Targeting expression to the mammary gland: intronic sequences can enhance the efficiency of gene expression in transgenic mice

We are studying the tissue-specific expression of the sheep milk-whey protein gene, β-lactoglobulin. We have used sequences derived from this gene to target the expression of biomedical proteins into milk with the intention to exploit this technology in transgenic sheep as a means of protein production. In the present study, a series of β-lactoglobulin hybrid genes and β-lactoglobulin minigenes were evaluated for expression in the mammary gland of transgenic mice. In particular, we have assessed whether there is a requirement for introns for efficient transgene expression in the mammary gland, since the coding sequences of many candidate proteins are available only as cDNAs. The results suggest that the inclusion of natural introns in constructs can enhance the efficiency of transgene expression. Thus, a hybrid construct comprising 4.3 kb of the immediate 5′ flanking sequences of β-lactoglobulin fused to a genomic minigene encoding human α-antitrypsin (α₁AT) was expressed much more efficiently than an α₁AT-cDNA construct containing the same β-lactoglobulin segment. Similarly, the intact β-lactoglobulin gene was expressed more efficiently than the corresponding intronless β-lactoglobulin minigene. This effect was not seen in transient expression expriments in baby hamster kidney cells when β-lactoglobulin-α₁AT constructs were driven by SV40 enhancer sequences. The effect cannot be explained by a simple requirement for splicing, since the inclusion of the first β-lactoglobulin intron into cDNA constructs encoding human α₁AT or β-lactoglobulin itself failed to enhance the efficiency of transgene expression. It is concluded that sequence elements within introns may interact with the upstream 5′ flanking sequences of β-lactoglobulin and enable the latter to function efficiently in the mammary gland of transgenic mice.     

The SV40 T-antigen induces premature apoptotic mammary gland involution during late pregnancy in transgenic mice

Transgenic animals of the line 8 contain the WAP-SV-T transgene. Females of this line synthesise the SV40 T-antigen in mammary gland epithelial cells during pregnancy and the lactation period. All females are ‘milk-less’ and the offspring have to be nursed by foster mothers. The reason for this phenomenon is a premature apoptosis during late pregnancy. Nonetheless a significant number of mammary epithelial cells escape apoptosis and all transgenic females develop breast cancer after the first lactation period.     

The effects of aromatase overexpression on mammary growth and gene expression in the aromatase x transforming growth factor alpha double transgenic mice

The transforming growth factor alpha (TGF) and its receptor (EGFR) are expressed in many breast cancers. Typically, the progression of estrogen dependent primary breast cancers into a hormone-independent state, due to the loss of the estrogen receptor, is associated with increased levels of TGF and EGFR, leading to aggressive breast carcinomas. The relationship between breast tumorigenesis and TGF is evident in the transgenic mice overexpressing TGF in the mammary glands. In the aromatase transgenic mice, the mammary glands exhibit preneoplastic developments but do not form frank tumors. To test the interactions between growth factor overexpression with tissue estrogen, we have crossed the aromatase transgenic mice with the TGF transgenic mice to produce a double transgenic strain. The histological data for the mammary glands of aromatase x TGF double transgenic mice show that these mice develop hyperplastic changes similar to the aromatase parental strain but no tumors are formed. Consistently, the expression of cyclin D1 and PCNA is diminished in the double transgenic strain as compared to the parental strains. In addition, the expression of TGF, EGF and EGFR are also decreased in the double transgenic strain, suggesting that continuous estrogen presence in the tissue due to aromatase overexpression downregulates the expression of EGFR and its ligands.     

Aromatase overexpression transgenic mice model: cell type specific expression and use of letrozole to abrogate mammary hyperplasia without affecting normal physiology

Our recent studies have shown that overexpression of aromatase results in increased tissue estrogenic activity and induction of hyperplastic and dysplastic lesions in female mammary glands and gynecomastia and testicular cancer in male aromatase transgenic mice. Both aromatase mRNA and protein are overexpressed in transgenic mammary glands and its expression is not limited to epithelial cells. However, it is more in epithelial than in stromal cells. Our results also indicate aromatase overexpression-induced changes in mammary glands can be abrogated with very low concentrations of the aromatase inhibitor, letrozole. Low concentration of letrozole had no effect on normal physiology as indicated by no significant change in the circulating levels of estradiol and follicle stimulating hormone as well as no change in estrogen responsive genes such as the progesterone receptor and lactoferrin in the uterine tissue. These observations indicate that the expression of aromatase in both epithelial and stromal cells can influence the complex interactions of biochemical pathways leading to mammary carcinogenesis and that the aromatase inhibitor, letrozole can be used as chemopreventive agents without affecting normal physiology.     

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.     

Estrogen receptor alpha is required for mammary development and the induction of mammary hyperplasia and epigenetic alterations in the aromatase transgenic mice

Aromatase transgenic mice exhibit hyperplastic and dysplastic changes, attesting to the importance of local estrogen in breast carcinogenesis. These mice also show increased levels of the estrogen receptor and β (ER, ERβ) suggesting that this receptor may play an important role in the initiation of estrogen-mediated mammary hyperplasia observed in these mice. To address the specific role of ER in the mammary development and in the induction of estrogen-mediated hyperplasia in aromatase transgenic mice, we have generated MMTV-aromatase × ER knockout cross (referred as aromatase/ERKO). Even though ERβ is expressed in aromatase/ERKO mice, lack of ER leads to impaired mammary growth in these mice. The data suggest that ER plays an important role in the mammary gland development as well as in the induction of mammary hyperplasia in aromatase transgenic mice. Lack of ER expression in the aromatase/ERKO mice resulted in a decrease in the expression of Cyclin D1, PCNA and TGFβ relative to the aromatase parental strain. The studies involving aromatase/ERKO mice show that lack of ER results in impaired mammary development even in the presence of continuous tissue estrogen, suggesting estrogen/ER-mediated actions are critical for mammary development and carcinogenesis.     

Impaired mammary gland and lymphoid development caused by inducible expression of Axin in transgenic mice.

Axin is a component of the canonical Wnt pathway that negatively regulates signal transduction by promoting degradation of beta-catenin. To study the role of Axin in development, we developed strains of transgenic mice in which its expression can be manipulated by the administration of doxycycline (Dox). Animals carrying both mouse mammary tumor virus (MMTV)-reverse tetracycline transactivator and tetracycline response element (TRE)2-Axin-green fluorescent protein (GFP) transgenes exhibited Dox-dependent Axin expression and, when induced from birth, displayed abnormalities in the development of mammary glands and lymphoid tissues, both sites in which the MMTV promoter is active. The transgenic mammary glands underwent normal ductal elongation and side branching during sexual maturation and early pregnancy, but failed to develop lobulo-alveoli, resulting in a defect in lactation. Axin attenuated the expression of cyclin D1, a Wnt target that promotes the growth and differentiation of mammary lobulo-alveoli. Increased apoptosis occurred in the mammary epithelia, consistent with the inhibition of a Wnt/cyclin D1 survival signal by Axin. High levels of programmed cell death also occurred in the thymus and spleen. Immature thymocytes underwent massive apoptosis, indicating that the overexpression of Axin blocks the normal development of T lymphocytes. Our data imply that the Axin tumor suppressor controls cell survival, growth, and differentiation through the regulation of an apoptotic signaling pathway.     

Expression of human lysozyme mRNA in the mammary gland of transgenic mice

Owing to its inherent antimicrobial effect and positive charge, the expression of human lysozyme in bovine milk could be beneficial by altering the overal microbial level and the functional and physical properties of the milk. We have used transgenic mice as model systems to evaluate the expression of human lysozyme containing fusion gene constructs in the mammary gland. Expression of human lysozyme was targeted to the mammary gland by using the 5 promoter elements of either the bovine (line B mice) or _s1 (line H mice) casein genes coupled to the cDNA for human lysozyme. Expression of human lysozyme mRNA was not found in mammary tissue from any of line B mice. Tissues were analysed from six lines of H mice and two, H6 and H5, were found to express human lysozyme mRNA in the mammary gland at 42% and 116%, respectively, of the levels of the endogenous mouse whey acidic protein gene. At peak lactation, female mice homozygous for the H5 and H6 transgene have approximately twice the amount of mRNA encoding human lysozyme as hemizygous animals. Expression levels of human lysozyme mRNA in the mammary gland at time points representing late pregnancy, early, peak and late lactation corresponded to the profile of casein gene expression. Human lysozyme mRNA expression was not observed in transgenic males, virgin females or in the kidney, liver, spleen or brain of lactating females. A very low level of expression of human lysozyme mRNA was observed in the salivary gland of line H5.     

Impaired development of the Harderian gland in mutant protein phosphatase 2A transgenic mice

Although Harderian glands are especially large in rodents, many features of this retroocular gland, including its development and function, are not well established. Protein phosphatase 2A (PP2A) is a family of heterotrimeric enzymes expressed in this gland. PP2A substrate specificity is determined by regulatory subunits with leucine 309 of the catalytic subunit playing a crucial role in the recruitment of regulatory subunits into the complex in vitro. Here we expressed an L309A mutant catalytic subunit in Harderian gland of transgenic mice. We found a delayed postnatal development and hypoplasia of the gland, causing enophthalmos. To determine why expression of the L309A mutant caused this phenotype, we determined the PP2A subunit composition. We found an altered subunit composition in the transgenic gland that was accompanied by pronounced changes of proteins regulating cell adhesion. Specifically, cadherin and beta-catenin were dramatically reduced and shifted to the cytosol. Furthermore, we found an inactivating phosphorylation of the cadherin-directed glycogen synthase kinase-3beta. In conclusion, the carboxy-terminal leucine L309 of the PP2A catalytic subunit determines PP2A heterotrimer composition in vivo. Moreover, our data demonstrate that PP2A subunit composition plays a crucial role in regulating cell adhesion and as a consequence in the development of the Harderian gland.     

Consumption of milk from transgenic goats expressing human lysozyme in the mammary gland results in the modulation of intestinal microflora

Lysozyme is a key antimicrobial component of human milk that has several health-promoting functions including the development of a healthy intestinal tract. However, levels of lysozyme in the milk of dairy animals are negligible. We have generated transgenic dairy goats that express human lysozyme (HLZ) in their milk in an attempt to deliver the benefits of human milk in a continual fashion. To test the feasibility of this transgenic approach to achieve a biological impact at the level of the intestine, feeding trials were conducted in two animal models. Pasteurized milk from HLZ transgenic animals was fed to both kid goats (ruminant model) and young pigs (human model), and the numbers of total coliforms and Escherichia coli present in the small intestine were determined. Data from this proof-of-principle study demonstrate that milk from transgenic animals was capable of modulating the bacterial population of the gut in both animal models. Pigs that consumed pasteurized milk from HLZ transgenic goats had fewer numbers of coliforms and E. coli in their intestine than did those receiving milk from non-transgenic control animals. The opposite effect was seen in goats. Milk from these transgenic animals not only represent one of the first transgenic food products with the potential of benefiting human health, but are also a unique model to study the development and role of intestinal microflora on health, well-being and resistance to disease.     

Enteroendocrine cell expression of a cholecystokinin gene construct in transgenic mice and cultured cells

CCK is predominantly expressed in subsets of endocrine cells in the intestine and neurons in the brain. We evaluated the expression of a CCK gene construct in transgenic mice and cultured cells to identify a genomic region that directs correct tissue- and cell-specific expression in enteroendocrine cells. The CCKL1 transgene contained 6.4 kb of mouse Cck fused to lacZ. Expression was evaluated in three transgenic lines (J11, J12, J14) by measurement of beta-galactosidase in tissue homogenates and frozen sections. Correct tissue-specific expression was observed, with beta-galactosidase activity detected in intestine and brain. However, there were differences seen in cell-specific expression in the intestine. Line J14 exhibited expression in CCK-endocrine cells, with expressing cells arising at the normal time during fetal development. However, transgene expression in line J12 intestine was limited to neurons of the enteric nervous system, which reflect an early fetal expression pattern for CCK. Analysis of an additional 15 transgenic founder mice demonstrated intestinal expression in 40% of transgenics, with expressing mice following either an endocrine cell pattern or a neuronal pattern in approximately equal numbers. CCKL1 transfection analysis in cultured cells also demonstrated enteroendocrine cell expression, with 100-fold enhanced activity in the enteroendocrine cell line STC-1 compared with nonendocrine cell lines. The results suggest that the minimal cis-regulatory DNA elements necessary for appropriate CCK expression in enteroendocrine cells reside within the 6.4-kb mouse genomic fragment.     

Structure of the rabbit tc-casein encoding gene: expression of the cloned gene in the mammary gland of transgenic mice

The rabbit κ-casein (κ-Cas) encoding gene has been isolated as a series of overlapping DNA fragments cloned from a rabbit genomic library constructed in bacteriophage λEMBL3. The clones harboured the 7.5-kb gene flanked by about 2.1 kb upstream and 9 kb downstream sequences. The cloned gene is the most frequently occurring of two κ-Cas alleles identified in New Zealand rabbits. Comparison of the corresponding domains in rabbit and bovine κ-Cas shows that both genes comprise 5 exons and that the exon/intron boundary positions are conserved whereas the introns have diverged considerably. The first three introns are shorter in the rabbit, the second intron showing the greatest difference between the two species: 1.35 kb instead of 5.8 kb in the bovine gene. Repetitive sequence motives reminiscent of the rabbit C type repeat and the complementary inverted C type repeat were identified in the fourth and first introns, respectively. Transgenic mice were produced by microinjecting into mouse oocytes an isolated genomic DNA fragment which contained the entire κ-Cas coding region, together with 2.1-kb 5′ and 4.0-kb 3′ flanking region. Expression of transgene rabbit κ-Cas mRNA could be detected in the mammary gland of lactating transgenic mice and the production of rabbit κ-Cas was detected in milk using species-specific antibodies. The cloned gene is thus functional.