In order to determine the effects of IGF-II overexpression on growth of mice, transgenic mice were produced carrying one of three different H-2Kb human IGF-II minigenes in which different non-coding exons (exon 5, truncated exon 5 or exon 6) preceded the coding exons 7, 8 and 9. These were spaced by truncated introns and for proper polyadenylation an SV40 polyadenylation signal was incorporated. The highest levels of IGF-II minigene mRNA expression were found in lines containing the truncated exon 5 construct (II5'). Those containing exon 6 (II6) had less expression and 5 constructs (II5) gave only moderate levels of mRNA expression. In general mRNA expression was highest in thymus and spleen, low in liver and kidney and absent in the brain. In addition, one II5' line showed expression in the brain. Serum IGF-II levels at 8 weeks of age were increased 7- to 8-fold in homozygous transgenic lines with construct II5' without brain expression and 2- to 3-fold in the one that showed expression in the brain; serum IGF-I levels were unchanged. Serum IGFs in the lines containing the constructs II5 and II6 were not different from those of the controls. In all cases body length and weight as well as the weight of several organs such as brain, liver, kidneys, heart and spleen when expressed as a function of age did not differ from controls. Only the thymus showed a significant increase in weight in the transgenics II5'. Inbreeding of 2 lines containing construct II5' with pituitary deficient Snell dwarf mice did not influence body length or weight despite increased serum IGF-II levels. Again the thymus showed a marked increase in growth. The biological activity of the IGF-II peptide was further demonstrated by increased serum IGF-binding protein-3 in the transgenic dwarf mice, as shown by Western ligand blotting. In summary, overexpression of IGF-II in transgenic normal and dwarf mice does not affect overall body growth, but causes increased growth of the thymus. This suggests a role for IGF-II in thymic development by paracrine/autocrine action.
Previously, transgenic mice were constructed overexpressing human insulin-like growth factor II (IGF-II) under control of the H2kb promoter. The IGF-II transgene was highly expressed in thymus and spleen, and these organs showed an increase in weight. In the current study we have analyzed the sites of IGF-II mRNA expression, the distribution of IGF-II, IGF-I, and both IGF receptors, and histomorphometrical changes in thymus and spleen. With in situ mRNA hybridization, expression of the IGF-II transgene is found with high intensity in the thymic medulla and in the white pulp/marginal zone of the spleen, whereas there were scattered positive cells in the thymic cortex and in the splenic red pulp. Hybridization was restricted to non-lymphocytic cells. Immunohistochemistry revealed intense IGF-II peptide staining with the same distribution as IGF-II mRNA. There was additional intense IGF-II staining of all elements in the splenic red pulp (including trabeculae) and diffuse, low level staining in the thymic cortex. These findings were not observed in control mice. In the thymic medulla, most IGF-II producing cells co-labelled with keratin, whereas a minor population also stained for the monocyte/ macrophage marker MOMA-2. In the spleen, co-labelling of IGF-II producing cells was found with MOMA-1 (marginal zone), or with the dendritic cell marker NLDC-145 (red pulp). IGF-I and both IGF receptors were found in these organs in nearly all cell types, with a similar pattern in transgenic mice and in control animals. Histomorphometric analysis revealed a marked increase of thymus cortex size and an increased trabecular size in the spleen. This suggests that IGF-II overproduction induces local effects (auto/paracrine) in the thymic cortex, but not in the thymic medulla. Trabecular growth in the spleen most likely is a distant effect (paracrine or endocrine) of IGF-II overproduction.
The actions and interactions of recombinant insulin-like growth factor-I and -II (IGF-I and IGF-II), alone or in combination with human GH on body growth and the growth of several organs were studied in the Snell dwarf mouse. IGF-I and -II stimulate to a similar extent sulfate incorporation into cartilage, and both IGFs increase body length and weight. IGF-II as well as IGF-I have clear effects on the size of the submandibular salivary glands, kidneys, and spleen. IGF-II, however, did not influence the weight of the lung, in contrast with IGF-I. GH treatment alone resulted in growth of the liver, whereas both IGFs were inactive. Surprisingly, IGF-II and, to a lesser extent, IGF-I inhibited GH-induced growth of the liver. Glycogen storage in the liver was decreased by treatment with IGF-II alone or in combination with GH, as shown by histological examination. It was not affected by GH, IGF-I, or GH plus IGF-I. Also, the size of the centrilobular hepatocytes was decreased by treatment with IGF-II and IGF-II plus GH; GH alone had a hypertrophic effect, whereas IGF-I or GH plus IGF-I had none. In contrast to GH, IGFs did not increase polyploidy. Treatment with IGF-II increased the level of IGFBP-3, as did IGF-I or GH treatment, as shown by Western ligand blotting. The IGFs appeared to have a greater effect on the induction of 38.5-kilodalton IGFBP-3 than GH, suggesting a different role in the regulation of glycosylation. In conclusion, IGF-I and IGF-II as well as GH have a stimulatory effect on general body growth and are effective in the stimulation of serum IGFBP-3, sulfate incorporation into cartilage, as well as the growth of specific organs in Snell dwarf mice. Both IGFs, alone or in combination with GH, show distinct effects on the growth of the liver with respect to several histological parameters, which require further exploration.
The ontogeny of serum insulin-like growth factors (IGFs)-I and -II and their binding proteins (IGFBPs) was studied in normal and dwarf Snell mice. IGF-I concentrations in serum of normal mice increased between 4 and 8 weeks of age; dwarf mice had very low serum IGF-I levels. In both normals and dwarfs, serum IGF-II levels were highest soon after birth and dropped steadily thereafter. Western ligand blots of serum IGFBPs with 125I-IGF-II as tracer revealed the expected bands of 41.5, 38.5, 30-32 and 24 kDa. In normal mice the IGFBP-3 doublet was already detectable at 2 weeks of age, and its intensity increased with age. In dwarf mice the IGFBP-3 doublet was hardly detectable. The changes of IGFs and their IGFBPs were studied in sera of dwarf mice after treatment with growth hormone (GH) and/or thyroxine (T4) for 4 weeks. In spite of a comparable growth response obtained using these hormones, serum IGF-I was increased only by GH treatment; a small but significant decrease of serum IGF-II was obtained following GH or T4 treatment. An increase of the IGFBP-3 doublet was only obtained with GH; T4 and GH + T4 had no effect. The rise of IGFBP-3 after GH treatment was accompanied by the formation of the IGFBP 150 kDa complex, as measured by neutral gel chromatography. The size distribution of 125I-IGF-II was restored to normal, while with 125I-IGF-I only a small peak at 150 kDa was observed.(ABSTRACT TRUNCATED AT 250 WORDS)
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