This Article Abstract Free Full Text (Free PDF) Free Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Add to Saved Citations Download to citation manager Request Permissions Request Reprints Add to My Marked Citations Citing Articles Citing Articles via Google Scholar Citing Articles via Scopus Google Scholar Articles by Lucas, J. N. Articles by Snyder, P. W. Search for Related Content PubMed PubMed Citation Articles by Lucas, J. N. Articles by Snyder, P. W. Pubmed/NCBI databases Compound via MeSH Substance via MeSH Medline Plus Health Information Hormones Hazardous Substances DB PROGESTERONE Social Bookmarking                   What's this?

The Rat Mammary Gland: Morphologic Changes as an Indicator of Systemic Hormonal Perturbations Induced by Xenobiotics

¹ Purdue University Department of Pathobiology, College of Veterinary Medicine, West Lafayette, IN 47907, USA
² Lilly Research Laboratories, Eli Lilly and Company, Greenfield Laboratories, Greenfield, IN 46140, USA

Correspondence: Address correspondence to: Daniel G. Rudmann, Lilly Research Laboratories, Eli Lilly and Company, Greenfield Laboratories, Greenfield, IN 46140, USA; e-mail:rudmanndg{at}lilly.com

	Abstract

TOP Abstract Development of the Rat... Study Designs and Collection... Unique Sex-Specific Morphology... Implications for Toxicology... Conclusion References

 
The development and morphology of the rat mammary gland are dependent upon several hormones including estrogens, androgens, progesterone, growth hormone and prolactin. In toxicology studies, treatment with xenobiotics may alter these hormones resulting in changes in the morphology of reproductive tissues such as the mammary gland. In the rat, male and female mammary glands exhibit striking morphologic differences that can be altered secondary to hormonal perturbations. Recognizing these morphologic changes can help the pathologist predict potential xenobiotic-induced perturbations in the systemic hormonal milieu. This review examines the development of the rat mammary gland and the influence of sex hormones on the morphology of the adult male and female rat mammary gland. Specific case examples from the literature and data from our laboratory highlight the dynamic nature of the rat mammary gland in response to hormonal changes.

Key Words: Endocrine disrupters • reproductive system • mammary gland • toxicologic pathology • rat pathology • preclinical safety-assessment/risk management • xenobiotics

Abbreviations: TEB, terminal end bud • E, estrogen • E2, estradiol • IGF-I, insulin -like growth factor one • PRL, prolactin • T, testosterone • P4, progesterone • GH, growth hormone • EGF, epidermal growth factor • DHT, dihydrotestosterone • Er, estrogen receptor alpha • Erβ, estrogen receptor beta • SERM, selective estrogen receptor modulator • LH, luteinizing hormone • FSH, follicular stimulating hormone • SD, Sprague-Dawley

	Development of the Rat Mammary Gland

TOP Abstract Development of the Rat... Study Designs and Collection... Unique Sex-Specific Morphology... Implications for Toxicology... Conclusion References

 
Embryologic development of the rat mammary gland has been investigated extensively and will only be briefly considered here (for reviews see Ceriani, 1970; Knight and Peaker, 1982; Russo et al., 1989c). The male and female rat mammary gland develops from a single layer of cuboidal epithelium, progressing in a cephalo-caudal sequence (Myers, 1917). Islands of epithelium thicken into hillocks of cuboidal cells resting on an indistinct basal membrane; simultaneously there is atrophy of the epithelial cells between the hillocks (Myers, 1917). In the male or female fetus, mammary glands remain as rudimentary buds of epithelium without development into distinct lobules or alveoli (Knight and Peaker, 1982).

In the rat fetus the importance of androgens in mammary gland development is well documented. Androgens initiate differentiation of the male phenotype by promoting atrophy of the rudimentary buds in the male (Goldman et al., 1976; Sourla et al., 1998a, 1998b). This atrophy of the buds is triggered by testosterone-induced condensation of the stroma (Topper and Freeman, 1980). Mammary gland morphology in the male rat is altered (feminization) to the morphology of the female rat if androgens are eliminated and androgens administered to female rat fetuses cause mammary glands to appear male-like (virilization) (Goldman et al., 1976). In contrast, the roles of estrogens (E) and progesterone (P4) in the rat fetus are less clear and their proposed function has been extrapolated from studies in mice and ex vivo mammary gland explants. Progesterone does not appear critical to embryonic development of mammary glands in mice and absence in utero does not affect the potential for maturation in adulthood (Freeman and Topper, 1978). Estrogens promote mammary gland development in the mouse fetus; however E inhibits development in the rat fetus (Ceriani, 1970).

The neonatal male and female rat has 6 pairs of glands with a central lactiferous duct, several branching secondary ducts and numerous tertiary ducts (Ceriani, 1970). The glands are distributed in pairs along the milk line, with 1 pair cervical, 2 thoracic, 1 abdominal and 2 inguinal (Astwood et al., 1937). Mammary tissue is embedded in a mass of adipocytes, pre-adipocytes and fibroblasts, referred to as the fat pad, with a thin layer of stroma separating the epithelial cells from the fat pad (Hovey et al., 1999; Silberstein, 2001; Imagawa et al., 2002). In the pre-pubescent female rat, mammary growth is mainly influenced by growth hormone (GH) and prolactin (PRL) with minimal influences of estradiol (E2) and P4 (Knight and Peaker, 1982).

Mammary growth in the male and female rat during puberty is dependent on normal gonadal function, as indicated by the absence of development in ovariectomized or gonadectomized rats (Cowie and Folley, 1961). To our knowledge, a detailed description of pubescent mammary gland development in males is not published. In females, growth of the mammary gland during puberty is characterized by differentiation of the epithelium into terminal end bud units (TEBs); rapid expansion by elongation and branching of the ducts; and hypertrophy of the fat pad (Cowie and Folley, 1961; Russo et al., 1989c; Knight and Peaker, 1982).

	Study Designs and Collection and Evaluation of Rat Mammary Glands

TOP Abstract Development of the Rat... Study Designs and Collection... Unique Sex-Specific Morphology... Implications for Toxicology... Conclusion References

 
In the evaluation of the rat mammary gland, a systematic approach to study design and sampling and processing of the mammary gland for histology is critical. The morphologic characteristics of the rat mammary gland are both site and age-specific (Russo et al., 1986, 1989a). For this reason, when designing studies it is important to use rats that are sexually mature at study start and to collect the same mammary gland pair at necropsy. In our laboratory, we examine the inguinal mammary gland pair and collect the gland with the overlying skin. Included in the trimmed section is the inguinal lymph node that can be used by the histologist as a landmark for slide preparation. Consistent sectioning is very helpful in the histologic evaluation of the rat mammary gland especially when evaluating mammary gland atrophy.

	Unique Sex-Specific Morphology of Rat Mammary Gland

TOP Abstract Development of the Rat... Study Designs and Collection... Unique Sex-Specific Morphology... Implications for Toxicology... Conclusion References

 
The mammary gland from preclinical species such as the mouse, beagle dog, and nonhuman primate do not exhibit significantly different microscopic morphology between the nonlactating adult female and male, only the quantity of glandular tissue is different (Richert et al., 2000). However, in the sexually mature rat there is a striking histologic divergence of male and female mammary glands (Table 1 and Figure 1). While these differences in female and male mammary gland morphology were first noted approximately 50 years ago (Ahren and Etienne, 1957), the observations and their potential mechanism have been given little attention in the literature except for a review by Cardy (1991) and a recent publication by Rudmann et al. (2005). For this reason, these differences are reviewed briefly next.

View larger version (988K): [in this window] [in a new window]   Figure 1 Mammary gland from sexually mature male and female rats. The mammary gland from the female rat is characterized by a predominance of ducts and few alveoli (A) compared to the male that is mostly lobules of alveoli (B). Intralobular ducts in females are lined by 1 layer of cuboidal epithelial cells with sparse cytoplasm (C) in contrast to ducts in males that have a stratified epithelium and epithelial cells with abundant, vacuolated cytoplasm (D). Occasionally, ducts and tubules with morphologic characteristics similar to those observed in female rats are observed in male rats subadjacent to normal male lobuloalveolar morphology and should not be diagnosed as feminization (E). Terminal end buds are structures observed commonly in sections of mammary gland from young rats and should not be confused with foci of hyperplasia (F). Hematoxylin and eosin; magnification 25x for A and B, 200x for C, D, and F, and 100x for E.

Ducts in females have a distinct lumina lined by a single layer of cuboidal epithelial cells that is surrounded by a myopepitheial tunic and thick basement membrane (Cardy, 1991; Masso-Welch et al., 2000). The alveolar buds appear as clusters of tubules with a central lumen, which is lined by cuboidal epithelium. Epithelial cells in ducts and alveoli of females have less cytoplasm than males that is basophilic. Mitoses and apoptotic cells are not observed. Terminal ducts are small, finger-shaped, with thin walls and wide lumens (Russo et al., 1989c). Male ducts and alveoli have a pseuodstratified or stratified epithelium and cells are larger with more abundant cytoplasm that is eosinophilic and usually vacuolated (Cardy, 1991; Rudmann et al., 2005). Apoptotic cells are observed in the epithelial lining as well as in alveolar and ductal lumina. In many cases alveolar and ductal epithelial cells fill the lumina of the male structures.

There are also other normal variations in the morphology of the male and female rat mammary gland that are important for interpreting experimental results. Terminal end buds as described earlier are normal structures that are commonly observed in sexually immature rats but are also observed in sexually mature rats (Figure 1). These structures should not be confused with foci of ductular or alveolar hyperplasia. Mammary gland morphology in the female is also influenced by the stage of estrus (Lotz and Krause, 1978) and if the stage of the female is not considered it is possible that the variation could be interpreted as a treatment-related change. For the male, tubular and ductal profiles with female-like characteristics are observed occasionally adjacent to normal male structures (Figure 1).

	Implications for Toxicology Studies

TOP Abstract Development of the Rat... Study Designs and Collection... Unique Sex-Specific Morphology... Implications for Toxicology... Conclusion References

 
It is important to recognize the morphologic differences between the mammary gland of normal adult male and female rats because, by virtue of its unique sexual dimorphism, the rat mammary gland may undergo morphologic changes indicating endocrine disruption (Table 2). The purpose of this section is to familiarize the pathologist with the different morphologic changes in the rat mammary gland that can occur with altered systemic hormone levels. Because of the complex interplay involved with maintaining hormonal homeostasis, effects on one hormone or its receptor will usually result in changes in multiple hormones. Therefore, the case studies provided below include examples of mammary gland changes observed with perturbation of single and multiple hormones. For the purpose of this review, the discussion and case studies will be limited to non-neoplastic mammary gland alterations observed in studies 6 months in duration.

Female rats from this study had multifocal or diffuse lobuloalveolar hyperplasia. Glands had an increased density of alveoli centered on ducts. Morphologic changes in both male and female rats were accompanied by elevated serum prolactin and estrogen levels (Biegel et al., 1998a; Cook et al., 1998), the former expected due to the positive regulation of pituitary prolactin secretion by estrogen (Nolin et al., 1977) (Table 3).

View larger version (1256K): [in this window] [in a new window]   Figure 2 Mammary gland from sexually mature male and female rats treated with vehicle (A-female, B-male), a xenobiotic that does not bind ER but causes hyperprolactinemia (C-female, D-male), and a xenobiotic that is an ER agonist and also causes hyperprolactinemia (E- female, F-male). Female mammary glands have lobuloalveolar hyperplasia and male mammary glands are feminized characterized by a tubuloalveolar appearance. Hematoxylin and eosin; magnification 200x.

Androgens
The male and female rat mammary gland, in contrast to the mouse mammary gland, develops and proliferates after puberty in response to androgens, GH, and IGF-1 (Topper et al., 1972; Kleinberg et al., 1990; Ruan et al., 1992; Feldman et al., 1993; Ruan et al., 1995, 1999). When T is administered to adult ovary intact female rats, the tubuloalveolar morphology of the mammary gland is altered to a more male-like lobuloalveolar appearance with ductal and alveolar dilatation and secretory activity (Selye et al., 1936; Laqueur and Fluhmann, 1942). Hypophysectomy ablates the mammary gland changes suggesting that pituitary hormones like PRL or GH are necessary for the effects (Laquer and Fluhmann, 1942). While PRL was not measured in these early studies, adult ovariectomized female rats and intact male rats given T have elevated circulating T, DHT, and PRL (O’Connor et al., 2000) (Table 3). When rats are treated with T, PRL secretion is likely stimulated because T is aromatized to E, a positive regulator of pituitary prolactin secretion (Nolin et al., 1977). Intact or ovariectomized female rats given the androgen DHT which is not aromatized to E do not have increases in serum prolactin but have changes in other hormones comparable to rats treated with T (Nolin et al., 1977) (Table 3).

Androgens in the absence of hyperprolactinemia cause virilization of the normal female gland. The tubuloalveolar morphology of the normal female mammary gland is converted to the lobuloalveolar morphology of the male mammary gland (Table 1, Figure 1). This alteration has been observed in ovariectomized female rats given non-aromatizable androgens (Sourla et al., 1998) and recently described in female ovary intact rats treated with a SERM (Rudmann et al., 2005) (Figure 3). For the SERM studies, female rats had hormonal changes including elevated E2 and T without changes in PRL or P4. While the mammary gland effects of increased E2 were blocked by the SERM, the effects of hyperandrogenemia were unopposed resulting in mammary gland virilization that could be blocked by the AR antagonist flutamide (Rudmann et al., 2005). SERM-treated rats did not have the increased ductal and alveolar secretions observed with T or DHT treatment presumably due to the lack of PRL elevation in SERM-treated rats (Rudmann et al., 2005).

View larger version (511K): [in this window] [in a new window]   Figure 3 Mammary gland from female F344 rats given vehicle (A), the SERM, LY2066948 (B), LY2066948 and flutamide (C), or flutamide alone (D). Intralobular ducts and alveoli from females given vehicle (A) or flutamide (D) are lined by a single layer of cuboidal epithelial cells with scant cytoplasm. Intralobular ducts in LY2066948-treated females (B) are lined by 2 or more layers of epithelial cells with abundant, vacuolated cytoplasm. LY2066948-treated rats given flutamide (C) have ducts and alveoli comparable to vehicle (A) or flutamide-treated (D) controls. Hematoxylin and eosin; magnification 200x.

Prolactin
PRL is synthesized in the pituitary and at a number of extra-pituitary sites including the rat mammary gland (Ben-Jonathon et al., 1996). PRL of pituitary origin promotes lobuloalveolar development and initiates milk production during pregnancy (Likhider et al., 1997; Harris et al., 2004). PRL is also produced locally in the mammary gland and is thought to have a role in lactogenesis i.e., in sustaining milk production (Harris et al., 2004). The action of PRL on the rat and mouse duct is inferred from evidence in mice in which genetic deletion of PRL in mice causes an absence of secondary branching of the ducts (Brisken C et al., 1999). PRL probably promotes ductal branching independently of E and synergistically with P4 by inducing local factors in the fat pad (Oka and Topper, 1972; Brisken et al., 1999; Daniel and Silberstein, 1987; Imagawa et al., 2002). While PRL may have effects on duct branching, several other hormones can promote duct development independently, including androgens, GH and EGF (Carsol et al., 2002; Gallego et al., 2001).

Dopaminergic receptor antagonists cause elevated PRL and mammary lobuloalveolar hyperplasia in female rats (Lotz and Krausse, 1978; O’Connor, 1996) (Table 3). Cardy (1991) described feminization of male rat mammary gland in males treated with a dopamine antagonist for 52 weeks. In these male rats, the lobuloalveolar appearance changed to the tubuloalveolar appearance of the female and there was increased secretory activity and duct ectasia (Cardy, 1991). There was no hormone data reported; however, we also recently observed mammary gland feminization in male rats with compounds that cause hyperprolactinemia and lobuloalveolar mammary gland hyperplasia in female rats (Figure 2C–D).

Feminization of the male gland consisted of loss of the normal male lobuloalveolar arrangement and development of a tubuloalveolar arrangement with an increased number of ducts and more abundant small alveoli lined by a low cuboidal epithelium surrounding small lumina. As reported by Cardy, at lower doses males had a blend of male and female mammary gland morphology. These data suggest that hyperprolactinemia by itself can produce mammary gland feminization in males and lobuloalveolar hyperplasia in females (Table 2). To our knowledge there are no reports of the effects of decreased prolactin on the mammary gland morphology of male and female rats.

Progesterone
Progesterone is important in the ductular and lobuloalveolar changes that occur in prepubescent development and pregnancy as indicated by studies in transgenic mice and P4 knockout animals. Ablation of PR in the female mouse causes a decrease in pregnancy-associated development and branching of the ductal epithelium, failure of alveologeneis and absence of ductal side-branching proteins, absence of terminal end buds, and inhibition of lobuloalveolar differentiation in response to E or P4 (Atwood et al., 2000; Conneely et al., 2000; Fernandez-Valdivia et al., 2005). However, P4 is not essential for the pubescent development of the mammary gland in the PR knockout mouse (Fernandez-Valdivia R et al., 2005). Transgenic mice with an excess of P4 receptor develop thick ducts with extensive lateral branching and large numbers of terminal buds, lined by cells that are multilayered and disorganized (Shyamala, 1999; Shyamala et al., 1999). The effects of progesterone on ductal development is synergistic with other hormones such as estrogen and IGF-1 (Ruan et al., 2005) and in the rat P4 acts synergistically with E2, PRL, and GH to promote duct growth (Kamiya et al., 1998).

In rats, the effects of blocking progesterone activity have been examined in adult ovary intact females given RU486 (Mifepristone), a potent PR antagonist (van der Schoot et al., 1987) (Table 3). In female rats administered RU486 for 4 weeks, there was mammary gland lobuloalveolar hyperplasia with increased secretions and the formation of large cysts filled with milk (van der Schoot et al., 1987). Serum concentrations of E2 and P4 were elevated and the pituitary gland was enlarged. These morphologic changes were consistent with those caused by hyperprolactinemia in female rats. While PRL was not measured in the van der Schoot study, Ruiz (1996) demonstrated that female rats given RU486 had approximately 4-fold increases in serum prolactin. Of note is that lobuloalveolar hyperplasia was observed despite complete antagonism of the PR receptor. The effects of RU486 on male rat mammary gland morphology were not described. Intact male rats treated with RU486 have increased serum FSH and LH concentrations (O’Connor et al., 2000).

Growth Hormone
The pituitary is required for mammary glandular development (Reece et al., 1936; Lewis et al., 1942). Pituitary secretion of GH stimulates TEB proliferation, IGF-1 mRNA production, and acts via GH receptors in the mammary gland stroma and fat pad (Kleinberg, 1997). The fat pad becomes hypertrophic and synthesizes growth regulatory molecules like IGF-1 and TEBs proliferate resulting in lengthening and increased branching of ducts in rats during puberty (Knight and Peaker, 1982; Russo et al., 1989c; Hovey et al., 1999).

Treatment of rats with hGH for 1 or 3 months causes mammary gland lobuloalveolar hyperplasia with secretory activity in male and female rats (Jorgensen et al., 1988). These changes are similar to those observed with hyperprolactinemia and GH is known to have prolactin-like activity in the rat (Peckham et al., 1967). There are no reports of the mammary gland effects of GH depletion in rats.

	Conclusion

TOP Abstract Development of the Rat... Study Designs and Collection... Unique Sex-Specific Morphology... Implications for Toxicology... Conclusion References

 
The normal male and female rat mammary gland has striking species specific differences in morphology. Morphologic changes in the normal mammary gland morphology provide important clues to the endocrine effects of xenobiotics (Table 3). Recognizing these morphologic patterns not only helps the toxicologic pathologist predict specific changes in the hormonal milieu but also helps the pathologist partner with the toxicologist and endocrinologist to define follow-up studies that directly test hypotheses around endocrine dysfunction.

	Footnotes

 
Both authors Lucas and Rudman contributed equally to this manuscript.

	References

TOP Abstract Development of the Rat... Study Designs and Collection... Unique Sex-Specific Morphology... Implications for Toxicology... Conclusion References

 

• Ahren, K, & Etieinne, M. (1957). The development of the mammary gland in normal and castrated male rats after the age of 21 days. Acta Physiol Scand, 41(2–3), 283-300[Web of Science][Medline] [Order article via Infotrieve]
• Astwood, EB, Geschickter, CF, & Rausch, EO. (1937). Development of the mammary gland of the rat. Amer J Anat, 61, 373-405[CrossRef]
• Atwood, CS, Hovey, RC, Glover, JP, Chepko, G, Ginsburg, E, Robison, WG, & Vonderhaar, BK. (2000). Progesterone induces side-branching of the ductal epithelium in the mammary glands of peripubertal mice. J Endocrinol, 167(1), 39-52[Abstract]
• Ben-Jonathon, N, Mershon, JL, Allen, DL, & Steinmetz, RW. (1996). Extrapituitary prolactin: distribution, regulation, functions and clinical aspects. Endocr Rev, 17, 639-69[Abstract/Free Full Text]
• Biegel, LB, Cook, LC, Hurtt, ME, & O’Connor, JC. (1998). Effects of 17 beta-estradiol on serum hormone concentrations and estrous cycle in female Crl:CD BR rats: effects on parental and first generation rats. Toxicol Sci, 44, 143-54[Abstract/Free Full Text]
• Biegel, LB, Flaws, JA, Hirshfield, AN, O’Connor, JC, Elliott, GS, Ladics, GS, Silbergeld, EK, Van Pelt, CS, Hurtt, ME, Cook, JC, & Frame, SR. (1998). 90-day feeding and one-generation reproduction study in Crl:CD BR rats with 17b-estradiol. Toxicol Sci, 44, 116-42[Abstract/Free Full Text]
• Brisken, C, Kaur, S, Chavarria, TE, Binart, N, Sutherland, RL, Weinberg, RA, Kelly, PA, & Ormandy, CJ. (1999). Prolactin controls mammary gland development via direct and indirect mechanisms. Develop Biol, 210(1), 96-106[CrossRef][Web of Science][Medline] [Order article via Infotrieve]
• Cardy, RH. (1991). Sexual dimorphism of the normal rat mammary gland. Vet Pathol, 28(2), 139-45[Abstract]
• Carsol, JL, Gingras, S, & Simard, J. (2002). Synergistic action of prolactin (PRL) and androgen on PRL-inducible protein gene expression in human breast cancer cells: a unique model for functional cooperation between signal transducer and activator of transcription-5 and androgen receptor. Mol Endocrinol, 16(7), 1696-710[Abstract/Free Full Text]
• Ceriani, RL. (1970). Fetal mammary gland differentiation in vitro in response to hormones. II. Biochemical findings. Develop Biol, 21(4), 530-46[CrossRef][Web of Science][Medline] [Order article via Infotrieve]
• Conneely, OM, Mulac-Jericevic, B, DeMayo, F, Lydon, JP, & O’Malley, BW. (2002). Reproductive functions of progesterone receptors. Recent Progr Hormone Res, 57, 339-55
• Cook, JC, Johnson, L, O’Connor, JC, Biegel, LB, Krams, CH, Frame, SR, & Hurtt, ME. (1998). Effects of dietary 17b-estradiol exposure on serum hormone concentrations and testicular parameters in male Crl:CD BR rats. Toxicol Sci, 44, 155-68[Abstract/Free Full Text]
• Cowie, AT, & Folley, SJ. In Young, WC (Ed.). (1961). The mammary gland and lactation. Sex and Internal Secretion, 1, (3) 590-641). Baltimore: Williams and Wilkins
• Daniel, CW, & Silberstein, GB. In Neville, MC, & Daniel, CW (Eds.). (1987). Postnatal development of the rodent mammary gland. The Mammary Gland: Development, Regulation and Function (pp.1-36). New York: Plenum Press
• Feldman, M, Ruan, W, Cunningham, BC, Wells, JA, & Kleinberg, DL. (1993). Evidence that the growth hormone receptor mediates differentiation and development of the mammary gland. Endocrinology, 133(4), 1602-8[Abstract/Free Full Text]
• Fernandez-Valdivia, R, Mukherjee, A, Mulac-Jericevic, B, Conneely, OM, DeMayo, FJ, Amato, P, & Lydon, JP. (2005). Revealing progesterone’s role in uterine and mammary gland biology: insights from the mouse. Sem Reproduct Med, 23(1), 22-37[CrossRef]
• Freeman, CS, & Topper, YJ. (1978). Progesterone and glucocorticoid in relation to the growth and differentiation of mammary epithelium. J Toxicol Environ Health, 4(2–3), 269-82[Web of Science][Medline] [Order article via Infotrieve]
• Gallego, MI, Binart, N, Robinson, GW, Okagaki, R, Coschigano, KT, Perry, J, Kopchick, JJ, Oka, T, Kelly, PA, & Hennighausen, L. (2001). Prolactin, growth hormone, and epidermal growth factor activate Stat5 in different compartments of mammary tissue and exert different and overlapping developmental effects. Develop Biol, 229(1), 163-75[CrossRef][Web of Science][Medline] [Order article via Infotrieve]
• Goldman, AS, Shapiro, B, & Neumann, F. (1976). Role of testosterone and its metabolites in the differentiation of the mammary gland in rats. Endocrinology, 99(6), 1490-5[Abstract/Free Full Text]
• Greaves, P, Goonetilleke, R, Nunn, G, Topham, J, & Orton, T. (1993). Two-year carcinogenicity study of tamoxifen in Alderley Park Wistar-derived rats. Cancer Res, 53(17), 3919-24[Abstract/Free Full Text]
• Harris, J, Stanford, PM, Oakes, SR, & Ormandy, CJ. (2004). Prolactin and the prolactin receptor: new targets of an old hormone. Ann Med, 36(6), 414-25[CrossRef][Web of Science][Medline] [Order article via Infotrieve]
• Hovey, RC, McFadden, TB, & Akers, RM. (1999). Regulation of mammary gland growth and morphogenesis by the mammary fat pad: a species comparison. J Mamm Gland Biol Neoplasia, 4(1), 53-68[CrossRef][Web of Science][Medline] [Order article via Infotrieve]
• Imagawa, W, Pedchenko, VK, Helber, J, & Zhang, H. (2002). Hormone/growth factor interactions mediating epithelial/stromal communication in mammary gland development and carcinogenesis. J Ster Biochem Mol Biol, 80(2), 213-30[CrossRef][Web of Science][Medline] [Order article via Infotrieve]
• Jorgensen, KD, Svendsen, O, Greenough, RJ, Kallesen, T, Goburdhun, R, Skydsgaard, K, Finch, J, Dinesen, B, & Nilsson, P. (1988). Biosynthetic human growth hormone: subchronic toxicity studies in rats and monkeys. Pharm Toxicol, 62, 329-33[Web of Science][Medline] [Order article via Infotrieve]
• Kamiya, K, Gould, MN, & Clifton, KH. (1998). Quantitative studies of ductal versus alveolar differentiation from rat mammary clonogens. Proc Soc Exper Biol & Med, 219(3), 217-25[CrossRef][Medline] [Order article via Infotrieve]
• Karlsson, S, Hirsimaki, Y, Mantyla, E, Nieminen, L, Kangas, L, Hirsimaki, P, Perry, CJ, Mulhern, M, Millar, P, Handa, J, & Williams, GM. (1996). A two-year dietary carcinogenicity study of the antiestrogen toremifene in Sprague–Dawley rats. Drug Chem Toxicol, 19, 245-66[Web of Science][Medline] [Order article via Infotrieve]
• Kennel, P, Pallen, C, Barale-Thomas, E, Espuna, G, & Bars, R. (2003). Tamoxifen: 28-day oral toxicity study in the rat based on the enhanced OECD test guideline 407 to detect endocrine effects. Arch Toxicol, 77, 487-99[CrossRef][Web of Science][Medline] [Order article via Infotrieve]
• Kleinberg, DL. (1997). Early mammary development: growth hormone and IGF-1. J Mamm Gland Biol Neoplasia, 2(1), 49-57[CrossRef][Medline] [Order article via Infotrieve]
• Kleinberg, DL, Ruan, W, Catanese, V, Newman, CB, & Feldman, M. (1990). Non-lactogenic effects of growth hormone on growth and insulin-like growth factor-I messenger ribonucleic acid of rat mammary gland. Endocrinology, 126(6), 3274-6[Abstract/Free Full Text]
• Knight, CH, & Peaker, M. (1982). Development of the mammary gland. J Reproduct Fertil, 65(2), 521-36[Abstract/Free Full Text]
• Laqueur, GL, & Fluhmann, CF. (1942). Effects of testosterone propionate in immature and adult female rats. Endocrinology, 30, 93-101[Abstract/Free Full Text]
• Lewis, AA, Gomez, ET, & Turner, CW. (1942). Mammary gland development with mammogen I in the castrated and the hypophysectomized rat. Endocrinology, 30, 34-47
• Lkhider, M, Delpal, S, Le Provost, F, & Ollivier-Bousquet, M. (1997). Rat prolactin synthesis by lactating mammary epithelial cells. FEBS Lett, 401(2–3), 117-22[CrossRef][Web of Science][Medline] [Order article via Infotrieve]
• Lotz, W, & Krause, R. (1978). Correlation between the effects of neuroleptics on prolactin release, mammary stimulation and the vaginal cycle in rats. J Endocr, 76, 507-15[Abstract/Free Full Text]
• Masso-Welch, PA, Darcy, KM, Stangle-Castor, NC, & Ip, MM. (2000). A developmental atlas of rat mammary gland histology. J Mamm Gland Biol Neoplasia, 5(2), 165-85[CrossRef][Web of Science][Medline] [Order article via Infotrieve]
• Myers, JA. (1917). Studies of the mammary gland II. The fetal development of the mammary gland in the female albino rat. Amer J Anat, 22, 195-223[CrossRef]
• Nolin, JM, Campbell, GT, Nansel, DD, & Bogdanove, EM. (1977). Does androgen influence prolactin secretion? Endocr Res Comm, 4, 61-70
• O’Connor, JC, Cook, JC, Craven, SC, Van Pelt, CS, & Obourn, JD. (1996). An in vivo battery for identifying endocrine modulators that are estrogenic or dopamine regulators. Fund Appl Toxicol, 33, 182-95[CrossRef][Web of Science][Medline] [Order article via Infotrieve]
• O’Connor, JC, Davis, LG, Frame, SR, & Cook, JC. (2000). Evaluation of a Tier 1 screening battery for detecting endocrine-active compounds (EACs) using the positive controls testosterone, coumestrol, progesterone, and RU486. Toxicol Sci, 54, 338-54[Abstract/Free Full Text]
• O’Connor, JC, Frame, SR, Biegel, LB, Cook, JC, & Davis, LG. (1998). Sensitivity of a Tier I screening battery compared to an in utero exposure for detecting the estrogen receptor agonist 17 beta-estradiol. Toxicol Sci, 44, 169-84[Abstract/Free Full Text]
• O’Connor, JC, Frame, SR, & Ladics, GS. (2002). Evaluation of a 15-day screening assay using intact male rats for identifying steroid biosynthesis inhibitors and thyroid modulators. Toxicol Sci, 69, 79-91[Abstract/Free Full Text]
• O’Connor, JC, Frame, SR, & Ladics, GS. (2002). Evaluation of a 15-day screening assay using intact male rats identifying antiandrogens. Toxicol Sci, 69, 92-108[Abstract/Free Full Text]
• Oka, T, & Topper, YJ. (1972). Is prolactin mitogenic for mammary epithelium? Proc Natl Acad Sci USA, 69(7), 1693-6[Abstract/Free Full Text]
• Peckham, WD, Hotchkiss, J, Knobil, E, & Nicoll, CS. (1968). Prolactin activity of homogenous primate growth hormone preparations. Endocrinology, 82, 1247[Abstract/Free Full Text]
• Reece, RP, Turner, CW, & Hill, RT. (1936). Mammary gland development in the hypophysectomized albino rat. Proc Soc Exp Biol Med, 34, 204-17[CrossRef]
• Richert, MM, & Wood, TL. (1999). The insulin-like growth factors (IGF) and IGF type I receptor during postnatal growth of the murine mammary gland: sites of messenger ribonucleic acid expression and potential functions. Endocrinology, 140(1), 454-61[Abstract/Free Full Text]
• Ruan, W, & Kleinberg, DL. (1999). Insulin-like growth factor I is essential for terminal end bud formation and ductal morphogenesis during mammary development. Endocrinology, 140(11), 5075-81[Abstract/Free Full Text]
• Ruan, W, Monaco, ME, & Kleinberg, DL. (2005). Progesterone stimulates mammary gland ductal morphogenesis by synergizing with and enhancing insulin-like growth factor-I action. Endocrinology, 146(3), 1170-8[Abstract/Free Full Text]
• Ruan, W, Newman, CB, & Kleinberg, DL. (1992). Intact and aminoterminally shortened forms of insulin-like growth factor I induce mammary gland differentiation and development. Proc Natl Acad Sci USA, 89(22), 10872-6[Abstract/Free Full Text]
• Ruan, W, Catanese, V, Wieczorek, R, Feldman, M, & Kleinberg, DL. (1995). Estradiol enhances the stimulatory effect of insulin-like growth factor-I (IGF-I) on mammary development and growth hormone-induced IGF-I messenger ribonucleic acid. Endocrinology, 136(3), 1296-302[Abstract]
• Ruiz, A, Aguilar, R, Tebar, M, Gaytan, F, & Sanchez-Criado, JE. (1996). RU486-treated rats show endocrine and morphologic responses to therapies analogous to responses of women with polycystic ovary syndrome treated with similar therapies. Biol Reprod, 55, 1284-91[Abstract]
• Rudmann, DG, Cohen, IR, Robbins, MR, Coutant, DE, & Henck, JW. (2005). Androgen dependent mammary gland virilism in rats given the selective estrogen receptor modulator LY2066948 hydrochloride. Toxicol Pathol, 33(6), 711-19[Abstract/Free Full Text]
• Russo, IH, Pokorzynski, T, & Russo, J. (1986). Asynchronous development of the rat mammary glands: a determining factor in carcinogenesis. Breast Cancer Res Treat, 8, 118a
• Russo, IH, Gimotty, P, Dupuis, M, & Russo, J. (1989a). Effect of medoxyprogesterone acetate on the response of the rat mammary gland to carcinogenesis. Brit J Canc, 59(2), 210-16
• Russo, IH, Medado, J, & Russo, J. In Jones, TC, Mohr, U, & Hunt, RD (Eds.). (1989b). Endocrine Influences on the Mammary Gland. Monographs on Pathology of Laboratory Animals (pp.33, Berlin: Springer-Verlag
• Russo, IH, Tewari, M, & Russo, J. In Jones, TC, Mohr, U, & Hunt, RD (Eds.). (1989c). Morphology and development of the rat mammary gland. Monographs on Pathology of Laboratory Animals (pp.233, Berlin: Springer-Verlag
• Selye, H, McEuen, CS, & Collip, JB. (1936). Effect of testosterone on the mammary gland. Proceedings of the Society of Experimental Biology, 34, 201-203
• Shyamala, G. (1999). Progesterone signaling and mammary gland morphogenesis. J Mamm Gland Biol Neoplasia, 4(1), 89-104[CrossRef][Web of Science][Medline] [Order article via Infotrieve]
• Shyamala, G, Louie, SG, Camarillo, IG, & Talamantes, F. (1999). The progesterone receptor and its isoforms in mammary development. Mol Genet Metabol, 68(2), 182-90[CrossRef][Web of Science][Medline] [Order article via Infotrieve]
• Silberstein, GB. (2001). Postnatal mammary gland morphogenesis. Microsc Res Techn, 52(2), 155-62[CrossRef][Web of Science][Medline] [Order article via Infotrieve]
• Sourla, A, Martel, C, Labrie, C, & Labrie, F. (1998). Almost exclusive androgenic action of dehydroepiandrosterone in the rat mammary gland. Endocrinology, 139(2), 753-64[Abstract/Free Full Text]
• Sourla, A, Flamand, M, Belanger, A, & Labrie, F. (1998). Effect of dehydroepiandrosterone on vaginal and uterine histomorphology in the rat. J Steroid Biochem Mol Biol, 66(3), 137-49[CrossRef][Web of Science][Medline] [Order article via Infotrieve]
• Topper, YJ, & Freeman, CS. (1980). Multiple hormone interactions in the developmental biology of the mammary gland. Physiol Rev, 60(4), 1049-106[Free Full Text]
• Topper, YJ, Oka, T, Owens, IS, & Vonderhaar, BK. (1972). Some aspects of mouse mammary gland development from maturity to early pregnancy. In Vitro, 8(3), 228-36[Web of Science][Medline] [Order article via Infotrieve]
• Toyoda, K, Shibutani, M, Tamura, T, Koujitani, T, Uneyama, C, & Hirose, M. (2000). Repeated dose (28 days) oral toxicity study of flutamide in rats, based on the draft protocol for the ‘Enhanced OECD Test Guideline 407’ for screening endocrine-disrupting chemicals. Arch Toxicol, 74, 127-32[CrossRef][Web of Science][Medline] [Order article via Infotrieve]
• Van Der Schoot, P, Bakker, GH, & Klijn, JGM. (1987). Effects of the progesterone antagonist RU486 on ovarian activity in the rat. Endocrinology, 121, 1375-82[Abstract/Free Full Text]
• Wang, XJ, Bartolucci-Page, E, Fenton, SE, & You, L. (2005). Altered mammary gland development in male rats exposed to genistein and methoxychlor. Toxicol Sci, 91, 93-103[Web of Science]

Toxicologic Pathology, Vol. 35, No. 2, 199-207 (2007)
DOI: 10.1080/01926230601156260


CiteULike    Connotea    Del.icio.us    Digg    Reddit    Technorati    What's this?

This Article Abstract Free Full Text (Free PDF) Free Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Add to Saved Citations Download to citation manager Request Permissions Request Reprints Add to My Marked Citations Citing Articles Citing Articles via Google Scholar Citing Articles via Scopus Google Scholar Articles by Lucas, J. N. Articles by Snyder, P. W. Search for Related Content PubMed PubMed Citation Articles by Lucas, J. N. Articles by Snyder, P. W. Pubmed/NCBI databases Compound via MeSH Substance via MeSH Medline Plus Health Information Hormones Hazardous Substances DB PROGESTERONE Social Bookmarking                   What's this?