Regulatory role for amino acids in mammary gland growth and milk synthesis

The health and growth of mammalian neonates critically depend on the yield and composition of their mothers' milk. However, impaired lactogenesis occurs in both women in response to stress and hormonal imbalance and in primiparous sows which exhibit low voluntary feed intake and underdevelopment of mammary tissues. Because of ethical concerns over lactation research with women and children, swine is often used as an animal model to study mammary gland development and the underlying regulatory mechanisms. Available evidence from work with lactating sows shows that amino acids are not only building blocks for protein but are also key regulators of metabolic pathways critical to milk production. Particularly, arginine is the common substrate for the generation of nitric oxide (NO; a major vasodilator and angiogenic factor) and polyamines (key regulators of protein synthesis). Thus, modulation of the arginine-NO pathway may provide a new strategy to enhance the growth (including vascular growth) of mammary tissue and its uptake of nutrients, therefore improving lactation performance in mammals. In support of this proposition, supplementing 0.83% L: -arginine (as 1% L: -arginine-HCl) or 50 mg/day diethylenetriamine-NO adduct (NO donor) to diets of lactating primiparous sows increased milk production and the growth of suckling piglets. Future studies with animal models (e.g., pigs, sheep, cows, and rats) are necessary to elucidate the underlying mechanisms at molecular, cellular, tissue, and whole-body levels.     

Biosynthesis of lactosamine in bovine mammary gland

Lactosamine (beta-D-Galp-(1-->4)-D-GlcN) was isolated from bovine milk sampled after intravenous infusion of glucosamine through the jugular vein of a lactating cow. The chemical structure was established by 2D NMR spectroscopy and electrospray ionisation mass spectrometry (ESIMS). Selected ion monitoring liquid chromatography-mass spectrometry (SIMLC-MS) of the perbenzoylated carbohydrate fraction showed the presence of the novel disaccharide in the milk sample after infusion, but not in the control bovine milk sample. The results showed the uptake of glucosamine in bovine mammary gland, and also indicated that a part of glucosamine was metabolised to the product lactosamine.     

Synthesis and cloning of DNA complementary to mRNA of the bovine mammary gland

Poly(A+)mRNA from bovine mammary glands was used to synthesize double-stranded cDNAs that were subsequently inserted into the plasmid vector pBR322 at the Pst1 site by means of oligo(dG)-oligo(dC) tailing. After transfection of Escherichia coli JC5183, recombinant plasmid library containing 5400 clones was screened by serial rounds of colony hybridization in situ to total [23P] poly(A+)mRNA and electrophoretically homogenious [32P]16SmRNA of mammary glands. Then hybrid selection of mRNA and subsequent in vitro translation of selected mRNAs were performed. In this manner, recombinant clones coding for alpha S1- beta-, kappa-casein were identified. cDNA clones range in size from 35% for beta-casein, 65% for alpha S1-casein to about 95% for kappa-casein, in comparison with their respective mRNAs.     

Reconstruction of metabolic network in the bovine mammary gland tissue

Understanding bovine metabolism and its relationship with milk products is important in cow breeding. In the present work, the metabolic network in the mammary gland tissue of cattle was reconstructed with the available bovine genome information using several public datasets from NCBI, Uniprot, and KEGG. The network consisted of 1,743 metabolites named by KEGG compound numbers as nodes and 657 enzymes that catalyzed the corresponding reactions as edges. The characteristics of the network were analyzed. The top 20 hub metabolites were determined, and the mean path length was identified to be 6.52. Moreover, 11 key enzymes with significant changes in expression under the condition of mastitis were identified and analyzed by integrating the microarray expression data of normal and clinical mastitis. Aside from the GATM gene, 10 downregulated enzymes were detected in bovine with mastitis. In addition, many of the identified enzymes were involved in amino acid metabolisms or had a direct connection to amino acid metabolisms. These results indicate that mastitis could affect the expression of enzymes, which is vital in some amino acid metabolisms, resulting in the reduction of milk proteins. The present work provides information that may improve the understanding on bovine milk production and mastitis.     

Nuclear bodies in bovine mammary gland in different physiological states

The frequency of nuclear bodies was determined in epithelial cells of mammary ductules or alveoli, milk cistern and teat sinus of virgin heifers, non-lactating cows and cows in early lactation. The determined frequency was within the range 12–16% with the single exception of the epithelial cells of secretory alveoli of lactating cows, in which the frequency was 3 %. These data support the concept that nuclear bodies are normal nuclear organelles which can respond to altered physiological conditions.     

Proteomic analysis of microsomes from lactating bovine mammary gland

Mammary gland has multiple metabolic potential including for large-scale synthesis of milk proteins, carbohydrate, and lipids including nutrient triacylglycerols. We have carried out a proteomic analysis of mammary tissue to discover proteins that affect lipid metabolism. Unfractionated microsomes from lactating bovine mammary tissue were analyzed using one-dimensional SDS-PAGE with RPLC-ESI-MS/MS. This approach gave 703 proteins including 160 predicted transmembrane proteins. Proteins were classified according to their subcellular localizations and biological functions. Over 50 proteins were associated with cellular uptake, metabolism, and secretion of lipids, including some enzymes that have been previously associated with breast cancer and potential therapeutic targets. This database develops a proteomic view of the metabolic potential of mammary gland that can be expected to contribute to a greater understanding of gene expression and tissue remodeling associated with lactation, and to further dissection of normal and pathological processes in mammary tissue.     

Cell hierarchy and lineage commitment in the bovine mammary gland

The bovine mammary gland is a favorable organ for studying mammary cell hierarchy due to its robust milk-production capabilities that reflect the adaptation of its cell populations to extensive expansion and differentiation. It also shares basic characteristics with the human breast, and identification of its cell composition may broaden our understanding of the diversity in cell hierarchy among mammals. Here, Lin⁻ epithelial cells were sorted according to expression of CD24 and CD49f into four populations: CD24^medCD49f^pos (putative stem cells, puStm), CD24^negCD49f^pos (Basal), CD24^highCD49f^neg (putative progenitors, puPgt) and CD24^medCD49f^neg (luminal, Lum). These populations maintained differential gene expression of lineage markers and markers of stem cells and luminal progenitors. Of note was the high expression of Stat5a in the puPgt cells, and of Notch1, Delta1, Jagged1 and Hey1 in the puStm and Basal populations. Cultured puStm and Basal cells formed lineage-restricted basal or luminal clones and after re-sorting, colonies that preserved a duct-like alignment of epithelial layers. In contrast, puPgt and Lum cells generated only luminal clones and unorganized colonies. Under non-adherent culture conditions, the puPgt and puStm populations generated significantly more floating colonies. The increase in cell number during culture provides a measure of propagation potential, which was highest for the puStm cells. Taken together, these analyses position puStm cells at the top of the cell hierarchy and denote the presence of both bi-potent and luminally restricted progenitors. In addition, a population of differentiated luminal cells was marked. Finally, combining ALDH activity with cell-surface marker analyses defined a small subpopulation that is potentially stem cell- enriched.     

Characterization of anionic amino acid transport systems in mouse mammary gland

L-glutamate was transported into mammary tissue via Na(+)-dependent system XAG- that strongly interacted with both D- and L-isomers of aspartate but only with L-isomer of glutamate. Replacement of Cl- by gluconate from the extracellular medium did not affect the uptake of L-glutamate. Although neutral amino acids weakly inhibited the uptake of L-glutamate, there was no evidence for the heterogeneity of anionic amino acid transport system. The XAG- system was inhibited by sulfhydryl group blocking reagent N-ethylmalemide. Low pH (6) partially inhibited the uptake by L-glutamate by mammary tissue. Prior loading of mammary tissue with L-glutamate slightly down regulated its uptake. Culturing pregnant mouse mammary tissue explants in vitro in the presence of lactogenic hormones (insulin plus cortisol plus prolactin) did not affect appreciably the uptake of L-glutamate.     

Mobilization of neutrophils and defense of the bovine mammary gland

The leucocytes present in normal milk are not very efficient in preventing infection, because very small numbers of bacteria are able to induce infection experimentally. The mobilization of phagocytes from the blood to milk appears crucial in coping with the expansion of the bacterial population in the mammary gland. Important parameters for the outcome of mammary infections are the bactericidal efficiency of neutrophils and the antiphagocytic and cytotoxic properties of the invading bacteria, but several studies have shown that the promptness and the magnitude of the initial recruitment of neutrophils by the infected mammary gland have a profound influence on the severity and the outcome of mastitis. This is an incentive for studying the mechanisms behind the mobilization of neutrophils to the mammary gland. Although milk macrophages may play a role in the triggering of the inflammatory response, studies on several responses to infections at various epithelium sites strongly suggest that epithelial cells are capable of responding to bacterial intrusion and play a major part in the initiation of inflammation. A better knowledge of the effector cells and of the mediators involved in the mobilization of neutrophils could help in devising strategies to modulate this important determinant of milk quality and udder defense.