A novel model for brain iron uptake: introducing the concept of regulation.

Neurologic disorders such as Alzheimer's, Parkinson's disease, and Restless Legs Syndrome involve a loss of brain iron homeostasis. Moreover, iron deficiency is the most prevalent nutritional concern worldwide with many associated cognitive and neural ramifications. Therefore, understanding the mechanisms by which iron enters the brain and how those processes are regulated addresses significant global health issues. The existing paradigm assumes that the endothelial cells (ECs) forming the blood-brain barrier (BBB) serve as a simple conduit for transport of transferrin-bound iron. This concept is a significant oversimplification, at minimum failing to account for the iron needs of the ECs. Using an in vivo model of brain iron deficiency, the Belgrade rat, we show the distribution of transferrin receptors in brain microvasculature is altered in luminal, intracellular, and abluminal membranes dependent on brain iron status. We used a cell culture model of the BBB to show the presence of factors that influence iron release in non-human primate cerebrospinal fluid and conditioned media from astrocytes; specifically apo-transferrin and hepcidin were found to increase and decrease iron release, respectively. These data have been integrated into an interactive model where BBB ECs are central in the regulation of cerebral iron metabolism.

Mitochondria impairment correlates with increased sensitivity of aging RPE cells to oxidative stress.

Impairment of mitochondria function and cellular antioxidant systems are linked to aging and neurodegenerative diseases. In the eye, the retinal pigment epithelium (RPE) is exposed to a highly oxidative environment that contributes to age-related visual dysfunction. Here, we examined changes in mitochondrial function in human RPE cells and sensitivity to oxidative stress with increased chronological age. Primary RPE cells from young (9-20)-, mid-age (48-60)-, and >60 (62-76)-year-old donors were grown to confluency and examined by electron microscopy and flow cytometry using several mitochondrial functional assessment tools. Susceptibility of RPE cells to H(2)O(2) toxicity was determined by lactate dehydrogenase and cytochrome c release, as well as propidium iodide staining. Reactive oxygen species, cytoplasmic Ca(2+) [Ca(2+)](c), and mitochondrial Ca(2+) [Ca(2+)](m) levels were measured using 2',7'-dichlorodihydrofluorescein diacetate, fluo-3/AM, and Rhod-2/AM, respectively, adenosine triphosphate (ATP) levels were measured by a luciferin/luciferase-based assay and mitochondrial membrane potential (ΔΨm) estimated using 5,5',6,6'-tetrachloro 1,1'3,3'-tetraethylbenzimid azolocarbocyanine iodide. Expression of mitochondrial and antioxidant genes was determined by real-time polymerase chain reaction. RPE cells show greater sensitivity to oxidative stress, reduction in expression of mitochondrial heat shock protein 70, uncoupling protein 2, and superoxide dismutase 3, and greater expression of superoxide dismutase 2 levels with increased chronological age. Changes in mitochondrial number, size, shape, matrix density, cristae architecture, and membrane integrity were more prominent in samples obtained from >60 years old compared to mid-age and younger donors. These mitochondria abnormalities correlated with lower ATP levels, reduced ΔΨm, decreased [Ca(2+)](c), and increased sequestration of [Ca(2+)](m) in cells with advanced aging. Our study provides evidence for mitochondrial decay, bioenergetic deficiency, weakened antioxidant defenses, and increased sensitivity of RPE cells to oxidative stress with advanced aging. Our findings suggest that with increased severity of mitochondrial decay and oxidative stress, RPE function may be altered in some individuals in a way that makes the retina more susceptible to age-related injury.

Persistent vascular defects in lung allografts attributed to defective endogenous endothelial progenitors.

BACKGROUND: A major pathological finding in human newborns with pulmonary hypoplasia and congenital diaphragmatic hernia is the presence of vascular abnormalities in lungs. Vasculogenesis/angiogenesis are crucial to lung development. To study lung alveolar development, including microvascular formation in fetal lung implants, Schwarz et al. [1] developed a subcutaneous allograft model. We adopted their model to assess the influence of neovascularization or the "host-graft vascular development" on hypoplastic lung structure and growth. MATERIALS AND METHODS: Normal and hypoplastic lungs at pseudoglandular stage were implanted subcutaneously under the dorsolateral fold of immunocompromised nude mice (athymic, nu/nu). Lung allografts were removed and assessed at 2, 4, 6, and 8 weeks postimplantation. RESULTS: Neovascularization of implanted lungs from subcutaneous vasculature of nude mice resulted in varying degrees of maturation of implanted normal and hypoplastic lungs. By 4 weeks, implanted normal lungs contained Type 2-like cells and by 7 to 8 weeks, Type 2 and Type 1-like cells, air spaces had enlarged, and surfactant secretion was observed. Despite some differentiation and maturation of hypoplastic lungs, there was more mesenchymal tissue, no secondary septa, and smaller air spaces compared to normal lungs. CONCLUSIONS: (a) Neovascularization or host-graft vascular development occurs in both normal and hypoplastic lung allografts. (b) Development and maturation of implanted normal and hypoplastic lungs follow the establishment of the vascular connections between the host and grafts. (c) The host-graft vascular connections do not improve the growth of normal or hypoplastic lungs. (d) Neovascularization failed to overcome the embryonic defects in vascular formation and the pulmonary vasculogenesis remained defective in hypoplastic lung allografts, which may be attributed to the defective endogenous endothelial progenitor cells.

Dynamic changes appearing in collagen fibers during intrinsic tendon repair.

Intrinsic healing of severed tendons shows a delay in a gain in breaking strength and the tendon becomes translucent. The cause of tendon translucence was investigated in suture-repaired rat Achilles tendon. The repair site with adjacent translucent tendon were evaluated histologically on day 10 by immunofluorescence and transmission electron microscopy. The healing tendon translucent region by hematoxylin-eosin staining had few inflammatory cells, polarized light birefringence showed thinner collagen fibers, immunofluorescence showed few myofibroblasts, and transmission electron microscopy revealed frayed, irregular thin collagen fibers. During embryogenesis, tendon fibers grow by the addition of discreet collagen fibril segment structures. The speculation is that collagen fibril segment structures are released from collagen fibers within the translucent tendon region for reuse during the regeneration of tendon collagen fibers during intrinsic tendon repair. Healing tendon translucence is related to a decrease in the diameter of collagen fibers by the release of collagen fibril segments within tendon bundles/fascicles.