黄牛泌乳系统正常菌群的检测

采用稀释滴种法对30头健康黄牛泌乳系统的10种主要正常菌群分四个部位(乳头、乳池、输乳管和腺泡)进行定性、定量检测。结果有6种菌群被检测出,按数量由多至少依次为棒状杆菌、乳杆菌、葡萄球菌、芽胞杆菌、双歧杆菌和肠杆菌。乳头的优势菌群为棒状杆菌、芽胞杆菌和葡萄球菌;乳池、输乳管和腺泡的优势菌群均为棒状杆菌和乳杆菌。黄牛泌乳系统各正常菌群的数量均较少,远低于其他孔道系统。     

Organoid models for mammary gland dynamics and breast cancer

The mammary gland is a highly dynamic tissue that undergoes repeated cycles of growth and involution during pregnancy and menstruation. It is also the site from which breast cancers emerge. Organoids provide an in vitro model that preserves several of the cellular, structural, and microenvironmental features that dictate mammary gland function in vivo and have greatly advanced our understanding of glandular biology. Their tractability for genetic manipulation, live imaging, and high throughput screening have facilitated investigation into the mechanisms of glandular morphogenesis, structural maintenance, tumor progression, and invasion. Opportunities remain to enhance cellular and structural complexity of mammary organoid models, including incorporating additional cell types and hormone signaling.     

Secretion of recombinant human fibrinogen by the murine mammary gland

Transgenic animals secreting individual chains and assembled fibrinogen were produced to evaluate the capacity of the mammary gland for maximizing assembly, glycosylation and secretion of recombinant human fibrinogen (rhfib). Transgenes were constructed from the 4.1kbp murine Whey Acidic Protein promoter (mWAP) and the three cDNAs coding for the A, B and fibrinogen chains. Transgenic mice secreted fully assembled fibrinogen into milk at concentrations between 10 and 200 g/ml, with total secretion of subunits approaching 700 g/ml in milk. Partially purified fibrinogen was shown to form a visible and stable clot after treatment with human thrombin and factor XIII. The level of assembled fibrinogen was proportional to the lowest amount of subunit produced where both the B and chains were rate limiting. Both the B and chains were glycosylated when co-expressed and the degree of saccharide maturation was dependent on expression level, with processing preferred for chains over B chains. Also, the subunit complexes ₂, A₂ and the individual subunits A, B and were found as secretion products. When the B was secreted individually, the glycosylation profile of the molecule was of a mature complex saccharide indicating recognition of the molecule by the glycosylation pathway without association with other fibrinogen chains. To date secretion of B chain has been not observed in any cell type, suggesting that the secretion pathway in mammary epithelia is less restrictive than that occurring in hepatocytes and other cells previously used to study fibrinogen assembly.     

Identification and characterization of microRNAs from the bovine adipose tissue and mammary gland

We report the identification of bovine miRNAs by cloning small RNAs from adipose tissue and the mammary gland. Fifty-nine distinct miRNAs were identified, five of them were not homologous to known mammalian miRNAs, and many of them had 3' and/or 5' end variants. Ribonuclease protection assays indicated that miR-23a and miR-24, whose genes are closely located on the same chromosome, were co-expressed in different tissues. The assays also suggested a role for several miRNAs in the mammary gland and a role for miR-133, a previously known skeletal and cardiac muscle-specific miRNA, in the rumen, an organ unique to the ruminant.     

Oestrogen receptor-alpha regulates non-canonical Hedgehog-signalling in the mammary gland

Mesenchymal dysplasia (mes) mice harbour a truncation in the C-terminal region of the Hh-ligand receptor, Patched-1 (mPtch1). While the mes variant of mPtch1 binds to Hh-ligands with an affinity similar to that of wild type mPtch1 and appears to normally regulate canonical Hh-signalling via smoothened, the mes mutation causes, among other non-lethal defects, a block to mammary ductal elongation at puberty. We demonstrated previously Hh-signalling induces the activation of Erk1/2 and c-src independently of its control of smo activity. Furthermore, mammary epithelial cell-directed expression of an activated allele of c-src rescued the block to ductal elongation in mes mice, albeit with delayed kinetics. Given that this rescue was accompanied by an induction in estrogen receptor-alpha (ERα) expression and that complex regulatory interactions between ERα and c-src are required for normal mammary gland development, it was hypothesized that expression of ERα would also overcome the block to mammary ductal elongation at puberty in the mes mouse. We demonstrate here that conditional expression of ERα in luminal mammary epithelial cells on the mes background facilitates ductal morphogenesis with kinetics similar to that of the MMTV-c-src^Act mice. We demonstrate further that Erk1/2 is activated in primary mammary epithelial cells by Shh-ligand and that this activation is blocked by the inhibitor of c-src, PP2, is partially blocked by the ERα inhibitor, ICI 182780 but is not blocked by the smo-inhibitor, SANT-1. These data reveal an apparent Hh-signalling cascade operating through c-src and ERα that is required for mammary gland morphogenesis at puberty.     

Morphogenesis and secretory activity of mouse mammary cultures on EHS biomatrix

Summary The nature of the substratum profoundly influences the growth and function of epithelia in tissue culture. Mammospheres, hollow spherical structures, develop when epithelial clusters are plated on a biomatrix derived from the Engelbreth-Holm-Swarm murine tumour (EHS matrix). Morphologic examination of mammosphere development demonstrates that morphogenesis is a two stage process. Over the first 48 h the cells aggregate into spheres, drawing the matrix up and over themselves to become buried within the material. Changes in matrix morphology emphasize the importance of the quasi-fluid nature of the substratum on which the cells are plated. Lumen formation ensues over the next 2 to 5 days as the cells, polarized by basal contact with the matrix, differentiate. They form tight junctions at their apical borders and synthesize milk proteins, secreting caseins into the enlarging interior cavity and transferrin from their basal surfaces into the medium. These experiments demonstrate that the physical properties of the EHS matrix allow epithelial cells to develop the cuboidal shape necessary for secretory activity.Abbreviations EHS Engelbreth-Holm-Swarm biomatrix     

Increased gene expression of endothelin-1 and vasoactive intestinal contractor/endothelin-2 in the mammary gland of lactating mice

In an attempt to understand the roles of endothelin-1 (ET-1) and vasoactive intestinal contractor/endothelin-2 (VIC/ET-2), we have studied the genes for both peptides to be expressed in the mammary gland of lactating mice. We observed through real-time PCR analysis that ET-1 and VIC/ET-2 gene expression gradually increase after parturition and that ET-1 gene expression is significantly higher than that of VIC/ET-2. The distribution of ET-1 peptide was found to be localized mainly in the epithelial cells of the mammary gland at 14th day of lactation. ET-1 gene expression increases significantly, parallel to the increase in beta-casein gene expression, in epithelial cell lines (HC11) of mouse mammary gland after hormonal stimulation by addition of dexamethazone and prolactin. The observed increase in ET-1 expression in differentiated epithelial cells suggests physiological roles for ET-1, including milk production and secretion in the mammary gland of lactating mice.     

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.     

Origin,concentration and structural features of human mammary gland cells cultured from breast secretions

Summary This study traced the origin of cells observed in human breast secretion samples obtained during lactation and describes the appearance of these cells following prolonged maintenance in vitro. Human milk contains a large number of single vacuolated foam cells and a small proportion of non-vacuolated epithelial cells in clusters. Foam cells are identified by their large size, the polarity of their cytoplasmic organelles, the variation in number and size of lipid vacuoles and the condensed chromatin of their eccentrically located nucleus. Both cell types originate by exfoliation from the mammary gland. This was established by comparing the structural characteristics of cells isolated from milk with those of the cuboidal cell linings of ducts and alveoli in lactating mammary tissue. Relatively pure populations of foam cells could be established from early lactation samples (3–7 days post/partum) while non-vacuolated epithelial cell clusters were more frequently cultured from late lactation specimens (1–10 days postweaning). Foam cells did not divide and lost cytoplasmic organization during prolonged culture. In contrast, non-vacuolated epithelium in clusters proliferated to form colonies of polygonal cells. These results, which imply that foam cells are an active form of the non-vacuolated mammary cells in clusters, call attention to one system for the study of the complex hormonal interactions necessary to induce and maintain lactation.Supported in part by NCI contract NO 1-CB-33898     

The Ron receptor tyrosine kinase negatively regulates mammary gland branching morphogenesis

The Ron receptor tyrosine kinase is expressed in normal breast tissue and is overexpressed in approximately 50% of human breast cancers. Despite the recent studies on Ron in breast cancer, nothing is known about the importance of this protein during breast development. To investigate the functional significance of Ron in the normal mammary gland, we compared mammary gland development in wild-type mice to mice containing a targeted ablation of the tyrosine kinase (TK) signaling domain of Ron (TK−/−). Mammary glands from RonTK−/− mice exhibited accelerated pubertal development including significantly increased ductal extension and branching morphogenesis. While circulating levels of estrogen, progesterone, and overall rates of epithelial cell turnover were unchanged, significant increases in phosphorylated MAPK, which predominantly localized to the epithelium, were associated with increased branching morphogenesis. Additionally, purified RonTK−/− epithelial cells cultured ex vivo exhibited enhanced branching morphogenesis, which was reduced upon MAPK inhibition. Microarray analysis of pubertal RonTK−/− glands revealed 393 genes temporally impacted by Ron expression with significant changes observed in signaling networks regulating development, morphogenesis, differentiation, cell motility, and adhesion. In total, these studies represent the first evidence of a role for the Ron receptor tyrosine kinase as a critical negative regulator of mammary development.     

Secretory membranes of the lactating mammary gland

Summary The lactating mammary gland is one of the most highly differentiated and metabolically active organs in the body. Membranes of the lactating mammary cell have important roles in transmitting from one membrane to another of hormonal information and in milk secretion, which is the final event. During milk secretion, the projection of the surface membrane into the alveolar lumen by enveloping intracellular lipid droplets with the apical plasma membrane is one of the most remarkable aspects of biological membrane action throughout nature.This review focuses on current knowledge about membranes in the lactating mammary gland. (1) Advances in the isolation and properties of membranes, especially the plasma membrane and Golgi-derived secretory vesicles, concerned with milk secretion from the lactating mammary gland are described. (2) Milk serum components are secreted by fusing the membranes of secretory vesicles that condense milk secretions with the plasma membrane in the apical regions. This occurs through the formation of a tubular-shaped projection and vesicular depression in a ball-and-socket configuration, as well as by simple fusion. (3) Intracellular lipid droplets are directly extruded from the mammary epithelial cells by progressive envelopment of the plasma membranes in the apical regions. (4) The balance between the surface volume lost in enveloping lipid droplets and that provided by fusion of the secretory vesicle and other vesicles with the apical plasma membrane is discussed. (5) The membrane surrounding a milk fat globule, which is referred to as the milk fat globule membrane (MFGM), is composed of at least the coating membrane of an intracellular lipid droplet, of the apical plasma membrane and secretory vesicle membrane, and of a coat material. Consequently, MFGM is molecularly different from the plasma membrane in composition. (6) MFGM of bovine milk is structurally composed of an inner coating membrane and outer plasma membrane just after segregation. These two membranes are fused and reorganized through a process of vesiculation and fragmentation to stabilize the fat globules. Hypothetical structural models for MFGM from bovine milk fat globules just after secretion and after rearrangement are proposed.Abbrevations MFGM milk fat globule membrane - HEPES N-2-hydroxylpiperazine-N-2-ethanesulfonic acid - INT 2-(p-indophenyl)-3-(p-nitrophenyl)-5-phenyltetrazolium - SDS-PAGE polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate - Sph sphingomyelin - PC phosphatidyl choline - PE phosphatidyl ethanolamine - PS phosphatidyl serine - PI phosphatidyl inositol - PAS periodic acid-Schiff reagent - CB Coomassie brilliant blue R-250 Dedicated to Professor Stuart Patton on the occasion of his 70th birthday.     

Cloned kids derived from caprine mammary gland epithelial cells

The use of nucleus transfer techniques to generate transgenic dairy goats capable of producing recombinant therapeutic proteins in milk could have a major impact on the pharmaceutical industry. However, transfection or gene targeting of nucleus transfer donor cells requires a long in vitro culture period and the selection of marker genes. In the current study, we evaluated the potential for using caprine mammary gland epithelial cells (CMGECs), isolated from udders of lactating F1 hybrid goats (Capra hircus) and cryopreserved at Passages 24 to 26, for nucleus transfer into enucleated in vivo-matured oocytes. Pronuclear-stage reconstructed embryos were transferred into the oviducts of 31 recipient goats. Twenty-three (74%), 21 (72%), and 14 (48%) recipients were confirmed pregnant by ultrasonography on Days 30, 60, and 90, respectively. Four recipients aborted between 35 and 137 d of gestation. Five recipients carried the pregnancies to term and delivered one goat kid each, one of which subsequently died due to respiratory difficulties. The remaining four goat kids were healthy and well. Single-strand conformation polymorphism analysis confirmed that all kids were clones of the donor cells. In conclusion, the CMGECs remained totipotent for nucleus transfer.     

Sex steroids and growth factors in the regulation of mammary gland proliferation, differentiation, and involution

The mammary gland is subjected to major morphological and biochemical changes during the lactation cycle. It is therefore not surprising that this dynamic process is strictly controlled. The importance of the sex steroid hormones 17beta-estradiol and progesterone for normal development of the mammary gland was recognized several decades ago and has been unequivocally confirmed since. Furthermore, it is now also established that the influence of sex steroids is not restricted to mammogenesis, but that these hormones also control involution. Another important regulatory role is played by growth factors that have been shown to modulate survival (epidermal growth factor, amphiregulin, transforming growth factor alpha, insulin like growth factor, and tumor necrosis factor alpha) or apoptosis (tumor necrosis factor alpha, transforming growth factor beta) of mammary cells. However, the molecular mechanism underlying the influence of sex steroid hormones and/or growth factors on the development and function of the mammary gland remains largely unknown to date. Also scarce is information on the interaction between both groups of modulators. Nevertheless, based on the current indications compiled in this review, an important functional role for sex steroid hormones in the lactation cycle in co-operation with growth factors can be suggested.     

Mast cells contribute to the stromal microenvironment in mammary gland branching morphogenesis

The stromal microenvironment regulates mammary gland branching morphogenesis. We have observed that mast cells are present in the mammary gland throughout its postnatal development and, in particular, are found around the terminal end buds and ductal epithelium of the pubertal gland. Mast cells contribute to allergy, inflammatory diseases, and cancer development but have not been implicated in normal development. Genetic and pharmacological disruption of mast cell function in the mammary gland revealed that mast cells are involved in rapid proliferation and normal duct branching during puberty, and this effect is independent of macrophage recruitment, which also regulates mammary gland development. For mast cells to exert their effects on normal morphogenesis required activation of their serine proteases and degranulation. Our observations reveal a novel role for mast cells during normal pubertal development in the mammary gland.