Ontogenic changes in the circulating concentrations of insulin-like growth factor (IGF)-I, IGF-II, and IGF-binding proteins in the chicken embryo

Developmental changes of plasma insulin, glucagon, insulin-like growth factors, thyroid hormones, and glucose concentrations in chick embryos and hatched chicks

Developmental hormonal changes in Cobb 500 chick embryos and hatched chicks were determined by measuring plasma insulin, glucagon, insulin-like growth factor (IGF)-I, IGF-II, triiodothyronine, thyroxine, and glucose concentrations at different ages of embryogenesis and posthatch development. Plasma samples were obtained daily from 10 d of embryogenesis (10E) through 13 d posthatch and also at 17 and 21 d posthatch. A significant increase in plasma insulin was observed with increasing age from 10E to hatch. Plasma glucagon levels remained low until 17E, and then significantly increased approximately 3-fold at hatch, which corresponded with increasing plasma glucose levels during late embryo development. The plasma insulin to glucagon molar ratio of incubation from 14E to 17E ranged from 2 to 4, and was significantly higher than at any other time during incubation. These results indicate that insulin may be an important promoter of chick embryonic growth by the anabolic drive to promote protein deposition. Insulin and glucagon increased after hatch, which may be due to increased feed consumption and increased utilization of carbohydrates as the key energy source, compared with nutrients obtained through lipolysis and proteolysis in the embryos. Plasma triiodothyronine increased 4-fold from 18E to 20E, and thyroxine increased 3-fold from 16E to 19E. Insulin-like growth factor-I and IGF-II peaked at 14E. Insulin-like growth factor-I steadily increased above embryonic levels during the 3 wk of the posthatch period, whereas IGF-II levels steadily declined. These results suggest that IGF-II may be a more important functionary for chick embryonic development than IGF-I, and that IGF-I may be more important than IGF-II after hatch. The profile of metabolic hormones in the present study may help support an understanding of significant changes that occur in embryonic development and posthatch growth in chicks.

GRP94 is essential for mesoderm induction and muscle development because it regulates insulin-like growth factor secretion

Because only few of its client proteins are known, the physiological roles of the endoplasmic reticulum chaperone glucose-regulated protein 94 (GRP94) are poorly understood. Using targeted disruption of the murine GRP94 gene, we show that it has essential functions in embryonic development. grp94-/- embryos die on day 7 of gestation, fail to develop mesoderm, primitive streak, or proamniotic cavity. grp94-/- ES cells grow in culture and are capable of differentiation into cells representing all three germ layers. However, these cells do not differentiate into cardiac, smooth, or skeletal muscle. Differentiation cultures of mutant ES cells are deficient in secretion of insulin-like growth factor II and their defect can be complemented with exogenous insulin-like growth factors I or II. The data identify insulin-like growth factor II as one developmentally important protein whose production depends on the activity of GRP94.

Potential role for insulin-like growth factor II and vitronectin in the endothelial–mesenchymal transition process

Endothelial-to-mesenchymal transition (EndoMT) is a process through which certain subsets of endothelial cells lose endothelial characteristics and transform into mesenchymal or smooth muscle-like cells. Emerging evidence suggests that this process plays an important role during vascular development and in many vascular pathologies. As in epithelial-mesenchymal transition, EndoMT seems to progress through a series of important steps whose interdependence and order are not clear, and that some of them are regulated by soluble growth factors. Insulin-like growth factor II (IGFII), apart from being considered important in cancer, angiogenesis, and atherosclerotic lesions, is also considered as essential to embryonic development. Here, we report that addition of IGFII promoted the EndoMT process in the presence of very low amounts of chicken serum to arrested primary embryonic aortic chicken endothelial cells attached to fibronectin (FN), gelatin, or native type I collagen. This was demonstrated by cell spreading, loss of cell-cell contacts, detachment, migration, and transformation. These cellular events also occurred when IGFII was added to medium containing vitronectin (VN). Additionally, we demonstrated that these proteins were present in the spontaneous intimal thickenings that are observed at day 11-13 of chicken embryo development. We also show that alterations in the distribution of VE-cadherin and beta-catenin occur after IGFII and serum or VN stimulation, and propose that the via VN IGFII effects may be facilitated by interaction of the mannose-6-phosphate/IGFII receptor (M6P/IGFIIR) with the urokinase-type plasminogen activator receptor (uPAR) and its ligand (uPA). Collectively, these findings provide the first evidence for a potential role of the IGFII-VN complex during the EndoMT process. From our observations and previous studies, we postulate a working hypothesis supporting a fundamental role for these molecules during EndoMT.

Developmental changes in amniotic and allantoic fluid insulin-like growth factor (IGF)-I and -II concentrations of avian embryos

In the literature, IGFs in the developing embryo are usually determined by blood serum concentrations. For this study, IGF-I/-II was quantified in the amniotic and allantoic fluids of fertile commercial broiler chicken (Gallus domesticus) (n=222), Pekin duck (Anas platyrhyncha) (n=250), and turkey (Meleagridis gallopavo) eggs (n= 200) during incubation. Amniotic and allantoic fluids were collected from embryos starting at 6 days of incubation for chickens and 8 days of incubation for ducks and turkeys. IGF concentrations within the fluids were determined by radioimmunoassay. Chicken amniotic IGF-I concentration at stage 29 of development was significantly higher (P< or =0.05) than the duck or turkey. At stage 36 of development the concentration of IGF-II in the amniotic fluid was 2.8 times greater in the chicken versus the duck (P< or =0.05) and 2 times greater than in the turkey (P< or =0.05). Within species, chicken IGF-I concentration in the amniotic fluid had a cubic trend (P< or =0.001), duck IGF-I increased linearly (P< or =0.001), and turkey concentrations declined quadratically (P< or =0.001) throughout development. In all species, the IGF-II concentration was higher than the IGF-I concentration in the amniotic and allantoic fluids.

Insulin-like growth factor-I affects amino compounds in the fluids of the chicken embryo

The concentration differences of more than 40 amino acids and related compounds in the amniotic fluid, allantoic fluid, and plasma of the chicken embryo are maintained by specific barriers. Since the amniotic and allantoic membranes are not innervated, we proposed that these barriers are controlled by hormones. Specific effects of insulin and prolactin on the amino compounds in the three fluids confirmed this hypothesis and raised the question of the possible role of growth factors. Application of insulin-like growth factor-I (IGF-I) to the chorioallantoic membrane of day 13 chicken embryos caused the following concentration changes in 41 amino compounds measured 1 and 2 h later: (1) in the amniotic fluid, an increase of 40 compounds, regardless of the presence or absence of a concomitant stress effect on these compounds; only NH3 was not affected; (2) in the allantoic fluid, a decrease of reduced glutathione (GSH) and anserine, and an increase of NH3; (3) in the plasma, a decrease of 24 compounds. Within the same time frame, stress caused in the amniotic fluid a drop of the concentration of 29, and an increase of 5, amino compounds; IGF-I reversed the stress effect on all 29 compounds the concentrations of which had dropped and enhanced the stress-induced increase of the other 5 compounds. In the allantoic fluid, stress induced an increase of GSH; IGF-I reversed this effect. In the plasma, stress caused an increase of 9 compounds; IGF-I counteracted the increase in 7 cases. These findings indicate new and unexpected roles of IGF-I in the prenatal regulation of amino compounds.

Effect of in ovo administration of insulin-like growth factor-I on composition and mechanical properties of chicken bone

The influence of in ovo administration of insulin-like growth factor-I (IGF-I) on long bone growth (tibiae and femora) of 42-d-old broiler chickens was investigated. Eggs were divided into three groups: uninjected control, vehicle-injected control, and recombinant human (rh) IGF-I. Eggs were injected once with 100 microL vehicle (10 mM acetic acid and 0.1% BSA) per embryo or vehicle containing 100 ng rh IGF-I/100 microL per embryo (n = 555 eggs total) on Days 1, 2, 3, or 4 of embryonic development. Males had greater bone length and moment of inertia than did females for the tibia and the femur (P < or = 0.01 for all). Although fracture load was significantly affected by gender (P < or = 0.02 and P < or = 0.006 for the femur and tibia, respectively), there was no treatment effect on these variables. However, when the fracture load was normalized with body weight of the animal, treatment and gender effects were found for femora (P < or = 0.04). Hydroxyproline concentrations of bones from male broilers were increased by the treatment (P < or = 0.02), whereas it had no effect on female broilers. There was no treatment effect on ash content, stiffness, yield load, yield deflection, and ultimate deflection and elastic, plastic, and total work for the femur or the tibia. We suggest that the effect of in ovo administration of IGF-I on bone mechanical properties was site-specific, and treated femora tended to have a lower fracture load relative to increased body weight.

Hormonal effects on amino acids and related compounds in plasma, amniotic fluid, and allantoic fluid of the chicken embryo

So far, more than 40 free amino acids and related compounds have been identified in plasma, amniotic fluid, and/or allantoic fluid of the 13-day chicken embryo. Concentration differences, and greatly varying behavior of these compounds under experimental conditions, revealed the presence of specific barriers among the three fluids. We tested the hypotheses that (1) the absence of an innervation of amnion and allantois indicates a hormonal control of their barriers, and (2) changes in the concentrations of certain amino compounds in the three fluids indicate anabolic or catabolic actions of hormones. Insulin, prolactin, and stress caused complex changes of the concentrations of amino compounds in all three fluids within 30 min. Some of these changes indicated breakdown of embryonic tissues, while others must have been due to transfer of amino compounds among the three fluid compartments. However, there was no significant effect on the glucose concentration in any of the three compartments under any of the experimental conditions. This is the first demonstration of hormonal effects on the amino compounds in the extraembryonic fluids of nonmammalian amniotes.

Morphogenesis and differentiation of the avian endocrine pancreas, with particular reference to experimental studies on the chick embryo

The avian pancreas has three or four lobes and develops from a dorsal and two ventral buds. The cells that will contribute to formation of the dorsal bud are at first located in the mid-dorsal endoderm, those of the ventral buds in the floor of the foregut. The determination of endoderm to form dorsal and ventral bud derivatives occurs before formation of the buds. The highest concentration of endocrine tissue is in the splenic lobe. The lobes contain A and B islets in which glucagon and insulin cells, respectively, predominate. Islets contain somatostatin and pancreatic polypeptide (PP) cells, both of which also occur scattered in the exocrine parenchyma. Pancreatic endocrine cells arise from endoderm: glucagon, insulin, and somatostatin cells differentiate early, PP cells later. To establish culture conditions suitable for avian insulin cells, the epithelial component of dorsal buds of 5-day chick embryos was cultured under various conditions. At the end of 7 days the proportion of insulin cells was determined. In raising the proportion of insulin cells, Matrigel was superior to collagen gel and a serum-free medium (incorporating insulin, transferrin, and selenium) was superior to a serum-containing medium. Modifications to the serum-free medium were tested. Raising the level of glucose or of glucose and essential amino acids increased the proportion of insulin cells. This proportion was also increased by replacement of insulin by insulin-like growth factor-I, whereas addition of transforming growth factor beta1 reduced the proportion. Transfer of explants from poor to favourable culture conditions showed that the improved conditions stimulated quiescent insulin progenitor cells to develop.