Endocrine and autocrine prolactin (PRL) exerts effects on normal breast and breast cancer cells, and high serum PRL is a poor prognostic factor for colorectal cancer. Here we tested the hypothesis that short isoforms of the PRL receptor (PRLR) in human tissue regulate the actions of PRL in cancer. Using 3′ RACE we isolated five splice variants of the human PRLR (hPRLR), three of which encode the complete extracellular binding domain. Two of these isoforms, short form 1a (SF1a) and short form 1b (SF1b), possess unique intracellular domains encoded by splicing to exon 11 from exons 10 and 9 respectively. A third novel isoform (∆7/11) reflects alternative splicing from exon 7 to exon 11 and encodes a secreted soluble PRL-binding protein. Additional splice variants of SF1b and ∆7/11 that lacked exon 4 (∆4-SF1b and ∆4-∆7/11) were also identified. Functional analyses indicated that hPRLR-SF1b is a strong dominant-negative to the differentiative function of the PRLR long form while hPRLR-SF1a is a weaker dominant-negative. Differential abundance of SF1a, SF1b and ∆7/11 expression was detected in normal breast, colon, placenta, kidney, liver, ovary and pancreas, and breast and colon tumors. Taken together, these data indicate the presence of multiple isoforms of the hPRLR that may function to modulate the endocrine and autocrine effects of PRL in normal human tissue and cancer.
Development of the functional secretory epithelium in the mammary gland of the female mouse requires the elongation of the anlage through the mammary fat pad to form the primary/secondary ductal network from which tertiary ductal side-branches and lobuloalveoli develop. In this study we examined the hormonal requirements for the spatial development of the primary/secondary epithelial network and tertiary side-branches by quantifying ductal growth and epithelial cell proliferation in normal and hormone-treated BALB/c mice between 21 and 39 days of age. In normal mice, an allometric increase in ductal length commenced at 31 days of age and resulted in completion of the primary/secondary ductal network by 39 days of age. Concurrent with this allometric growth was a significant increase in cellular proliferation in the terminal end-buds (TEBs) of the ductal epithelium from 29 days of age, as determined by 5-bromo-2 -deoxyuridine (BrdU) incorporation. A level of cellular proliferation similar to that in the TEBs of 33-day-old control mice could be induced in the TEBs of 25-day-old mice following treatment for 1 day with estrogen (E), or progesterone (P) or both (E/P), indicating that both E and P were mitogenic for epithelial cells of the peripubertal TEBs. However, the period of allometric ductal growth in untreated mice did not correspond to an increase in serum E or P (which might have been expected during the estrous cycle). In addition, epithelial growth was not observed in mammary glands from 24-day-old mice that were cultured in vitro with E, P or E/P. In contrast to treatment with E, treatment with P promoted a dramatic increase, relative to control mice, in the number of tertiary branch points upon the primary/secondary ductal network. BrdU labeling of mammary glands from 24-33-day-old mice pelleted with cholesterol (C), E, P or E/P confirmed the greater mitogenicity of P on the epithelial cells of the secondary/tertiary ducts as compared with C or E. Concurrent with these changes, localized progesterone receptor (PR) expression in clusters of cells in the ductal epithelium was associated with structures that histologically resembled early branch points from ductules. In conclusion, our results suggest that additional endocrine growth factor(s) other than E and P contribute to the development of the primary/secondary ductal network, and that P is responsible for the formation of tertiary side-branches in the mammary glands of mice during puberty.
Epithelial-Mesenchymal Transition (EMT) is a process occurring during both embryogenesis and early stages of invasive cancer. Epithelial cells that undergo EMT become more migratory and invasive with a mesenchymal morphology. Herein we assess EMT induction in a mouse mammary epithelial cell line driven by Msx2, a homeobox-containing transcription factor important during mammary gland development. NMuMG cells, a normal mouse mammary epithelial cell line, stably-transfected with a Msx2 cDNA showed downregulation of an epithelial marker E-cadherin and upregulation of the mesenchymal markers vimentin and N-cadherin. Furthermore, overexpression of Cripto-1, a member of the epidermal growth factor-CFC protein family already known to be involved in EMT, was detected in Msx2-transfected cells. The expression of Cripto-1 was accompanied by activation of the tyrosine kinase c-Src pathway and an increase in the invasive ability of the cells. Functional assays also demonstrated inhibition of the invasive behavior of the Msx2-transfected cells by a c-Src specific inhibitor. Moreover, immunohistochemistry of human infiltrating breast carcinomas showed positive staining for Msx2 only in the infiltrating tumor cells while the non-infiltrating tumor cells were negative. These results suggest that Msx2 may play a significant role in promoting EMT in epithelial cells that acquire properties involved in tumor invasion.
Background: The normal growth and function of mammary epithelial cells depend on interactions with the supportive stroma. Alterations in this communication can lead to the progression or expansion of malignant growth. The human mammary gland contains two distinctive types of fibroblasts within the stroma. The epithelial cells are surrounded by loosely connected intralobular fibroblasts, which are subsequently surrounded by the more compacted interlobular fibroblasts. The different proximity of these fibroblasts to the epithelial cells suggests distinctive functions for these two subtypes. In this report, we compared the gene expression profiles between the two stromal subtypes.
Mammary glands from second generation vitamin D-deficient mice and rats were examined for their ability to make the major milk proteins, casein and a-lactalbumin, both in vivo and in vitro. The glands from the rachitic animals were morphologically indistinguishable from those of age-matched controls. When placed in explant culture, glands from vitamin D-deficient mice and rats underwent DNA synthesis at a rate comparable to that of glands from the vitamin D-replete controls. However, the hormonally induced synthesis of casein and a-lactalbumin was significantly reduced in explants of glands from rachitic us. control animals. The reduction in caseinsynthesizing ability by mouse mammary gland explants was not reversed by the addition of 10~8 or 10~6 M 1,25-dihydroxycholecalciferol to the culture medium, but could be reversed by pretreating the vitamin D-deficient mice with the D metabolite in vivo for 10 days before the onset of culture. The decrease in milk protein synthesis in culture is paralleled in vivo by a decrease in milk protein content in the milk and lactating mammary glands of vitamin D-deficient mice and rats. Both in vivo and in vitro, it is the two highest mol wt caseins that are most affected by the lack of vitamin D in the diet. These data suggest that vitamin D does not play a fundamental role in growth and morphological development of the normal mammary gland, but, rather, it is important in maintenance of full hormonally induced functional differentiation of the mature gland. (Endocrinology 121:865-874,1987)
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