Differential mRNA and tissue expression of lymphangiogenic growth factors (VEGF-C and -D) and their receptor (VEGFR-3) during tail regeneration in a gecko.

Lymphangiogenesis, the growth of new lymph vessels, has important roles in both normal and pathological lymphatic function. Despite recent advances, the precise molecular mechanisms behind the lymphangiogenic process remain unclear. The Australian marbled gecko, Christinus marmoratus, voluntarily drops its tail (autotomy) as a predator avoidance strategy. Following autotomy a new tail is regenerated including lymphatic drainage pathways. We examined the molecular control of lymphangiogenesis within the unique model of the regenerating gecko tail. Partial sequences were obtained of the gecko lymphangiogenic growth factors, vascular endothelial growth factor C (VEGF-C) and VEGF-D along with their receptor VEGFR-3. These were highly homologous to other vertebrates. Quantitative real-time polymerase chain reaction (PCR) demonstrated up-regulation of VEGF-C, VEGF-D and VEGFR-3 mRNA expression during the early and middle stages of tail regeneration (between 4 and 9 weeks following autotomy), in late regeneration (12 weeks) and during mid-regeneration (7 and 9 weeks), respectively. VEGF-C and VEGF-D immunostaining was observed lining some lymphatic-like and blood vessels in early-mid tail regeneration, indicating possible associations of the proteins with VEGFRs on endothelia. Keratinocytes and fibroblasts also showed positive staining of VEGF-C and VEGF-D in early-mid tail regeneration. Additionally, VEGF-C was localised in adipose tissue in all tail states examined. This work suggests that specific timings exist for the expression of the lymphangiogenic growth factors, VEGF-C and VEGF-D, and their receptor, VEGF-R3, throughout the regeneration of a functional lymphatic network. Along with localisation data, this suggests potential functions for the growth factors in lymphangiogenesis and angiogenesis throughout tail regeneration.

How regenerating lymphatics function: lessons from lizard tails.

Rational treatment of lymphoedema may be improved in the future with a better understanding of the physiological processes involved in the regeneration of new lymphatic vessels (lymphangiogenesis). Many lizard species undergo tail autotomy as a predator escape response and subsequently regenerate nonlymphoedematous tails. Such species may offer novel models for examining lymphangiogenesis. In this lymphoscintigraphic evaluation, three radioactive tracers were employed, (99m)Tc-antimony trisulphide colloid (approximately 10 nm diameter), (99m)Tc-tin fluoride colloid (approximately 2,000 nm; (99m)Tc-TFC), and (99m)Tc-diethylenetriaminepentaacetic acid (soluble; (99m)Tc-DTPA), to examine lymphatic function in regenerating tails of the Australian marbled gecko, Christinus marmoratus. Rate of local clearance and velocity of migration were determined in geckos with original tails and at 6, 9, 12, and >24 weeks after autotomy. In original-tailed geckos, the smaller radiocolloid was cleared to a greater extent and had a faster lymph velocity than in geckos with regenerated tails. The same parameters measured for larger particles were greater in early regeneration than later. (99m)Tc-TFC did not migrate from the injection site in fully regenerated and original gecko tails, which indicates that larger particles are increasingly impeded as tail regeneration progresses. Soluble (99m)Tc-DTPA diffused from the injection site extremely rapidly via venous capillaries in all tails, confirming that the slower clearance of the colloids is solely via the lymphatics. Differences in clearance and lymph velocity between differently sized colloids throughout tail regeneration may be influenced by changes in surrounding tissue structure density and the lymphatic vessel porosity.

Hypoxic control of the development of the surfactant system in the chicken: evidence for physiological heterokairy.

The surfactant system, a complex mixture of lipids and proteins, controls surface tension in the lung and is crucial for the first breath at birth, and thereafter. Heterokairy is defined as plasticity of a developmental process within an individual. Here, we provide experimental evidence for the concept of heterokairy, as hypoxia induces a change in the onset and rate of development of surfactant, probably via endogenous glucocorticoids, to produce individuals capable of surviving early hatching. Chicken eggs were incubated under normoxic (21% O(2)) conditions throughout or under hypoxic (17% O(2)) conditions from day 10 of incubation. Embryos were sampled at days 16, 18, and 20 and also 24 h after hatching. In a second experiment, dexamethasone (Dex), tri-iodothyronine (T(3)), or a combination (Dex + T(3)) was administered 24 and 48 h before each time point. Both hypoxia and Dex accelerated maturation of the surfactant lipids by increasing total phospholipid (PL), disaturated phospholipid (DSP), and cholesterol (Chol) in lavage at days 16 and 18. Maturation of surfactant lipid composition was accelerated, with day 16 %DSP/PL, Chol/DSP, and Chol/PL resembling the ratios of day 20 control animals. The effect of Dex + T(3) was similar to that of Dex alone. Hypoxia increased plasma corticosterone levels at day 16, while plasma T(3) levels were not affected. Hence, exposure to hypoxia during critical developmental windows accelerates surfactant maturation, probably by increasing corticosterone production. This internal modulation of the developmental response to an external stimulus is a demonstration of physiological heterokairy.