Over-expression of an endogenous milk protein gene in transgenic mice is associated with impaired mammary alveolar development and a milchlos phenotype.

The whey acidic protein (WAP) gene is expressed in mammary epithelial cells at late pregnancy and throughout lactation. We have generated transgenic mice in which a mouse WAP transgene is expressed precociously in pregnancy. From 13 founder mice bearing WAP transgenes, two female founders and the daughters from a male founder failed to lactate and nurture their offspring. We named this phenotype milchlos. Mammary tissue from postpartum milchlos mice was underdeveloped, contained too few alveoli and resembled the glands of non-transgenic mid-pregnant mice. The hypothesis that alveolar development in milchlos mice was functionally arrested in a prelactational state is consistent with low levels of alpha-lactalbumin mRNA, and an unidentified keratin RNA in mammary tissue from postpartum mice. Defects in alveolar function in milchlos mice were detected at mid-pregnancy; in non-transgenic mice, WAP was secreted into the alveolar lumen but remained preferentially in the cytoplasm of the alveolar epithelial cells in the milchlos mice. Since deregulated WAP expression resulted in impaired mammary development, it is possible that WAP plays a regulatory role in the terminal differentiation and development of mammary alveolar cells.     

Regulatory function of whey acidic protein in the proliferation of mouse mammary epithelial cells in vivo and in vitro

Although possible biological functions of whey acidic protein (WAP) have been suggested, few studies have focused on investigating the function of WAP. This paper describes evidence for WAP function in lobulo-alveolar development in mammary glands in vivo and in the cell cycle progression of mammary epithelial cells in vitro. Ubiquitous overexpression of WAP transgene impaired only lobulo-alveolar development in the mammary glands of transgenic female mice but not other physiological functions, indicating that the inhibitory function of WAP is specific to mammary alveolar cells. The forced expression of WAP significantly inhibited the proliferation of mouse mammary epithelial cells (HC11 cells and EpH4/K6 cells), whereas it did not affect that of NIH3T3 cells. Co-culturing of WAP-clonal cells and control cells using a transwell insert demonstrated that WAP inhibited the proliferation of HC11 cells through a paracrine action but not that of NIH3T3 cells, and that WAP was able to bind to HC11 cells but not to NIH3T3 cells. Apoptosis was not enhanced in the HC11 cells with stable WAP expression (WAP-clonal HC11 cells). BrdU incorporation and FACScan analyses revealed that cell cycle progression from the G0/G1 to the S phase was inhibited in the WAP-clonal HC11 cells. Among G1 cyclins, the expression of cyclin D1 and D3 was significantly decreased in the WAP-clonal HC11 cells. The present results provide the first documented evidence that WAP plays a negative regulatory role in the cell cycle progression of mammary epithelial cells through an autocrine or paracrine mechanism in vivo.     

A transgenic mouse model for investigating the response of the upstream region of whey acidic protein (WAP) gene to various steroid hormones.

The limitations of studies of clarification of response elements of whey acidic protein (WAP) gene to hormones using mammary cell lines has been shown. We studied the response of the upstream region (2.6 kb) of WAP to various steroid hormones using gonadectomized mWAP/hGH transgenic mice. Ovariectomy or castration for transgenic mice was performed at 10 days or 30 days post partum. Various steroid hormones were administered daily for 10 days to the gonadectomized transgenic mice after they reached 2 months of age. Prior to the hormonal administration and 24 hr after the final administration, blood was collected and the hGH levels in the plasma was measured by RIA. Daily doses of estradiol-17 beta were significantly more effective at increasing hGH levels in transgenic females ovariectomized at 10 days post partum than progesterone of an equal dose. A combined dose of progesterone and of estradiol-17 beta significantly amplified the increase of hGH levels accompanied by the great development of mammary glands, compared to a dose of progesterone alone. Corticosterone induced only a slight increase of hGH, while testosterone had no effect. The doses of gonadal steroid hormones did not induce an increase in hGH levels and development of mammary glands in the castrated transgenic males. The results showed that the response of 5' region of WAP requires at least some extended development of the mammary gland and that the 2.6 kb upstream region of the exogenous WAP gene contained the element responsive to ovarian hormones.     

Targeting expression of a transforming growth factor beta 1 transgene to the pregnant mammary gland inhibits alveolar development and lactation.

Transforming growth factor-beta 1 (TGF-beta 1) possesses highly potent, diverse and often opposing cell-specific activities, and has been implicated in the regulation of a variety of physiologic and developmental processes. To determine the effects of in vivo overexpression of TGF-beta 1 on mammary gland function, transgenic mice were generated harboring a fusion gene consisting of the porcine TGF-beta 1 cDNA placed under the control of regulatory elements of the pregnancy-responsive mouse whey-acidic protein (WAP) gene. Females from two of four transgenic lines were unable to lactate due to inhibition of the formation of lobuloalveolar structures and suppression of production of endogenous milk protein. In contrast, ductal development of the mammary glands was not overtly impaired. There was a complete concordance in transgenic mice between manifestation of the lactation-deficient phenotype and expression of RNA from the WAP/TGF-beta 1 transgene, which was present at low levels in the virgin gland, but was greatly induced at mid-pregnancy. TGF-beta 1 was localized to numerous alveoli and to the periductal extracellular matrix in the mammary gland of transgenic females late in pregnancy by immunohistochemical analysis. Glands reconstituted from cultured transgenic mammary epithelial cells duplicated the inhibition of lobuloalveolar development observed in situ in the mammary glands of pregnant transgenic mice. Results from this transgenic model strongly support the hypothesis that TGF-beta 1 plays an important in vivo role in regulating the development and function of the mammary gland.     

Synthesis and secretion of the mouse whey acidic protein in transgenic sheep

The synthesis of foreign proteins can be targeted to the mammary gland of transgenic animals, thus permitting commercial purification of otherwise unavailable proteins from milk. Genetic regulatory elements from the mouse whey acidic protein (WAP) gene have been used successfully to direct expression of transgenes to the mammary gland of mice, goats and pigs. To extend the practical usefulness of WAP promoter-driven fusion genes and further characterize WAP expression in heterologous species, we introduced a 6.8 kb DNA fragment containing the genomic form of the mouse WAP gene into sheep zygotes. Two lines of transgenic sheep were produced. The transgene was expressed in mammary tissue of both lines and intact WAP was secreted into milk at concentrations estimated to range from 100 to 500 mg/litre. Ectopic WAP gene expression was found in salivary gland, spleen, liver, lung, heart muscle, kidney and bone marrow of one founder ewe. WAP RNA was not detected in skeletal muscle and intestine. These data suggest that unlike pigs, sheep may possess nuclear factors in a variety of tissues that interact with WAP regulatory sequences. Though the data presented are based on only two lines, these findings suggest WAP regulatory sequences may not be suitable as control elements for transgenes in sheep bioreactors.     

Establishment of La-tPA/G-CSF dual transgenic mice and expression in their mammary gland

Expression vectors of human granulocyte colony stimulating factor (G-CSG) and long acting tissue plasminogen activator (La-tPA) in mammary gland were constructed using promoters of mouse whey acid protein gene (WAP) and sheep β-lactoglobulin gene (BLG) with sizes of 2.6 and 5 kb respectively. Two kinds of transgenic mice of G-CSF and La-tPA were produced with microinjection. The expression of G-CSF and La-tPA was achieved in mammary glands of transgenic mice, respectively. In order to establish dual transgenic mice of La-tPA/G-CSF, transgenic mice carrying G-CSF and La-tPA gene characterized with specific expression in mammary gland were mated. La-tPA/G-CSF dual transgenic mice were screened out from the hybrid offspring by Once-PCR. The co-expression of La-tPA and G-CSF in mammary gland of the dual transgenic mice was confirmed by the milk assayed and Northern blot analysis. Some parameters about the dual transgenic mice indicated that there were fewer litters than that of normal mice. The ratio of du     

Establishment of La-tPA/G-CSF dual transgenic mice and expression in their mammary gland

Expression vectors of human granulocyte colony stimulating factor (G-CSG) and long acting tissue plasminogen activator (La-tPA) in mammary gland were constructed using promoters of mouse whey acid protein gene (WAP) and sheep β-lactoglobulin gene (BLG) with sizes of 2.6 and 5 kb respectively. Two kinds of transgenic mice of G-CSF and La-tPA were produced with microinjection. The expression of G-CSF and La-tPA was achieved in mammary glands of transgenic mice, respectively. In order to establish dual transgenic mice of La-tPA /G-CSF, transgenic mice carrying G-CSF and La-tPA gene characterized with specific expression in mammary gland were mated. La-tPA/G-CSF dual transgenic mice were screened out from the hybrid offspring by Once-PCR. The co-expression of La-tPA and G-CSF in mammary gland of the dual transgenic mice was confirmed by the milk assayed and Northern blot analysis. Some parameters about the dual transgenic mice indicated that there were fewer litters than that of normal mice. The ratio of dual transgenes was 46.1% in F1 generation, and offspring’s sex ratio was normal. Hence a dual transgenic mouse model was established for the study of co-expression foreign proteins in mammary gland.     

Cre-mediated gene deletion in the mammary gland.

To delete genes specifically from mammary tissue using the Cre-lox system, we have established transgenic mice expressing Cre recombinase under control of the WAP gene promoter and the MMTV LTR. Cre activity in these mice was evaluated by three criteria. First, the tissue distribution of Cre mRNA was analyzed. Second, an adenovirus carrying a reporter gene was used to determine expression at the level of single cells. Third, tissue specificity of Cre activity was determined in a mouse strain carrying a reporter gene. In adult MMTV-Cre mice expression of the transgene was confined to striated ductal cells of the salivary gland and mammary epithelial cells in virgin and lactating mice. Expression of WAP-Cre was only detected in alveolar epithelial cells of mammary tissue during lactation. Analysis of transgenic mice carrying both the MMTV-Cre and the reporter transgenes revealed recombination in every tissue. In contrast, recombination mediated by Cre under control of the WAP gene promoter was largely restricted to the mammary gland but occasionally observed in the brain. These results show that transgenic mice with WAP-Cre but not MMTV-Cre can be used as a powerful tool to study gene function in development and tumorigenesis in the mammary gland.     

RT-PCR测定组织纤溶酶原激活剂突变体(La-tPA)在转基因鼠乳腺表达的研究

利用所构建的乳腺表达组织纤溶酶原激活剂突变体（Ｌａ－ｔＰＡ）载体．对５４０枚小鼠受精卵进行显微注射,经ＰＣＰ和Ｓｏｕｔｈｅｒｎｂｌｏｔ检测,获得６只整合有人Ｌａ－ｔＰＡ转基因小鼠．为了精确研究转基因在小鼠体内的表达,采用ＲＴ－ＰＣＰ方法测定转基因鼠在泌乳期１～２０ｄＬａ－ｔＰＡ基因的转录,结果表明,在转基因鼠乳腺的Ｌａ－ｔＰＡｍＲＮＡ水平在１０～１５ｄ最高,在２０ｄ时降为最低．外源基因在转基因小鼠乳腺的表达规律研究为未来利用转基因动物生产Ｌａ－ｔＰＡ提供依据     

Cold-inducible RNA binding protein in mouse mammary gland development

RNA binding proteins (RBPs) regulate gene expression by controlling mRNA export, translation, and stability. When altered, some RBPs allow cancer cells to grow, survive, and metastasize. Cold-inducible RNA binding protein (CIRP) is overexpressed in a subset of breast cancers, induces proliferation in breast cancer cell lines, and inhibits apoptosis. Although studies have begun to examine the role of CIRP in breast and other cancers, its role in normal breast development has not been assessed. We generated a transgenic mouse model overexpressing human CIRP in the mammary epithelium to ask if it plays a role in mammary gland development. Effects of CIRP overexpression on mammary gland morphology, cell proliferation, and apoptosis were studied from puberty through pregnancy, lactation and weaning. There were no gross effects on mammary gland morphology as shown by whole mounts. Immunohistochemistry for the proliferation marker Ki67 showed decreased proliferation during the lactational switch (the transition from pregnancy to lactation) in mammary glands from CIRP transgenic mice. Two markers of apoptosis showed that the transgene did not affect apoptosis during mammary gland involution. These results suggest a potential in vivo function in suppressing proliferation during a specific developmental transition.     

转基因动物乳腺暂时性表达系统的建立

以乳清酸蛋白(WAP)基因5′区为调控序列,人基因组G-CSF基因为目的片段,同时将WAP基因第一内含子插入G-CSF基因5′端,构建成转基因动物乳腺表达载体。将其直接注射到小鼠乳腺,在泌乳期表达出人G-CSF。表明乳腺直接注射质粒的方法可以做为暂时性的一种表达系统,同时也表明内含子对表达有一定的作用。     

Expression of Human NSAID Activated Gene 1 in Mice Leads to Altered Mammary Gland Differentiation and Impaired Lactation

Transgenic mice expressing human non-steroidal anti-inflammatory drug activated gene 1 (NAG-1) have less adipose tissue, improved insulin sensitivity, lower insulin levels and are resistant to dietary induced obesity. The hNAG-1 expressing mice are more metabolically active with a higher energy expenditure. This study investigates female reproduction in the hNAG-1 transgenic mice and finds the female mice are fertile but have reduced pup survival after birth. Examination of the mammary glands in these mice suggests that hNAG-1 expressing mice have altered mammary epithelial development during pregnancy, including reduced occupancy of the fat pad and increased apoptosis via TUNEL positive cells on lactation day 2. Pups nursing from hNAG-1 expressing dams have reduced milk spots compared to pups nursing from WT dams. When CD-1 pups were cross-fostered with hNAG-1 or WT dams; reduced milk volume was observed in pups nursing from hNAG-1 dams compared to pups nursing from WT dams in a lactation challenge study. Milk was isolated from WT and hNAG-1 dams, and the milk was found to have secreted NAG-1 protein (approximately 25 ng/mL) from hNAG-1 dams. The WT dams had no detectable hNAG-1 in the milk. A decrease in non-esterified free fatty acids in the milk of hNAG-1 dams was observed. Altered milk composition suggests that the pups were receiving inadequate nutrients during perinatal development. To examine this hypothesis serum was isolated from pups and clinical chemistry points were measured. Male and female pups nursing from hNAG-1 dams had reduced serum triglyceride concentrations. Microarray analysis revealed that genes involved in lipid metabolism are differentially expressed in hNAG-1 mammary glands. Furthermore, the expression of Cidea/CIDEA that has been shown to regulate milk lipid secretion in the mammary gland was reduced in hNAG-1 mammary glands. This study suggests that expression of hNAG-1 in mice leads to impaired lactation and reduces pup survival due to altered milk quality and quantity.     

Quantitative collection of milk and active recombinant proteins from the mammary glands of transgenic mice

Summary

Transgenic mice expressing foreign genes specifically in their mammary glands have been obtained by several groups in the world. The mouse is generally considered as a good reference animal to evaluate the efficiency of gene constructs to be used in larger mammals for the preparation of the corresponding recombinant proteins at an industrial scale. The method described here shows that mammary glands from lactating mice separated from their pups for one day spontaneously released 1.5 ml milk when stored at O'C. The proteins of milk obtained by this method were essentially similar to those obtained after milking. Human growth hormone (hGH) gene under the control of the rabbit whey acidic (WAP) gene promoter was expressed at a high level in the milk of transgenic mice (4 mg/ml milk in the mice examined here). hGH was present in milk obtained after milking or after the incubation of the mammary glands at O'C. In both cases, the hormone was present in essentially similar concentration, undegraded and biologically active (as judged by its prolactin‐like activity). The method depicted here is very simple and can be applied easily to many mice. Its major limitation is that it implies the breeding and the sacrifice of a relatively large number of animals. One gram of crude recombinant protein can be virtually obtained in this way with about 200 lactating mice from their milk containing the proteins at the concentration of 3‐4 mg/ml. The milk of transgenic mice can therefore be considered as a practical source of recombinant proteins for biochemical and pharmaceutical studies.     

Breast cancer protein PS2 synthesis in mammary gland of transgenic mice and secretion into milk

PS2, a small estrogen-inducible secretory polypeptide with structural analogies to a growth factor, is produced by approximately 50% of human breast tumors. The function of PS2 is, however, unknown. To determine whether PS2 may play an autocrine role in the development of mammary tumors we constructed transgenic mice bearing fusion constructs designed to direct the expression of human PS2 in the lactating mammary gland under the control of the whey acidic protein (WAP) promoter. Mouse lines bearing the genomic PS2 gene under the control of the WAP promoter region (WAP-PS2-2) failed to express the transgene. However, mice harboring the fusion construct WAP-PS2-1, in which the PS2 coding sequence is inserted into the 5' untranslated region of the complete WAP gene, were observed to express the transgene. Expression was restricted to the secretory epithelium of the mammary gland during lactation, and PS2 protein was secreted into the milk. Nevertheless, no mammary gland dysplasia was observed, and PS2 expression had no discernable effect upon the physiology and/or development of the suckling young or the transgenic mother.