Pten对奶牛乳腺上皮细胞活力及乳蛋白合成的影响

Pten作为抑癌基因,参与调控细胞生长、粘附、凋亡以及其它细胞活动.目前,国内外关于Pten在奶牛乳腺发育过程中表达及调节的研究鲜有报道.为了揭示Pten的表达与奶牛乳腺发育与泌乳之间的关系,本研究应用qRT-PCR技术检测Pten在不同泌乳时期和不同乳品质的奶牛乳腺组织中的表达差异,进而应用脂质体转染方法,通过siRNA介导的RNA干扰技术改变Pten基因在奶牛乳腺上皮细胞中的表达量,CASY法检测细胞活力,用ELISA试剂盒检测细胞分泌β-酪蛋白的含量,采用qRT-PCR、Western 印迹等技术检测Pten对奶牛乳腺上皮细胞中乳蛋白相关信号通路基因表达的影响.结果显示,泌乳期高乳品质奶牛乳腺组织中Pten表达水平显著低于泌乳期低乳品质及干乳期奶牛;Pten基因沉寂后,细胞活力提高,β-酪蛋白质量浓度增加,CSN2、AKT、MTOR、STAT5表达量增加.研究表明,Pten可通过抑制细胞活力和乳蛋白分泌而影响泌乳.     

The epithelial cells and cell fragments in human milk

Summary The cell fragments and epithelial cells in human milk were examined in samples obtained from 30 women: 3 of these provided sequential samples at weekly intervals for 110 days. Membrane-bound cytoplasmic fragments in the sedimentation pellet greatly outnumbered the population of intact cells in all samples. Most of the fragments were derived from secretory cells and contained numerous cisternae of rough endoplasmic reticulum, lipid droplets and Golgi vesicles containing casein micelles. Secretory epithelial cells were present in small numbers in all samples and after the 2nd month of lactation replaced the macrophage as the predominant cell type. Ductal epithelial cells represented less than 1% of the total cell population up to 8 days post-partum, but thereafter they were very rarely found. They occurred in aggregates of 2–4 cells and possessed tight junctions that circumscribed the area of cell-cell contact. All samples of milk contained squamous epithelial cells derived from the galactophores and/or the skin of the nipple. Bacteria were often attached to the surface of the squamous cells. The possible relationship between the presence of secretory epithelial cells in milk and the occurrence of milk proteins in the blood of lactating women is discussed.     

Cell turnover and gene activities in sheep mammary glands prior to lambing to involution

Mammary glands are special tissue characterized by proliferation of the epithelium, during puberty and pregnancy and by programmed cell death, during involution. In this study, apoptosis was identified by TUNEL staining and then related to cell proliferation, as determined by Ki-67 staining. The apoptotic index was at its highest at 8 days of involution, whereas the proliferation index was at its highest during lactation. Caspase-3 was immunolocalised only in mast cells and along the basal membrane in the mammary tissue at −10 days from lambing, 150 days of lactation and at 8 days of involution. This finding could indicate that caspase-3 is not involved in sheep mammary gland apoptosis, but that other proteins – such as apoptosis inducing factor (AIF) – can trigger apoptosis, through the mitochondrial pathway, in a caspase-independent manner. The expression of genes involved in the regulation of lactation and apoptosis was also investigated and determined relatively to −10 days from lambing. The relative expression level of LALBA, reached its maximum during lactation, whereas the expressions of BCL2, BCL2L1, BAX, STAT5A, STAT3, IGFBP5 and FOXO3A, increased significantly during involution in correlation with apoptotic index.This work shows for the first time the turnover of mammary cells and the interaction of their signals during the complete lactation cycle in sheep. The data on gene expression can contribute to elucidate the mechanisms controlling milk production and cell turnover in this species.     

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.     

Expression of constitutively activated Akt in the mammary gland leads to excess lipid synthesis during pregnancy and lactation

Expression of constitutively activated Akt in the mammary glands of transgenic mice results in a delay in post-lactational involution. We now report precocious lipid accumulation in the alveolar epithelium of mouse mammary tumor virus-myr-Akt transgenic mice accompanied by a lactation defect that results in a 50% decrease in litter weight over the first 9 days of lactation. Although ductal structures and alveolar units develop normally during pregnancy, cytoplasmic lipid droplets appeared precociously in mammary epithelial cells in early pregnancy and were accompanied by increased expression of adipophilin, which is associated with lipid droplets. By late pregnancy the lipid droplets had become significantly larger than in nontransgenic mice, and they persisted into lactation. The fat content of milk from lactating myr-Akt transgenic mice was 65-70% by volume compared to 25-30% in wild-type mice. The diminished growth of pups nursed by transgenic mothers could result from the high viscosity of the milk and the inability of the pups to remove sufficient quantities of milk by suckling. Transduction of the CIT3 mammary epithelial cell line with a recombinant human adenovirus encoding myr-Akt resulted in an increase in glucose transport and lipid biosynthesis, suggesting that Akt plays an important role in regulation of lipid metabolism.     

Establishment and characterization of a lactating dairy goat mammary gland epithelial cell line

To study milk synthesis in dairy goat mammary gland, we had established an in vitro lactating dairy goat mammary epithelial cell (DGMEC) line. Mammary tissues of Guan Zhong dairy goats at 35 d of lactation were dispersed and cultured in a medium containing epithelial growth factor, insulin-like growth factor-1, insulin transferrin serum, and fetal bovine serum. Epithelial cells were enriched by digesting with 0.25% trypsin repeatedly to remove fibroblast cells and were identified as epithelial origin by staining with antibody against cytokeratine 18. The DGMECs displayed monolayer, cobble-stone, epithelial-like morphology, and formed alveoli-like structures and island monolayer aggregates which were the typical characteristics of mammary epithelial cells. A one-half logarithmically growth curve and cytoplasmic lipid droplets in these cells were observed. In this paper, we also studied the lactating function of DGMECs. Results showed that DGMECs could secrete lactose and β-casein. Lactating function of the cells had no obvious change after 48 h treated by insulin, while prolactin could obviously raise the secretion of milk proteins and lactose.     

Characterization of cells cultured from early lactation milks.

Two major types of cells can be cultured from early lactation human milks: a colony-forming epithelial cell and an adherent nondividing cell referred to as a foam cell. The epithelial cells show a positive reaction with a specific antiserum reactive against membrane components of the milk fat globule, whereas the foam cells do not. The nondividing foam cells are phagocytic and can be killed by silica particles; they produce lysozyme, are resistant to trypsinization, and have Fc receptors. These properties, together with the lack of reaction with antiserum to the milk fat globule membrane, suggest that the foam cells are not terminally differentiated epithelial cells, but tissue macrophages.     

The epithelial glucocorticoid receptor is required for the normal timing of cell proliferation during mammary lobuloalveolar development but is dispensable for milk production

Glucocorticoids have been shown to influence mammary gland function in vivo and to stimulate milk protein gene expression in vitro. Here, we describe the generation and analysis of a mouse model to study glucocorticoid receptor (GR, NR3C1) function in mammary epithelial cells. Using the Cre-loxP system, mutant mice were obtained in which the GR gene is specifically deleted in epithelial cells during lobuloalveolar development, leading to a complete loss of epithelial GR at the onset of lactation. Mice harboring the mammary-epithelial-specific GR mutation are able to nurse their litters until weaning. During pregnancy, however, GR deficiency delays lobuloalveolar development, leading to an incomplete epithelial penetration of the mammary fat pad that persists throughout lactation. We identified a reduced cell proliferation during lobuloalveolar development as reason for this delay. This reduction is compensated for by increased epithelial proliferation after parturition in the mutant glands. During lactation, GR-deficient mammary epithelium is capable of milk production and secretion. The expression of two milk proteins, namely whey acidic protein and beta-casein, during lactation was not critically affected in the absence of GR. We conclude that GR function is not essential for alveolar differentiation and milk production, but influences cell proliferation during lobuloalveolar development.     

Potential uses of milk epithelial cells: a review

Secretions collected from the mammary gland of different species contain heterogeneous populations of cells including lymphocytes, neutrophils, macrophages and epithelial cells in different species. Several factors influence the somatic cell count in milk and the distribution of cell types, such as species, infection status, physiological status and management practices. The epithelial cells are shed into milk during the lactation process. Most of them are viable and exhibit the characteristics of fully differentiated alveolar cells. Primary cultures of epithelial cells from colostrum and milk of humans, baboons, cows and goats together with established cell lines from human and goat milk, provide a good model for the study of lactogenesis, immunity transmission, cancer research and infection by viruses. The RNA extracted from milk cells have been shown to be representative of gene expression in the mammary gland and thus provide a source of material for molecular studies of gene expression and environmental interactions.     

Stem Cell Research: A Novel Boulevard towards Improved Bovine Mastitis Management

The dairy industry is a multi-billion dollar industry catering the nutritional needs of all age groups globally through the supply of milk. Clinical mastitis has a severe impact on udder tissue and is also an animal welfare issue. Moreover, it significantly reduces animal value and milk production. Mammary tissue damage reduces the number and activity of epithelial cells and consequently contributes to decreased milk production. The high incidence, low cure rate of this highly economic and sometimes deadly disease is an alarming for dairy sector as well as policy makers. Bovine mammary epithelial cells (MECs) and their stem cells are very important in milk production and bioengineering. The adult mammary epithelium consists of two main cell types; an inner layer of luminal epithelial cells, which produce the milk during lactation, and an outer layer of myoepithelial cells resting on a basement membrane, which are responsible for pushing the milk through the ductal network to the teat cistern. Inner layer of columner/luminal cells of bovine MECs, is characterized by cytokeratin18, 19 (CK18, CK19) and outer layer such as myoepithelial cells which are characterized by CK14, α-smooth muscle actin (α-SMA) and p63. Much work has been done in mouse and human, on mammary gland stem cell research, particularly in cancer therapy, but stem cell research in bovine is still in its infancy. Such stem/progenitor cell discoveries in human and mouse mammary gland bring some hope for application in bovines. These progenitors may be therapeutically adopted to correct the structural/cytological defects in the bovine udder due to mastitis. In the present review we focused on various kinds of stem/progenitor cells which can have therapeutic utility and their possibilities to use as a potential stem cell therapy in the management of bovine post-mastitis damage in orders to restore milk production. The possibilities of bovine mammary stem cell therapy offers significant potential for regeneration of tissues that can potentially replace/repair diseased and damaged tissue through differentiation into epithelial, myoepithelial and/or cuboidal/columnar cells in the udder with minimal risk of rejection and side effects.     

Localization and expression of BCAT during pregnancy and lactation in the rat mammary gland

During lactation, branched-chain aminotransferase (BCAT) gene expression increases in the mammary gland. To determine the cell type and whether this induction is present only during lactation, female rats were randomly assigned to one of three experimental groups: pregnancy, lactation, or postweaning. Mammary gland BCAT activity during the first days of pregnancy was similar to that of virgin rats, increasing significantly from day 16 to the last day of pregnancy. Maximal BCAT activity occurred on day 12 of lactation. During postweaning, BCAT activity decreased rapidly to values close to those observed in virgin rats. Analyses by Western and Northern blot revealed that changes in enzyme activity were accompanied by parallel changes in the amount of enzyme and its mRNA. Immunohistochemical studies of the mammary gland showed a progressive increase in mitochondrial BCAT (mBCAT)-specific staining of the epithelial acinar cells during lactation, reaching high levels by day 12. Immunoreactivity decreased rapidly after weaning. There was a significant correlation between total BCAT activity and milk production. These results indicate that the pattern of mBCAT gene expression follows lactogenesis stages I and II and is restricted to the milk-producing epithelial acinar cells. Furthermore, BCAT activity is associated with milk production in the mammary gland during lactation.     

Characterization of cells cultured from early lactation milks

Summary Two major types of cells can be cultured from early lactation human milks: a colony-forming epithelial cell and an adherent nondividing cell referred to as a foam cell The epithelial cells show a positive reaction with a specific antiserum reactive against membrane components of the milk fat globule, whereas the foam cells do not. The nondividing foam cells are phagocytic and can be killed by silica particles; they produce lysozyme, are resistant to trypsinization, and have Fc receptors. These properties, together with the lack of reaction with antiserum to the milk fat globule membrane, suggest that the foam cells are not terminally differential epithelial cells, but tissue macrophages. R. L. C. was supported by Grant No. Ca 19455 from the National Cancer Institute, a Yamagiawa-Yoshida Memorial International Cancer Study Grant, and the Imperial Cancer Research Fund. J. A. P. was supported by Grant No. CA 19455 from the National Cancer Institute.     

Histological and histochemical study on mammary gland of Damascus goats through stages of lactation

This research was carried out on seven Damascus goats, to study the relationship between milk production, during advancing lactation, and the changes in secretory mammary cells frequency and cellular activity. Biopsies were obtained from the mammary gland at the three stages of lactation, early, mid and late, for histological and histochemical studies. The histological structures of the mammary gland showed clear differences between lactation stages—being more developed in the early and the mid stages, compared to the late stage of lactation. The number of the alveolar secretory cells increased from the early to the mid stage of lactation by 12.9% and then was reduced at the late stage by 35.9% from that at the mid stage. The milk yield increased by 51.3% from the early to the mid stage, and then was reduced at the late stage by 71.4% from that of the mid stage. The total sectional areas of plate equal to 1.22 mm²/plate of the alveoli were the smallest during late lactation (0.36 mm²/plate) compared to that during the early and the mid stage of lactation (0.50 and 1.17 mm²/plate, respectively). Numerous loci of alkaline phosphatase enzyme (AP) were apparent on the outer surface of the alveolar secretory cells at the early and the mid stages of lactation—suggesting that this enzyme plays an important physiological role in the apical membrane of the alveolar epithelial cells during lactation. Dense protein staining of these cells as well as increased frequency of DNA expression denote great development and increased numbers of these cells at early and mid stages of lactation. This was accompanied by a high level of milk secretion reaching 939.3 ± 130 and 1421.4 ± 123.4 ml/head/day, respectively. In contrast, at the late stage of lactation, the size of alveoli was reduced and few alveoli showed weak AP activity, weak protein manifestation and the lowest frequency of DNA loci. This coincided with the reduction in milk yield (407 ml/head/day). It could be concluded that the stages of the lactation influence the cell number and activity of the mammary parenchyma.     

The Role of the Microenvironment in Mammary Gland Development and Cancer

The mammary gland is composed of a diverse array of cell types that form intricate interaction networks essential for its normal development and physiologic function. Abnormalities in these interactions play an important role throughout different stages of tumorigenesis. Branching ducts and alveoli are lined by an inner layer of secretory luminal epithelial cells that produce milk during lactation and are surrounded by contractile myoepithelial cells and basement membrane. The surrounding stroma comprised of extracellular matrix and various cell types including fibroblasts, endothelial cells, and infiltrating leukocytes not only provides a scaffold for the organ, but also regulates mammary epithelial cell function via paracrine, physical, and hormonal interactions. With rare exceptions breast tumors initiate in the epithelial compartment and in their initial phases are confined to the ducts but this barrier brakes down with invasive progression because of a combination of signals emitted by tumor epithelial and various stromal cells. In this article, we overview the importance of cellular interactions and microenvironmental signals in mammary gland development and cancer.The mammary gland is composed of a combination of multiple cell types that together form complex interaction networks required for the proper development and functioning of the organ. The branching milk ducts are formed by an outer myoepithelial cell layer producing the basement membrane (BM) and an inner luminal epithelial cell layer producing milk during lactation. The ducts are surrounded by the microenvironment composed of extracellular matrix (ECM) and various stromal cell types (e.g., endothelial cells, fibroblasts, myofibroblasts, and leukocytes). Large amount of data suggest that cell-cell and cell-microenvironment interactions modify the proliferation, survival, polarity, differentiation, and invasive capacity of mammary epithelial cells. However, the molecular mechanisms underlying these effects are poorly understood. The purification and comprehensive characterization of each cell type comprising normal and neoplastic human breast tissue combined with hypothesis testing in cell culture and animal models are likely to improve our understanding of the role these cells play in the normal functioning of the mammary gland and in breast tumorigenesis. In this article, we overview cellular and microenvironmental interactions that play important roles in the normal functioning of the mammary gland and their abnormalities in breast cancer.