DEAD-box helicase 6 (DDX6) is a new negative regulator for milk synthesis and proliferation of bovine mammary epithelial cells

Milk synthesis of bovine mammary gland is a complex biological process that is regulated by hormones and nutrients, but the mechanism of these regulations still needs further research. DEAD-box helicase 6 (DDX6) is an important member of the RNA helicase family, involved in the regulation of mRNA storage and translation in different systems, but its physiological role and mechanism are largely unclear. In this study, we describe DDX6 as a potentially novel negative regulator for milk synthesis and proliferation of bovine mammary epithelial cells (BMECs). Treatment of BMECs with amino acids (methionine or leucine) or hormones (estrogen or prolactin) decreased the expression of DDX6. DDX6 expression was lower in mammary tissues of lactation period than in mammary tissues of puberty and dry period. Notably, overexpressing DDX6 in BMECs significantly decreased milk synthesis, cell proliferation, and protein levels of p-mTOR, SREBP-1c, and cyclin D1, while inhibiting DDX6 had the opposite effect. Taken together, these results reveal that DDX6 is a new negative regulator to control milk synthesis and proliferation of BMECs.     

Cellular prion protein in mammary gland and milk fractions of domestic ruminants

The present study shows that PrP^c is expressed in the mammary gland and milk fractions of domestic ruminants in a species-specific manner. By applying immunohistochemistry, Western blot and ELISA, clear expression differences between bovine, ovine and caprine mammary gland, skimmed milk, acid whey and cream could be demonstrated, the highest relative PrP^c levels being associated with the cream fraction. In the bovine gland PrP^c was preferentially detectable at the basolateral surface of mammary gland epithelial cells, whereas in ovine and caprine samples the prion protein was more homogeneously distributed. Moreover, in ovine and caprine bovine mammary gland epithelial cells, apocrine secretory vesicles were strongly stained. Ovine and caprine milk proved to contain PrP^c in all fractions with an additional truncated form at 12 kDa in Western blot. This truncated isoform is the predominate one in caprine acid whey. These results support the hypothesis that the apocrine secretion mode of milk fat globules is a major way of PrP^c transport into the milk.     

Expression and localisation of GLUT1 and GLUT12 glucose transporters in the pregnant and lactating rat mammary gland

Glucose plays a major role in mammary gland function during lactation as it is used both as a fuel and as a precursor of milk components. In rats, previous studies have shown that the facilitative glucose transporter GLUT1 is expressed in mammary epithelial cells. We have used confocal immunofluorescence to localise GLUT1 and GLUT12, a recently identified member of the sugar transporter family, in pregnant and lactating rat mammary gland. GLUT12 staining was observed in the cytoplasm of mammary epithelial cells at day 20 of pregnancy, and at 1 and 6 days postpartum. Furthermore, GLUT12 staining was present at the apical plasma membrane of epithelial cells during lactation. In contrast, GLUT1 protein localised to the cytoplasm and basolateral surface of mammary epithelial cells. Forced weaning resulted in decreased cytoplasmic GLUT1 staining intensity, but no change in GLUT12 staining. The results suggest a possible role for GLUT12 in the metabolism of mammary epithelial cells during pregnancy and lactation.     

Accurate spatial and temporal transgene expression driven by a 3.8-kilobase promoter of the bovine β-casein gene in the lactating mouse mammary gland

The spatial, temporal, and hormonal pattern of expression of the β-casein gene is highly regulated and confined to the epithelial cells of the lactating mammary gland. Previous studies have shown that 1.7 kb of the bovine β-casein promoter were able to drive cell-specific and hormone-dependent expression to a mouse mammary cell line but failed to induce accurate expression to the mammary gland of transgenic mice. We investigated here the ability of 3.8 kb of the bovine β-casein gene promoter to drive the expression of the human growth hormone (hGH) gene in transgenic mice. A Northern blot analysis using total RNA obtained from different tissues of lactating and nonlactating females revealed the presence of hGH mRNA only in the mammary gland of lactating females. hGH mRNA was not detectable in the mammary gland of virgin females or males. A developmental analysis showed that hGH mRNA only peaked on parturition, resembling more closely the bovine β-casein temporal expression pattern rather than the murine. In situ hibridization studies performed on mammary gland sections showed that the cellular pattern of hGH expression was homogeneous in all lobules from heterozygous and homozygous transgenic mice. Silver grain counts on the tissue sections highly correlated with the hGH contents in the milk determined by radioimmunoassay (r = 0.996). Thus 3.8 kb of the bovine β-casein promoter direct a high-level expression of a reporter gene to the lactating mammary gland of transgenic mice in a tissue-specific and developmentally regulated manner. Mol. Reprod. Dev. 49:236–245, 1998. © 1998 Wiley-Liss, Inc.     

Cloning and expression of bovine imc-415 cDNA from mammary gland

Bovine imc-415 cDNA was cloned from mammary gland using RACE PCR; it coded for 245 amino acids. The deduced amino acid sequence of mouse and human showed about 94% identity. Expression of bovine imc-415 increased about 40% in involuted mammary tissues compared with lactating tissues.     

Cloning and Expression of Bovine imc-415 cDNA from Mammary Gland

Bovine imc-415 cDNA was cloned from mammary gland using RACE PCR; it coded for 245 amino acids. The deduced amino acid sequence of mouse and human showed about 94% identity. Expression of bovine imc-415 increased about 40% in involuted mammary tissues compared with lactating tissues.     

Characterization and expression of L-amino acid oxidase of mouse milk

l-Amino acid oxidase (LAO) was purified from mouse milk. LAO reacted with l-amino acids in an apparent order of Phe > Met, Tyr > Cys, Leu > His other 11 amino acids tested and produced H(2)O(2) in a dose- and time-dependent manner. LAO in milk had a molecular mass of about 113 kDa and was converted to a 60-kDa protein by SDS-PAGE. LAO consisted of two subunits. The N- and C-terminal amino acid sequence determination followed by cDNA cloning showed that the 60-kDa protein consisted of 497 amino acids. LAO mRNA spanned about 2.0 kb, and its expression was found only in the mammary epithelial cells. Glucocorticoid was essential for LAO gene expression. Thus, the LAO gene is expressed acutely upon the onset of milk synthesis. LAO mRNA increased 1 day before parturition, peaked during early to mid-lactation, and decreased at the end of lactation. This is the first demonstration showing that LAO is present in milk. Mastitis is caused by an intramammary bacterial infection. As mouse milk produced H(2)O(2) using endogenous free amino acids, we suggest that LAO, together with free amino acids, is responsible for killing bacteria in the mammary gland.     

Secretion of unprocessed human surfactant protein B in milk of transgenic mice

Because of the apparent clinical importance of human pulmonary surfactant B (SP-B), the expression of SP-B was directed to the mammary gland of transgenic mice using previously characterized rat whey acidic protein (WAP) regulatory sequences. rWAP/SP-B mRNA was expressed specifically in the mammary gland, and ranged from 1 to 5% of the endogenous WAP mRNA levels. SP-B was detected immunologically in both tissue and milk. The transgene product had an apparent molecular weight of 40--45 kDa, corresponding to the predicted size of the SP-B proprotein. Incubation of an SP-B-enriched fraction of milk with cathepsin D in vitro produced 20--25 kDa species, consistent with cleavage of the amino terminal domain by cathepsin D. This was confirmed using antibodies specific to the carboxy-terminal domain of SP-B. However, the appearance of only the SP-B proprotein in milk suggests that cathepsin D is not involved in the in vivo processing of SP-B. The SP-B proprotein can be expressed in milk of transgenic mice without any observed effects on mammary gland morphology or lactation     

Peptide transport in the mammary gland: expression and distribution of PEPT2 mRNA and protein

The lactating mammary gland utilizes free plasma amino acids as well as those derived by hydrolysis from circulating short-chain peptides for protein synthesis. Apart from the major route of amino acid nitrogen delivery to the gland by the various transporters for free amino acids, it has been suggested that dipeptides may also be taken up in intact form to serve as a source of amino acids. The identification of peptide transporters in the mammary gland may therefore provide new insights into protein metabolism and secretion by the gland. The expression and distribution of the high-affinity type proton-coupled peptide transporter PEPT2 were investigated in rat lactating mammary gland as well as in human epithelial cells derived from breast milk. By use of RT-PCR, PEPT2 mRNA was detected in rat mammary gland extracts and human milk epithelial cells. The expression pattern of PEPT2 mRNA revealed a localization in epithelial cells of ducts and glands by nonisotopic high resolution in situ hybridization. In addition, immunohistochemistry was carried out and showed transporter immunoreactivity in the same epithelial cells of the glands and ducts. In addition, two-electrode voltage clamp recordings using PEPT2-expressing Xenopus laevis oocytes demonstrated positive inward currents induced by selected dipeptides that may play a role in aminonitrogen handling in mammalian mammary gland. Taken together, these data suggest that PEPT2 is expressed in mammary gland epithelia, in which it may contribute to the reuptake of short-chain peptides derived from hydrolysis of milk proteins secreted into the lumen. Whereas PEPT2 also transports a variety of drugs, such as selected beta-lactams, angiotensin-converting enzyme inhibitors, and antiviral and anticancer metabolites, their efficient reabsorption via PEPT2 may reduce the burden of xenobiotics in milk.     

Visfatin is present in bovine mammary epithelial cells, lactating mammary gland and milk, and its expression is regulated by cAMP pathway

Visfatin was originally identified as a growth factor for immature B cells, and recently demonstrated to bind insulin receptor. Visfatin mRNA and protein were detected by RT-PCR and Western blot analysis in cloned bovine mammary epithelial cells, lactating bovine mammary gland and human breast cancer cell line, MCF-7. Immunocytochemical staining localized the visfatin protein in the cytosol and nucleus of both cells. Quantitative-RT-PCR analysis revealed that the expression of the visfatin mRNA was significantly elevated when treated with forskolin (500 microM), isopreterenol (1-10 microM) and dibutyric cyclic AMP (1 mM) for 24 h, and significantly reduced when treated with insulin (5-50 ng/ml) and dexsamethasone (0.5-250 nM) for 24 h. These results indicate that mammary epithelial cells express the visfatin protein and secrete them into the milk.     

Bovine lactoferrin mRNA: sequence, analysis, and expression in the mammary gland.

The mRNA sequence for bovine lactoferrin expressed in the mammary gland was determined by sequencing three over lapping cDNA clones and by direct sequencing of the mRNA. The mRNA (2351 bases) codes for a 708 amino acid protein with a 19 amino acid signal peptide immediately preceding a sequence identical to the N-terminal 40 amino acids reported for bovine lactoferrin. A putative destabilizing sequence (AUUUA) was identified in the 3'-untranslated region. The nucleic acid sequence and deduced amino acid sequence are highly homologous with other transferrin family members. Lactoferrin mRNA concentrations in bovine mammary tissue were quite low two days before parturition and during lactation but were high three days after the cessation of milking, a sharp contrast from the pattern of regulation of the other milk proteins.     

Cloning, characterization, and tissue distribution of messenger RNA species expressed at moderate and scarce frequencies within the lactating guinea pig mammary gland

In the lactating guinea pig mammary gland, the most abundant mRNA species encoding the major milk proteins, alpha-lactalbumin and caseins A, B, and C, have been extensively studied. Here we describe the isolation and characterization of cloned cDNA sequences representative of moderately abundant and scarce mammary gland mRNA species present at estimated concentrations of 1,400 (pgpO5), 540 (pgpKE6), 36 (pgpK1), and 2 (pgpJF4) copies per sequence per cell. RNA blotting showed these to represent mRNA species of 1,150, 1,900, 1,250, and 3,300 nucleotides in size, respectively. Hybrid selection cell-free synthesis showed that the mRNAs encoded proteins of Mr 33,000 (pgpO5), 58,000 (pgpKE6), and 36,000 (pgpK1). Studies on the tissue distribution of mammary gland mRNAs showed that the mRNA species of lower abundance, but not milk protein mRNAs, were expressed in other tissues but at concentrations differing from those in the mammary gland. None were expressed in all tissues, and so were not typical "housekeeping" proteins. We have used these cloned cDNA species to reinvestigate the apparent differential accumulation of moderately abundant poly(A)-containing mRNA species in polyadenylated and nonpolyadenylated cytoplasmic RNA populations of the mammary gland. Unlike previous observations, based on RNA excess hybridization using fractionated cDNA probes, the use of sequence-specific cloned cDNA probes showed that little intact mRNA was present in the nonpolyadenylated fraction. Thus previous observations were a reflection of the preferential accumulation of fragments of moderately abundant mRNA species, possibly a result of enhanced turnover. The significance of our results in terms of future investigations into factors which determine mRNA accumulation and tissue-specific expression is discussed.