Search Results

Intestinal development is modified by age and nutrition, mediated in part by insulin-like growth factors (IGF-I, IGF-II) and insulin. We have investigated whether expression of IGF-I, IGF-II and insulin receptors (IGF-IR, IGF-IIR and IR; measured by real-time RT-PCR) and binding capacity (Bmax) of IGF-IR, IGF-IIR and IR in the mucosa of the small and large intestine of neonatal calves are modified by age and different feeding regimes. In experiment 1, pre-term (GrP) and full-term (GrN) calves (after 277 and 290 days of pregnancy respectively) were killed immediately after birth before being fed; a further group of full-term calves were fed for 7 days and killed on day 8 of life (GrC(1-3)). In experiment 2, full-term calves were killed on day 8 after being fed first-colostrum for 7 days (GrCmax), colostrum of the first six milkings for 3 days (GrC(1-3)) or milk-based formula for 3 days (GrF(1-3)). Intestinal sites differed with respect to expression levels of IGF-IR (duodenum>jejunum in GrC(1-3); ileum>colon, duodenum> or = jejunum in GrF(1-3)), IGF-IIR (colon>duodenum and ileum in GrN), and IR (lowest in ileum in GrP and CrN; highest in colon in GrC(1-3) and GrCmax). They also differed with respect to Bmax of IGF-IR (ileum and colon>duodenum and jejunum in GrP; ileum and colon>jejunum in GrN; colon>jejunum in GrC(1-3); lowest in jejunum in GrF(1-3)), IGF-IIR (duodenum and colon>jejunum and ileum in GrP; duodenum>ilem and colon>jejunum in GrN; duodenum, jejunum and colon>ileum in GrCmax, GrC(1-3), and GrF(1-3)) and IR (ileum>duodenum, jejunum and colon in GrCmax, GrC(1-3), and GrF(1-3)). There were significant differences between groups in the expression of IGF-IR (GrF(1-3)> GrCmax and GrC(1-3) in ileum), IGF-IIR (GrN>GrP and GrC(1-3) in colon; GrN>GrC(1-3) in jejunum and total intestine), and IR (GrCmax>GrF(1-3) in colon) and in the Bmax of IGF-IR (GrP>GrN in colon; GrCmax>GrF(1-3) in jejunum), IGF-IIR (GrN>GrP in duodenum, ileum and total intestine; GrN>GrC(1-3) in duodenum, ileum, colon and total intestine) and IR (GrN>GrP in total intestine; GrC(1-3)>GrN in ileum and total intestine). In addition, Bmax values of IGF-IR, IGF-IIR and IR were correlated with villus circumference, villus height/crypt depth and proliferation rate of crypt cells at various intestinal sites. There were marked differences in Bmax of IGF-IR, IGF-IIR and IR dependent on mRNA levels, indicating that differences in Bmax were the consequence of differences in posttranslational control and of receptor turnover rates. In conclusion IGF-IR, IGF-IIR and IR expressions and Bmax in intestinal mucosa were different at different intestinal sites and were variably affected by age, but not significantly affected by differences in nutrition. Receptor densities were selectively associated with intestinal mucosa growth.

Glucocorticoids inhibit postnatal growth and yet can stimulate the somatotropic axis around birth. The aim of the present study was to investigate the effects of dexamethasone on the somatotropic axis and on the responses of the insulin-like growth factor (IGF) system to growth hormone treatment in calves. Calves (n=24) were randomly divided into four groups. Group DX was injected with dexamethasone (30 micro g/kg body weight per day), group GH was injected with 500 mg slow-release bovine growth hormone at 14-day intervals, group GHDX was injected with dexamethasone and bovine growth hormone, and group CNTRL (serving as control) was injected with saline from day 3 to day 42 of life. Blood samples were taken on day 3 and blood and liver samples were obtained on days 7, 14, 28 and 42. Body weight increased in the CNTRL and GH groups up to the end of the study and in the DX and GHDX groups up to the fourth week. Dexamethasone treatment decreased (P<0.05) plasma IGF binding protein (IGFBP)-1 on days 7 and 14, but increased (P<0.05) plasma IGFBP-1, decreased (P<0.05) plasma IGF-I and IGFBP-3, and decreased hepatic mRNA for growth hormone receptor (GHR) and IGF-I on day 42. Growth hormone treatment increased (P<0.05) plasma growth hormone concentrations on days 7 and 14, tended to increase (P<0.1) plasma IGF-I concentrations on day 42, and increased (P<0.05) hepatic mRNA levels of GHR on day 14 and IGF-I mRNA levels on days 7 and 14. The combined dexamethasone and growth hormone treatment increased plasma growth hormone concentrations on day 7 and resulted in the highest plasma concentrations of IGF-I and IGFBP-3 (day 7 to day 28) as well as the greatest abundance of hepatic GHR (day 14) and IGF-I (days 7 and 14) mRNA. Plasma IGFBP-1 concentrations in the GHDX group behaved in a similar manner as in the DX group. In conclusion, the response of the somatotropic axis to growth hormone treatment could be greatly enhanced by dexamethasone treatment during the neonatal and early postnatal period, but body weight gain was not improved. Dexamethasone alone inhibited the somatotropic axis and postnatal growth after the first Month of life.