Regulation and localization of vascular endothelial growth factor within the mammary glands during the transition from late gestation to lactation.

The vascular network within the developing mammary gland (MG) grows in concert with the epithelium to prepare for lactation, although the mechanisms coordinating this vascular development are unresolved. Vascular endothelial growth factor A (VEGF-A) mediates angiogenesis and vascular permeability in the MG during pregnancy and lactation, where its expression is upregulated by prolactin. Given our previous finding that late-gestational hyperprolactinemia induced by domperidone (DOM) increased subsequent milk yield from gilts, we sought to establish changes in vascular development during late gestation and lactation in the MGs of these pigs and determine whether DOM altered MG angiogenesis and the factors regulating it. Gilts received either no treatment (n = 6) or DOM (n = 6) during late gestation, then had their MG biopsied from late gestation through lactation to assess microvessel density, VEGF-A distribution and messenger RNA expression, and aquaporin (AQP) gene expression. Microvessel density in the MG was unchanged during gestation then increased between days 2 and 21 of lactation (P < 0.05). The local expression of messenger RNA for VEGF-A120, VEGF-A147, VEGF-A164, VEGF-A164b, VEGF-A188, VEGF receptors-1 and -2, and AQP1 and AQP3 all generally increased during the transition from gestation to lactation (P < 0.05). Immunostaining localized VEGF-A to the apical cytoplasm of secretory epithelial cells, consistent with a far greater concentration of VEGF-A in colostrum and/or milk vs plasma (P < 0.0001). There was no effect of DOM on any of the variables analyzed. In summary, we found that vascular development in the MG increases during lactation in first-parity gilts and that VEGF-A is a part of the mammary secretome. Although late-gestational hyperprolactinemia increases milk yield, there was no evidence that it altered vascular development.

Late gestational hyperprolactinemia accelerates mammary epithelial cell differentiation that leads to increased milk yield.

The growth rate of piglets is limited by sow milk yield, which reflects the extent of epithelial growth and differentiation in the mammary glands (MG) during pregnancy. Prolactin (PRL) promotes both the growth and differentiation of the mammary epithelium, where the lactational success of pigs is absolutely dependent on PRL exposure during late gestation. We hypothesized that inducing hyperprolactinemia in primiparous gilts during late gestation by administering the dopamine antagonist domperidone (DOM) would increase MG epithelial cell proliferation and differentiation, subsequent milk yield, and piglet growth. A total of 19 Yorkshire-Hampshire gilts were assigned to receive either no treatment (CON, n = 9) or DOM (n = 10) twice daily from gestation d 90 to 110. Serial blood sampling during the treatment period and subsequent lactation confirmed that plasma PRL concentrations were increased in DOM gilts on gestation d 91 and 96 (P < 0.001). Piglets reared by DOM-treated gilts gained 21% more BW during lactation than controls (P = 0.03) because of increased milk production by these same gilts on d 14 (24%, P = 0.02) and 21 (32%, P < 0.001) of lactation. Milk composition did not differ between the 2 groups on d 1 or 20 of lactation. Alveolar volume within the MG of DOM-treated gilts was increased during the treatment period (P < 0.001), whereas epithelial proliferation was unaffected by treatment. Exposure to DOM during late gestation augmented the postpartum increase in mRNA expression within the MG for ß-casein (P < 0.03), acetyl CoA carboxylase-α (P < 0.01), lipoprotein lipase (P < 0.06), α-lactalbumin (P < 0.08), and glucose transporter 1 (P < 0.06). These findings demonstrate that late gestational hyperprolactinemia enhances lactogenesis within the porcine MG and increases milk production in the subsequent lactation.

Triennial Lactation Symposium: Prolactin: The multifaceted potentiator of mammary growth and function.

At face value there are clear and established roles for prolactin (PRL) in the regulation of mammary gland growth, lactogenesis, and galactopoiesis. These actions of PRL do not occur in isolation; rather, they are finely attuned to and coordinated with many local, reproductive, and metabolic events in the female. Hence, to understand PRL action at the level of the mammary gland is to understand the systemic and local contexts in which it acts and functions. Herein we review the functions of PRL, its receptors, and the pathways leading to the phenotypes it evokes within the mammary glands, including growth and lactation, across a variety of species. At one level, the actions of PRL are mediated by several PRL receptor (PRLR) isoforms, including its long form and various short PRLR variants that are generated by alternative splicing in a species- and tissue-dependent manner. In turn, these PRLR activate a variety of intracellular signaling cascades. We also focus on how PRL coordinates with other endocrine cues to impart its effects on the mammary glands, where the ovarian hormones can independently and substantially modulate PRL action. Many of these effects of PRL are also realized at the local level of the mammary gland, either through the autocrine or paracrine synthesis of a multitude of molecules and transcription factors or through its effects on adjacent supporting tissues, including the mammary vasculature. Taken together, it is clear that PRL directs a variety of mechanisms during growth and function of the mammary gland and is deserving of its classification as the master hormone.

Technical note: A vacuum-assisted approach for biopsying the mammary glands of various species.

Biopsy of the mammary glands is a technique used in both research and clinical diagnosis. A vacuum-assisted approach that enables the collection of tissue from the mammary glands of various species is described, along with methods for biopsying cows and pigs. The procedure involves tissue penetration via blunt dissection with a sharpened trocar. Tissue cores are excised and collected via the vacuum-assisted handpiece followed by a saline lavage and wound closure. This approach yields tissue cores of approximately 100 mg, is well suited for use in various species, and affords the potential to reduce postoperative complications.