all granular convoluted tubule cells and in no other cell type within the salivary gland. Ultrastructural analyses indicate that NGF and EGF are evenly distributed together within mature secretory granules, although a population of small granules was identified that is not immunoreactive for either protein. Taken together, the data suggest that granular convoluted tubule cells are homogeneous in the production and storage of NGF and EGF.     

Effects of pretreatment with androgen or thyrold hormone on androgen-induced proliferation of granular convoluted tubular cells in mouse submandibular glands

The effects of pretreatment with androgen or thyroid hormone on androgen-induced proliferation of granular convoluted tubular cells (GCT cells) in the submandibular glands of ovariectomized female BALB/c or C57BL/6 mice were investigated. The proliferation of GCT cells was estimated by their labeling index. Daily injections of 5α-dihydrotestosterone (DHT) (100 μg/mouse/day) caused a transient increase in the labeling index of GCT cells of ovariectomized 60-day-old BALB/c mice during the first four injections, but injections of thyroxine (T₄) (15 μg/mouse/day) did not. On the other hand, both DHT and T₄ increased the esteroprotease activity, a marker of the differentiation of GCT cells, time dependently. Injections of DHT into ovariectomized 102-day-old BALB/c mice also caused a transient increase in the labeling index of GCT cells. However, pretreatment of ovariectomized 60-day-old BALB/c mice with DHT for 4 or 14 days completely abolished the DHT-induced increase in the labeling index of 102-day-old mice, and pretreatment with T₄ for 14 days reduced this increase. Pretreatment with DHT or T₄ for 14 days did not affect the DHT-induced increase in esteroprotease activity. Pretreatment of ovariectomized 60-day-old C57BL/6 mice with DHT for 14 days also completely abolished the DHT-induced increase in the labeling index of GCT cells at the age of 102 days, but pretreatment with T₄ for 14 days did not affect the increase. These results suggest that the proliferation of mouse GCT cells induced by androgen results in a complete abolition of their proliferative response to androgen, and that the effect of thyroid hormone on the proliferative response of GCT cells to androgen may differ in different strains of mice. © 1993 Wiley-Liss, Inc.     

Epidermal growth factor and insulin-like growth factor I are localized in different compartments of salivary gland duct cells. Immunohistochemical evidence

Immunohistochemical methods were used to map EGF (epidermal growth factor) and IGF-I (insulin-like growth factor I; somatomedin C) immunoreactivities in salivary glands of adult rodents. Epidermal growth factor is, as is NGF (nerve growth factor), limited in distribution to the granules in granular duct cells in the submandibular gland. Insulin-like growth factor I is, in contrast, cytoplasmic and has a much more widespread distribution. It is seen in intercalated, striated and granulated duct cells as well as in apical parts of excretory duct cells. The parotid and the palatine salivary glands, lacking EGF immunoreactivity, have their IGF-I immunoreactivity similarly distributed as the submandibular gland. Isoproterenol treatment of adult male rats results in rapid and extensive growth of the submandibular and the parotid glands, which double their weights in just a few days. Isoproterenol causes release of granules from the submandibular granular duct cells and decrease in frequency of EGF immunoreactive cells. However, there is no or only minor concomitant changes in the distribution and intensity of the IGF-I immunoreactivity in these duct cells. Our results indicate that the trophic peptides EGF (and NGF) and IGF-I are localized in different compartments in salivary gland duct cells and that divergent pathways control their release.     

Epidermal growth factor and insulin-like growth factor I are localized in different compartments of salivary gland duct cells. lmmunohistochemical evidence

Immunohistochemical methods were used to map EGF (epidermal growth factor) and IGF-I (insulin-like growth factor I; somatomedin C) immunoreactivities in salivary glands of adult rodents. Epidermal growth factor is, as is NGF (nerve growth factor), limited in distribution to the granules in granular duct cells in the submandibular gland. Insulin-like growth factor I is, in contrast, cytoplasmic and has a much more widespread distribution. It is seen in intercalated, striated and granulated duct cells as well as in apical parts of excretory duct cells. The parotid and the palatine salivary glands, lacking EGF immunoreactivity, have their IGF-I immunoreactivity similarly distributed as the submandibular gland. Isoproterenol treatment of adult male rats results in rapid and extensive growth of the submandibular and the parotid glands, which double their weights in just a few days. Isoproterenol causes release of granules from the submandibular granular duct cells and decrease in frequency of EGF immunoreactive cells. However, there is no or only minor concomitant changes in the distribution and intensity of the IGF-I immunoreactivity in these duct cells. Our results indicate that the trophic peptides EGF (and NGF) and IGF-I are localized in different compartments in salivary gland duct cells and that divergent pathways control their release.     

Precocious development of granular convoluted tubules in the mouse submandibular gland induced by thyroxine or by thyroxine and testosterone

The effects of the administration of thyroxine (T₄) and/or testosterone (TP) on the early postnatal differentiation of granular convoluted tubule (GCT) cells of the submandibular glands were studied in Swiss-Webster mice. From birth, mice were injected daily with T₄ up to the time of killing at 15 or 20 days of age. In addition, groups of mice were given one injection of TP eight days before killing. Control animals received vehicles (saline and/or sesame oil). Sections of the glands were stained with toluidine blue, or immunocytochemically by the unlabelled antibody enzyme method, for the localization of protease A, epidermal growth factor, or renin. Supernatants of the gland were analyzed for protease activity (pH 8.5, substrate: tosyl-glyclyl-L-prolyl-L-arginine nitroanilide acetate), or by radioimmunoassay for EGF content. At 15 days of age no GCT cells were present in the glands of control or TP-treated mice. In T₄-injected mice many small GCT cells occurred, while larger and more numerous GCT cells were seen in the glands of mice that received both hormones. TP alone had no effect on levels of EGF or protease activity. In T₄-treated mice, protease levels increased 10-fold and EGF content rose 28-fold. TP administration to T₄-treated mice caused a further threefold, increase in both protease activity and EGF content. At 20 days of age the glands of control mice had a few small GCT cells, and both protease activity and EGF content were substantially increased. TP treatment was again without effect. However, daily injections of T₄ caused both protease activity and EGF levels to increase 20- and 11-fold, respectively. Just as in 15-day-old mice, TP administration to T₄-primed mice resulted in further increases in the two polypeptides. Immunocytochemical staining for protease A and EGF confirmed the chemical data. Renin was detectable immunocytochemically at both ages in the glands of mice that had received T₄, but it was seen in the glands of mice that had received TP alone only at 20 days of age. It is concluded that T₄ caused a precocious induction of GCT cells and their specific products. Although TP alone had no effect on their early differentiation, it acted synergistically with T₄ in inducing GCT cells. There were no obvious sex differences in any of these features in control or treated animals.     

Morphological study of granular convoluted tubules in the submandibular gland of the mouse during the growth of a sarcoma-180 subcutaneous tumor

Histological and cytological changes in the submandibular glands of adult male mice arising during the growth of sarcoma-180 subcutaneous tumors were studied. The submandibular glands of the mice were examined by morphometric analysis at 1, 3, 6, 10, 20, 30 and 64 days after inoculation of the tumor cells. There was a slow increase in the relative cross-sectional area of the granular convoluted tubule (GCT) in the section of the submandibular gland of the animals as the tumors grew. The increased proportional area of the GCT was significantly different from that of the control's from day 30. However, the mean weight of the glands was not increased. The proportional area of the granular cluster in the cells of the GCT of tumor cells in inoculated animals decreased about 5% on the first day and then quickly increased by 16% on the third day in comparison with those of the controls, eventually reaching a maximum of 74% (control, 54%) by day 30. In addition, the average number of granules per GCT cell decreased in the first three days, then increased to normal levels from day 6, going above the normal level from day 20 of the tumor growth. These changes in the glands of tumor-bearing animals disappeared within 20 days after removal of the tumor. These results indicate that the growth of the sarcoma-180 subcutaneous tumor caused morphological changes in the GCT and GCT cells, suggesting an alternation in the requirements of the secretions contained in the granules, such as the epidermal growth factor, during the growth of the tumor.     

Lack of effects of viral sialoadenitis and depletion of epidermal growth factor on initiation of hepatic carcinogenesis in the rat.

Sialodacryoadenitis (SDA) is a commonly-encountered coronaviral infection in laboratory rats that causes acute destruction of submandibular salivary glands. SDA results in depletion of salivary epidermal growth factor (EGF) and may thereby affect EGF-dependent cell growth processes. The purpose of this study was to determine the effects of SDA virus (SDAV) infection on the growth factor-dependent stages of experimental liver carcinogenesis. Rats were injected ip with the carcinogen diethylnitrosamine (DENA) at 1, 2, or 3 weeks following inoculation with SDAV. Uninfected control rats were treated only with DENA. The salivary glands of SDAV-inoculated and control rats were stained using the immunoperoxidase method for the detection of EGF. Residual submandibular salivary gland lesions and focal depletion of EGF were still evident in affected submandibular glands for up to 42 days after SDAV infection. Serum EGF concentrations measured at 9, 28, and 42 days following SDAV inoculation were reduced, but were not significantly different in comparison with non-inoculated, DENA-treated control rats. Initiated hepatocytes were detected 21 days after DENA treatment in formalin-fixed sections by an immunoperoxidase stain for the P isoenzyme of the enzyme glutathione S-transferase (GST-P). There was no significant difference in the number of foci of GST-P positive cells in a comparison of initiated cells in SDAV-inoculated and non-inoculated rats. Based on this model, concurrent infection with SDAV does not appear to have any significant effects on the initial stages of chemical hepatocarcinogenesis in the rat.     

Expression of epidermal growth factor in human tissues

Summary The expression of epidermal growth factor (EGF) was examined on various human tissues by radioimmunoassay, immunohistochemistry and Northern blot analysis. Immunoreactive EGF was found in most of the human tissues by radioimmunoassay at various levels. Large quantities of EGF were detected in the kidney and thyroid gland. Immunohistochemically, EGF immunoreactivity was detected mainly in the epithelial cells of the lung, stomach, duodenum, pancreas, kidney, pituitary gland, thyroid gland, mammary gland, ovary, uterus and placenta. Weakly EGF-positive cells were also found in the adrenal gland. The results of EGF-immunostaining were not always consistent with the data from radioimmunoassay. We consider that the amount of EGF measured by radioimmunoassay reflects the density of EGF-positive cells in the tissues and the concentration of EGF in individual EGF-positive cells. Furthermore, EGF mRNA was expressed in the salivary gland, thyroid gland, mammary gland and kidney. It is thus evident that EGF is produced by a variety of human tissues. The kidney expressed exceptionally high levels of EGF mRNA which was about one-tenth of the expression in mouse submandibular gland, suggesting that most of EGF in the urine is produced and secreted by the epithelial cells of renal tubules.