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

Characterization of Enlarged Tongues in Cloned Piglets

Although the efficiency of cloning remains very low, this technique has become the most reliable way to produce transgenic pigs. However, the high rate of abnormal offspring such as an enlarged tongue lowers the cloning efficiency by reducing the early survivability of piglets. Thus, the present study was conducted to identify the characteristics of the enlarged tongue from cloned piglets by histologic and transcriptomic analysis. As a result, it was observed that the tissues from enlarged tongues (n = 3) showed isolated and broken muscle bundles with wide spaces while the tissues from normal tongues (n = 3) showed the tight connection of muscle bundles without space by histological analysis. Additionally, transmission electron microscopy results also showed the formation of isolated and broken muscle bundles in enlarged tongues. The transcriptome analysis showed a total of 197 upregulated and 139 downregulated genes with more than 2-fold changes in enlarged tongues. Moreover, there was clear evidence for the difference between groups in the muscle system process with high relation in the biological process by gene ontology analysis. The analysis of the Kyoto Encyclopedia of Gene and Genomes pathway of differentially expressed genes indicated that the pentose phosphate pathway, glycolysis/gluconeogenesis, and glucagon signaling pathway were also involved. Conclusively, our results could suggest that the abnormal glycolytic regulation may result in the formation of an enlarged tongue. These findings might have the potential to understand the underlying mechanisms, abnormal development, and disease diagnosis in cloned pigs.

Effect of Delta-9-tetrahydrocannabinol and cannabidiol on milk proteins and lipid levels in HC11 cells

Pregnant and lactating women have been discouraged from using cannabis by Health Canada. However, the increasing rate of cannabis use among pregnant women has presented an urgent need to investigate its physiological effects during the perinatal period. During pregnancy, the mammary gland (MG) undergoes remodeling, which involves alveolar differentiation of mammary epithelial cells (MECs), which is essential for breast milk production and secretion. Limited evidence has been reported on the impact of cannabis or its components, delta-9-tetrahydrocannabinol (THC) and cannabidiol (CBD), on MG development or MEC differentiation. In this study, we investigated the effects of THC and CBD on the differentiation of MECs by assessing changes in cellular viability, lipid accumulation, and gene and protein expression of major milk protein and lipid synthesizing markers. using the HC11 cells as a model. We hypothesized that THC and CBD will negatively impact the synthesis of milk proteins and lipids, as well as lipid markers in HC11 cells. Our results demonstrated that THC and CBD reduced cellular viability at concentrations above 30μM and 20μM, respectively. Relative to control, 10μM THC and 10μM CBD reduced mRNA levels of milk proteins (CSN2 and WAP), lipid synthesizing and glucose transport markers (GLUT 1, HK2, FASN, FABP4, PLIN2 and LPL), as well as whey acidic protein and lipid levels. In addition, co-treatment of a CB2 antagonist with THC, and a CB2 agonist with CBD, reversed the impact of THC and CBD on the mRNA levels of key markers, respectively. In conclusion, 10μM THC and CBD altered the differentiation of HC11 cells, in part via the CB2 receptor.

Upregulation of estrogen receptor alpha (ERα) expression in transgenic mice expressing human CYP4Z1

PURPOSE

CYP4Z1 is a human cytochrome P450 enzyme involved in breast cancer progression and prognosis, but its functional role in these processes is not understood. In order to gain more insight into CYP4Z1's properties it was recombinantly expressed in a host animal that does not have an endogenous homologue.

METHODS

We generated a transgenic mouse model that specifically expresses human CYP4Z1 in breast tissue under the control of the whey acidic protein promoter. Complementary experiments were done using cell lines derived from human breast cell.

RESULTS

Induction of CYP4Z1 expression led to reduction of body weight, activity, and birth rates. Histological analysis revealed no evidence for tumor formation. However, a strong increase in estrogen receptor alpha was observed by immunohistochemistry; weaker but significantly increased immunoreactivity was also detected for collagen I and fibronectin. Overexpression of CYP4Z1 in the human breast cancer cell line MCF7 also led to increased ERα expression. Moreover, increased expression of both CYP4Z1 and ERα was observed in MCF-10A normal breast cells upon cocultivation with MCF-7 cells (with or without overexpression of CYP4Z1).

CONCLUSION

These data suggest that CYP4Z1 facilitates breast cancer development by induction of ERα expression via an as yet undefined mechanism.

First identification and characterization of a triple WAP domain containing protein in Procambarus clarkii provides new insights into the classification and evolution of WAP proteins in crustacean

Whey acidic protein domain (WAPD) is a usual motif in crustaceans, and is found mainly in the immune-related proteins. In the present study, a protein containing three tandem WAPDs was identified in red swamp crayfish Procambarus clarkii and designated as PcTWD. This is the first report of a protein of such domain architecture in crustaceans. Introducing the WAPDs of PcTWD into phylogenetic analysis led to the classification of crustacean WAP proteins into classical crustins and proteins containing solely WAPDs. PcTWD was widely expressed in multiple tissues, including hemocytes, gills, hepatopancreas, heart, stomach and intestine. Its expression could be significantly induced by Staphylococcus aureus or Aeromonas hydrophila challenge. Knockdown PcTWD expression by RNAi suppressed host resistance against A. hydrophila, while exogenous recombinant PcTWD could enhance the host immunity. The three WAPDs showed a labor division. The first two domains were responsible for the protease inhibitory activity, and the third domain contributed to the antimicrobial activity. Thus PcTWD was found as an important protein in crayfish antibacterial immunity.

Hormonal regulation of platypus Beta-lactoglobulin and monotreme lactation protein genes

Endocrine regulation of milk protein gene expression in marsupials and eutherians is well studied. However, the evolution of this complex regulation that began with monotremes is unknown. Monotremes represent the oldest lineage of extant mammals and the endocrine regulation of lactation in these mammals has not been investigated. Here we characterised the proximal promoter and hormonal regulation of two platypus milk protein genes, Beta-lactoglobulin (BLG), a whey protein and monotreme lactation protein (MLP), a monotreme specific milk protein, using in vitro reporter assays and a bovine mammary epithelial cell line (BME-UV1). Insulin and dexamethasone alone provided partial induction of MLP, while the combination of insulin, dexamethasone and prolactin was required for maximal induction. Partial induction of BLG was achieved by insulin, dexamethasone and prolactin alone, with maximal induction using all three hormones. Platypus MLP and BLG core promoter regions comprised transcription factor binding sites (e.g. STAT5, NF-1 and C/EBPα) that were conserved in marsupial and eutherian lineages that regulate caseins and whey protein gene expression. Our analysis suggests that insulin, dexamethasone and/or prolactin alone can regulate the platypus MLP and BLG gene expression, unlike those of therian lineage. The induction of platypus milk protein genes by lactogenic hormones suggests they originated before the divergence of marsupial and eutherians.

STAT5 plays a critical role in regulating the 5'-flanking region of the porcine whey acidic protein gene in transgenic mice

The mammary gland serves as a valuable bioreactor system for the production of recombinant proteins in lactating animals. Pharmaceutical-grade recombinant protein can be harvested from the milk of transgenic animals that carry a protein of interest under the control of promoter regions genes encoding milk proteins. Whey acidic protein (WAP), for example, is predominantly expressed in the mammary gland and is regulated by lactating hormones during pregnancy. We cloned the 5'-flanking region of the porcine WAP gene (pWAP) to confirm the sequence elements in its promoter that are required for gene-expression activity. In the present study, we investigated how lactogenic hormones--including prolactin, hydrocortisone, and insulin--contribute to the transcriptional activation of the pWAP promoter region in mammalian cells, finding that these hormones activate STAT5 signaling, which in turn induce gene expression via STAT5 binding sites in its 5'-flanking region. To confirm the expression and hormonal regulation of the 5'-flanking region of pWAP in vivo, we generated transgenic mice expressing human recombinant granulocyte colony stimulating factor (hCSF2) in the mammary gland under the control of the pWAP promoter. These mice secreted hCSF2 protein in their milk at levels ranging from 242 to 1,274.8 ng/ml. Collectively, our findings show that the pWAP promoter may be useful for confining the expression of foreign proteins to the mammary gland, where they can be secreted along with milk.

Identification of whey acidic protein (WAP) in dog milk

Whey acidic protein (WAP) has been identified as a major whey protein in milk of a wide range of species and reportedly plays important roles in regulating the proliferation of mammary epithelial cells. However, in some species including humans, WAP is not synthesized in the mammary gland. The presence of WAP in carnivore species has not been reported. We searched the National Center for Biotechnology Information (NCBI) database for the dog WAP gene and tried biochemically to identify WAP in dog milk. The nucleotide sequence of the examined dog genomic DNA was completely identical to that in the NCBI database and showed that the dog WAP gene, like other known functional WAP genes, has four exons. Biochemical analysis of milk protein by reverse-phase HPLC and Western blotting demonstrated the presence of WAP in dog milk.

Gene expression profile of terminal end buds in rat mammary glands exposed to diethylstilbestrol in neonatal period

Diethlstilbestrol (DES) is a synthetic estrogen prescribed to several millions of pregnant women worldwide. The risk for breast cancer after age 40 in women prenatally exposed to DES has been reported; however, the precise mechanism of susceptibility to breast cancer remains to be resolved. We investigated the global gene expression profile of terminal end buds (TEBs), the target of carcinogen, in rat mammary glands neonatally exposed to a low- or high-dose DES at postnatal days (PND) 35 and 45, equivalent to the peripubertal stage in humans. In all groups, the number of TEBs gradually increased, peaked at PND35 and decreased at PND49. At PND35 and 49, the low-dose DES-treated group (low-DES group) showed the highest number of TEBs. In the low-DES group at PND35, β-casein, γ-casein and whey acidic protein (WAP) mRNA expression increased 8.2-fold, 26.1-fold and 13.3-fold, respectively, whereas γ-casein and WAP mRNA decreased 17.6-fold and 27.7-fold, respectively, at PND49. The most significant network revealed by Ingenuity Pathway Analysis (IPA) software showed the relevance of NF-κB in low-DES group. The present findings suggest that the deregulation of mammary gland differentiation and development-related genes could be induced and cause the increased number of terminal duct lobular units (TDLUs) in human mammary glands of DES daughters in a critical period of mammary gland development.

Bacteriostatic activity of Whey Acidic Protein (WAP)

We have previously reported the action of whey acidic protein (WAP) inhibiting the proliferation of mouse mammary epithelial cells in the experiments utilizing in vivo and in vitro systems. We report herein the bacteriostatic activity of WAP. Western blot analysis demonstrated successful isolation of WAP from whey fractions of rat milk by column chromatography. The WAP fraction inhibited the growth of Staphylococcus aureus JCM2413 in a dose-dependent manner, but did not inhibit the growth of Escherichia coli. The bacteriostatic activity of WAP was highest at pH 6.6 and was not affected by the presence of 150 mM NaCl. A scanning electron micrograph of bacteria treated with WAP exhibited the disruption of the bacterial cell walls.

Characterization of the tammar wallaby (Macropus eugenii) whey acidic protein gene: new insights into the function of the protein

Whey acidic protein (WAP) belongs to a family of four disulfide core (4-DSC) proteins rich in cysteine residues and is the principal whey protein found in milk of a number of mammalian species. Eutherian WAPs have two 4-DSC domains, whereas marsupial WAPs are characterized by the presence of an additional domain at the amino terminus. Structural and expression differences between marsupial and eutherian WAPs have presented challenges to identifying physiological functions of the WAP protein. We have characterized the genomic structure of tammar WAP (tWAP) gene, identified its chromosomal localization and investigated the potential function of tWAP. We have demonstrated that tWAP and domain III (DIII) of the protein alone stimulate proliferation of a mouse mammary epithelial cell line (HC11) and primary cultures of tammar mammary epithelial cells (Wall-MEC), whereas deletion of DIII from tWAP abolishes this proliferative effect. However, tWAP does not induce proliferation of human embryonic kidney (HEK293) cells. DNA synthesis and expression of cyclin D1 and cyclin-dependent kinase-4 genes were significantly up-regulated when Wall-MEC and HC11 cells were grown in the presence of either tWAP or DIII. These data suggest that DIII is the functional domain of the tWAP protein and that evolutionary pressure has led to the loss of this domain in eutherians, most likely as a consequence of adopting a reproductive strategy that relies on greater investment in development of the newborn during pregnancy.

Expression of the whey acidic protein (Wap) is necessary for adequate nourishment of the offspring but not functional differentiation of mammary epithelial cells

Whey acidic protein (WAP) is the principal whey protein found in rodent milk, which contains a cysteine-rich motif identified in some protease inhibitors and proteins involved in tissue modeling. The expression of the Wap gene, which is principally restricted to the mammary gland, increases more than 1,000-fold around mid-pregnancy. To determine whether the expression of this major milk protein gene is a prerequisite for functional differentiation of mammary epithelial cells, we generated conventional knockout mice lacking two alleles of the Wap gene. Wap-deficient females gave birth to normal litter sizes and, initially, produced enough milk to sustain the offspring. The histological analysis of postpartum mammary glands from knockout dams does not reveal striking phenotypic abnormalities. This suggests that the expression of the Wap gene is not required for alveolar specification and functional differentiation. In addition, we found that Wap is dispensable as a protease inhibitor to maintain the stability of secretory proteins in the milk. Nevertheless, a significant number of litters thrived poorly on Wap-deficient dams, in particular during the second half of lactation. This observation suggests that Wap may be essential for the adequate nourishment of the growing young, which triple in size within the first 10 days of lactation. Important implications of these findings for the use of Wap as a marker for advanced differentiation of mammary epithelial cells and the biology of pluripotent progenitors are discussed in the final section.

Whey acidic protein (WAP) regulates the proliferation of mammary epithelial cells by preventing serine protease from degrading laminin

Whey acidic protein (WAP) is a major whey protein in milk that has structural similarity to the family of serine protease inhibitors with WAP motif domains characterized by a four-disulfide core. We previously reported that enforced expression of the mouse WAP transgene in mammary epithelial cells inhibits their proliferation in vitro and in vivo by means of suppressing cyclin D1 expression (Nukumi et al., 2004, Dev Biol 274: 31-44). This study was conducted in order to clarify the molecular mechanism of the inhibitory function of WAP in HC11 cells, a mammary epithelial cell line. The assembly of laminin, a component in the extracellular matrix, was much more prominent around WAP-clonal HC11 cells that stably expressed the WAP transgene than around mock-clonal HC11 cells, and the proliferation of WAP-clonal HC11 cells was particularly inhibited in the presence of laminin. A laminin degradation assay demonstrated that WAP inhibited the activity of the pancreatic elastase-mediated cleavage of laminin B1 and the phosphorylation of ERK1/2. ERK1/2 phosphorylation was blocked by an inhibitor of the epidermal growth factor (EGF) receptor AG1478. Treatment with pancreatic elastase was found to enhance the proliferation of mock-clonal HC11 cells, but had no effect on that of WAP-clonal HC11 cells. The proliferation of WAP-clonal HC11 cells was recovered by the addition of exogenous EGF. We concluded that WAP plays some role in regulating the proliferation of mammary epithelial cells by preventing elastase-type serine protease from carrying out laminin degradation and thereby suppressing the MAP kinase signal pathway.

Molecular evolution of monotreme and marsupial whey acidic protein genes

Whey acidic protein (WAP), a major whey protein present in milk of a number of mammalian species has characteristic cysteine-rich domains known as four-disulfide cores (4-DSC). Eutherian WAP, expressed in the mammary gland throughout lactation, has two 4-DSC domains, (DI-DII) whereas marsupial WAP, expressed only during mid-late lactation, contains an additional 4-DSC (DIII), and has a DIII-D1-DII configuration. We report the expression and evolution of echidna (Tachyglossus aculeatus) and platypus (Onithorhynchus anatinus) WAP cDNAs. Predicted translation of monotreme cDNAs showed echidna WAP contains two 4-DSC domains corresponding to DIII-DII, whereas platypus WAP contains an additional domain at the C-terminus with homology to DII and has the configuration DIII-DII-DII. Both monotreme WAPs represent new WAP protein configurations. We propose models for evolution of the WAP gene in the mammalian lineage either through exon loss from an ancient ancestor or by rapid evolution via the process of exon shuffling. This evolutionary outcome may reflect differences in lactation strategy between marsupials, monotremes, and eutherians, and give insight to biological function of the gene products. WAP four-disulfide core domain 2 (WFDC2) proteins were also identified in echidna, platypus and tammar wallaby (Macropus eugenii) lactating mammary cells. WFDC2 proteins are secreted proteins not previously associated with lactation. Mammary gland expression of tammar WFDC2 during the course of lactation showed WFDC2 was elevated during pregnancy, reduced in early lactation and absent in mid-late lactation.

Reduction of tumorigenesis and invasion of human breast cancer cells by whey acidic protein (WAP)

Whey acidic protein (WAP) is a major component of whey, which has two or three WAP motif domains characterized by a four-disulfide core (4-DSC) structure similar to the serine protease inhibitor. We have previously found that WAP inhibits the proliferation of mammary epithelial cells in vitro and in vivo [N. Nukumi, K. Ikeda, M. Osawa, T. Iwamori, K. Naito, H. Tojo, Regulatory function of whey acidic protein in the proliferation of mouse mammary epithelial cells in vivo and in vitro, Dev. Biol. 274 (2004) 31-44]. We report herein that WAP also reduces the progression of human breast cancer cells (MCF-7 and MDA-MB-453 cells). We have demonstrated that the forced expression of WAP in MCF-7 cells reduces the proliferation in either the presence or absence of estrogen. The tumor progression of WAP-expressing MCF-7 cells in nude mice is significantly suppressed more than that of mock-MCF-7 cells following the reduced expression of angiopoietin-2 gene. We have confirmed that the invasive activity of breast cancer cells is reduced to approximately 30% of that of mock cells by the forced expression of exogenous WAP through its inhibition of degradation of laminin. These data suggest that WAP has a protease-inhibitory function on the progression of breast cancer cells. It is therefore possible to utilize WAP as therapeutic protein against tumorigenesis of breast cancer.

The Tammar Wallaby and Fur Seal: Models to Examine Local Control of Lactation

Mammary development and function are regulated by systemic endocrine factors and by autocrine mechanisms intrinsic to the mammary gland, both of which act concurrently. The composition of milk includes nutritional and developmental factors that are crucial to the development of the suckled young, but it is becoming increasingly apparent that milk also has a role in regulating mammary function. This review examines the option of exploiting the comparative biology of species with extreme adaptation to lactation to examine regulatory mechanisms that are present but not readily apparent in other laboratory and livestock species. The tammar wallaby has adopted a reproductive strategy that includes a short gestation (26 d), birth of an immature young, and a relatively long lactation (300 d). The composition of milk changes progressively during the lactation cycle, and this is controlled by the mother and not the sucking pattern of the young. Furthermore, the tammar can practice concurrent asynchronous lactation; the mother provides a concentrated milk high in protein and fat for an older animal that is out of the pouch and a dilute milk low in fat and protein but high in carbohydrates from an adjacent mammary gland for a newborn pouch young. This phenomenon suggests that the mammary gland is controlled locally. The second study species, the Cape fur seal, has a lactation characterized by a repeated cycle of long at-sea foraging trips (up to 28 d) alternating with short suckling periods of 2 to 3 d ashore. Lactation almost ceases while the seal is off shore, but the mammary gland does not progress to apoptosis and involution, most likely because of local control of the mammary gland. Our studies have exploited the comparative biology of these models to investigate how mammary function is regulated by endocrine factors, and particularly by milk. This review reports 3 major findings using these model animals. First, the mammary epithelial cell has an extraordinary intrinsic capacity for survival in our culture model, and the path to either function or death by apoptosis is actively driven. The second outcome is that the route to apoptosis is most likely regulated by specific milk factors. Finally, whey acidic protein, a major milk protein in some species, may play a role in normal mammary development, but that role in vivo may be limited to marsupials. Evolutionary pressure has led to changes in the structure of the protein with an accompanying change in function. Therefore, we propose that a loss of function of this protein in eutherians may relate to a reproductive strategy that is less dependent on lactation.

Ultrastructural Morphometry of Mammary Gland in Transgenic and Non-transgenic Rabbits

The mammary gland of transgenic animals has been used for the production of recombinant proteins of therapeutic and nutraceutical use. The objective of this study was to compare the ultrastructure of transgenic and non-transgenic rabbit mammary gland tissue. New Zealand White transgenic rabbits were obtained by breeding non-transgenic rabbits with transgenic founder rabbits containing a whey acidic protein-human factor VIII (WAP-hFVIII) transgene integrated into their genome. Samples of mammary gland tissue from lactating rabbit females were isolated by surgical procedures. These samples were examined by optical and electron microscopy and photographs were taken. Measurements of ultrastructural organelles were made from digital images of the mammary cells. No differences were found in the cellular structure of mammary tissue, but significant differences t((0.001)) in the relative volume of mitochondria and vacuoles between transgenic and non-transgenic mammary gland epithelium were observed.

Ruminants genome no longer contains Whey Acidic Protein gene but only a pseudogene

Whey Acidic Protein (WAP) has been identified in the milk of only a few species, including mouse, rat, rabbit, camel, pig, tammar wallaby, brushtail possum, echidna and platypus. Despite intensive studies, it has not yet been found in the milk of Ruminants. We have isolated and characterized genomic WAP clones from ewe, goat and cow, identified their chromosomal localization and examined the expression of the endogenous WAP sequence in the mammary glands of all three species. The WAP sequences were localized on chromosome 4 (4q26) as expected from comparative mapping data. The three ruminant WAP sequences reveal the same deletion of a nucleotide at the end of the first exon when compared with the pig sequence. Due to this frameshift mutation, the putative proteins encoded by these sequences do not harbor the features of a usual WAP protein with two four-disulfide core domains. Moreover, RT-PCR experiments have shown that these sequences are not transcribed and are, thus, pseudogenes. This loss of functionality of the gene in Ruminants raises the question of the biological role of the WAP. Some putative roles previously suggested for WAP are discussed.

Analysis of the Promoter of Mutated Human Whey Acidic Protein (WAP) Gene

Although whey acidic protein (WAP) has been identified in the milk of a range of species, it has been predicted that WAP is not secreted into human milk as a result of critical point mutations within the coding region. In the present study, we first investigated computationally the promoter region of mutated human WAP genes by comparing with those of other known WAP genes. Computational database analyses showed that the human WAP promoter region was highly conserved, as in other species with milk WAP. Next, we evaluated the activity of the human WAP promoter (2.6 kb) using a reporter gene assay. MCF-7 cells were stably transfected with the hWAP/hGH (human growth hormone) fusion gene, cultured on Matrigel, and treated with lactogenic hormones. Radioimmunoassay detected hGH in the culture medium, indicating that the human WAP promoter was responsible for the lactogenic hormones. The human WAP promoter was significantly more active in MCF-7 cells than the mouse WAP promoter (2.4 kb). The present results provide us with important information on the molecular evolution of milk protein genes.

Whey acidic protein (WAP) depresses the proliferation of mouse (MMT) and human (MCF-7) mammary tumor cells

We previously reported that the enforced expression of exogenous whey acidic protein (WAP) significantly inhibited the proliferation of mouse mammary epithelial cells (HC11 and EpH4/H6 cells). This paper presents the first evidence that WAP also depresses the proliferation of mammary tumor cells from mouse (MMT cells) and human (MCF-7 cells). We established WAP-clonal MMT and MCF-7 cell lines, and confirmed the secretion of WAP from the WAP-clonal cells into culture medium. The enforced expression of WAP significantly inhibited the proliferation of MMT and MCF-7 cells in in vitro culture. FACScan analyses revealed that G0/G1 phase cell-cycle progression was disordered and elongated in the WAP-clonal MMT and MCF-7 cells compared to that of the control cells. The expression of cyclin D1 was significantly decreased in the WAP-clonal MMT and MCF-7 cells, suggesting that progression from the G1 to the S phase was delayed in the WAP-clonal cells. The present results indicate that WAP plays a negative regulatory role in the cell-cycle progression of mammary tumor cells via a paracrine mechanism.