Coumestrol induces oxidative stress and impairs migration and embryonic growth.

In brief: Healthy development of the placenta is dependent on trophoblast cell migration and reduced oxidative stress presence. This article describes how a phytoestrogen found in spinach and soy causes impaired placental development during pregnancy. Abstract: Although vegetarianism has grown in popularity, especially among pregnant women, the effects of phytoestrogens in placentation lack understanding. Factors such as cellular oxidative stress and hypoxia and external factors including cigarette smoke, phytoestrogens, and dietary supplements can regulate placental development. The isoflavone phytoestrogen coumestrol was identified in spinach and soy and was found to not cross the fetal-placental barrier. Since coumestrol could be a valuable supplement or potent toxin during pregnancy, we sought to examine its role in trophoblast cell function and placentation in murine pregnancy. After treating trophoblast cells (HTR8/SVneo) with coumestrol and performing an RNA microarray, we determined 3079 genes were significantly changed with the top differentially changed pathways related to the oxidative stress response, cell cycle regulation, cell migration, and angiogenesis. Upon treatment with coumestrol, trophoblast cells exhibited reduced migration and proliferation. Additionally, we observed increased reactive oxygen species accumulation with coumestrol administration. We then examined the role of coumestrol within an in vivo pregnancy by treating wildtype pregnant mice with coumestrol or vehicle from day 0 to 12.5 of gestation. Upon euthanasia, fetal and placental weights were significantly decreased in coumestrol-treated animals with the placenta exhibiting a proportional decrease with no obvious changes in morphology. Therefore, we conclude that coumestrol impairs trophoblast cell migration and proliferation, causes accumulation of reactive oxygen species, and reduces fetal and placental weights in murine pregnancy.

Dermal Lymphatic Capillaries Do Not Obey Murray's Law.

Lymphatic vessels serve as a major conduit for the transport of interstitial fluid, immune cells, lipids and drugs. Therefore, increased knowledge about their development and function is relevant to clinical issues ranging from chronic inflammation and edema, to cancer metastasis to targeted drug delivery. Murray's Law is a widely-applied branching rule upheld in diverse circulatory systems including leaf venation, sponge canals, and various human organs for optimal fluid transport. Considering the unique and diverse functions of lymphatic fluid transport, we specifically address the branching of developing lymphatic capillaries, and the flow of lymph through these vessels. Using an empirically-generated dataset from wild type and genetic lymphatic insufficiency mouse models we confirmed that branching blood capillaries consistently follow Murray's Law. However surprisingly, we found that the optimization law for lymphatic vessels follows a different pattern, namely a Murray's Law exponent of ~1.45. In this case, the daughter vessels are smaller relative to the parent than would be predicted by the hypothesized radius-cubed law for impermeable vessels. By implementing a computational fluid dynamics model, we further examined the extent to which the assumptions of Murray's Law were violated. We found that the flow profiles were predominantly parabolic and reasonably followed the assumptions of Murray's Law. These data suggest an alternate hypothesis for optimization of the branching structure of the lymphatic system, which may have bearing on the unique physiological functions of lymphatics compared to the blood vascular system. Thus, it may be the case that the lymphatic branching structure is optimized to enhance lymph mixing, particle exchange, or immune cell transport, which are particularly germane to the use of lymphatics as drug delivery routes.