A. Joseph D'Ercole

Evidence that somatomedin is synthesized by multiple tissues in the fetus.

Abstract Production of somatomedin-C, a growth hormone-dependent peptide believed to mediate the growth-promoting actions of growth hormone, has been assessed using explants of fetal mouse tissues. Quantitation of this peptide in media of explants cultured for 3 days has been accomplished with a membrane receptor assay for somatomedin and a specific radioimmunoassay for somatomedin-C. Somatomedin-C is produced by the 11-day-gestation fetal mouse liver, increases exponentially in parallel with liver growth until the 16th day of gestation, and falls postnatally. Media somatomedin is believed to be derived by de novo synthesis since saline extracts of liver and most other fetal tissues contain only a small fraction of the activity in culture media. The immunoreactive material secreted into media appears to be closely related to human somatomedin-C since it produces dilution curves which are parallel to those of pure hormone, migrates on Sephacryl 200 at a size similar to that of one of the components of human serum somatomedin-C, dissociates into small molecular weight material with acid treatment, and isofocuses in a range comparable with that of somatomedin-C purified from human serum. Eleven-day limb bud mesenchymal micromass cultures and 17-day-gestation intestine, heart, brain, kidney, and lung also synthesize immunoreactive somatomedin-C in serum-free medium. For these tissues, the media activity was far in excess of the tissue extractable activity. Somatomedin activity in excess of the tissue extractable activity, however, was not found in media from 17-day-gestation placenta. The finding that multiple tissues synthesize somatomedin-C raises the possibility that the primary biological actions of this hormone are exerted locally at its sites of origin. Although a function of this type by a peptide has not been widely suspected, it seems plausible that the cells of fetal tissues are capable of producing local mitogens in much the same manner as the postulated inducers of tissue differentiation.

The Cerebrospinal Fluid Provides a Proliferative Niche for Neural Progenitor Cells

Cortical development depends on the active integration of cell-autonomous and extrinsic cues, but the coordination of these processes is poorly understood. Here, we show that the apical complex protein Pals1 and Pten have opposing roles in localizing the Igf1R to the apical, ventricular domain of cerebral cortical progenitor cells. We found that the cerebrospinal fluid (CSF), which contacts this apical domain, has an age-dependent effect on proliferation, much of which is attributable to Igf2, but that CSF contains other signaling activities as well. CSF samples from patients with glioblastoma multiforme show elevated Igf2 and stimulate stem cell proliferation in an Igf2-dependent manner. Together, our findings demonstrate that the apical complex couples intrinsic and extrinsic signaling, enabling progenitors to sense and respond appropriately to diffusible CSF-borne signals distributed widely throughout the brain. The temporal control of CSF composition may have critical relevance to normal development and neuropathological conditions.

In vivo actions of insulin-like growth factor-I (IGF-I) on cerebellum development in transgenic mice: evidence that IGF-I increases proliferation of granule cell progenitors

The in vivo actions of insulin-like growth factor-I (IGF-I) on cerebellum development have been investigated in transgenic (Tg) mice (IGF-II/I Tg mice) in whom an IGF-II promoter-driven IGF-I transgene is highly expressed in cerebellum. Compared to normal littermates, the brains of IGF-II/I Tg mice exhibited overgrowth beginning from the second week of postnatal life. Among the brain regions examined, cerebellum exhibited the greatest increase in size, such that by 50 days of age cerebellar weight and DNA content were increased by 90% and 143%, respectively, compared to littermate controls. Morphological studies of adult IGF-II/I Tg mice showed that the total number of granule and Purkinje cells was increased by 82% and 20%, respectively, findings consistent with the increased cerebellar DNA content and indicating that the increased cerebellar weight was due in part to an increase in cell number. The thickness of the molecular layer also was increased in IGF-II/I Tg mice. During early postnatal development the number of external granular layer cells, as well as the number of BrdU labeled external granular cells, was increased. These data strongly indicate that IGF-I increases granule cell number by a mechanism that involves the stimulation of granule cell progenitor proliferation. Our findings also indicate that IGF-I influences the growth of Purkinje cells and possibly of other cell types in the cerebellum.

Identification of somatomedin/insulin-like growth factor immunoreactive cells in the human fetus.

ABSTRACT: Somatomedins/insulin-like growth factors (Sm/IGFs) are present in blood and in extracts from multiple tissues of the human fetus and induce the proliferation of cultured human fetal cells. To identify the cellular location of immunoreactive Sm/IGF in human fetal tissues, we have performed immunocytochemistry in tissues from prostaglandin-induced human fetal abortuses of 12 to 20 wk in gestation. Every tissue studied except the cerebral cortex contains Sm/IGF immunoreactive cells. Cells staining positively include hepatocytes, hepatic hemopoietic cells, columnar epithelia of the pulmonary airways, intestine and kidney tubules, adrenal cortical cells, dermal cells, skeletal and cardiac muscle fibers, and pancreatic islet and acinar cells. Immunostaining was specific for Sm/IGFs, but because of the cross-reactivity of the antibodies it was not possible to determine whether the immunoreactivity represented Sm-C/IGF I, IGF II, or both. Liver contained the greatest proportion of immunoreactive cells, while the thymus and spleen had only a few immunostained cells. With the possible exception of dermal and some adrenal cortical cells, the immunoreactive cells do not appear to be the primary sites of Sm/IGF synthesis, because parallel in situ hybridization histochemical studies using Sm/IGF oligodeoxyribonucleotide probes show that Sm/IGF mRNAs are localized predominantly to fibroblasts and mesenchymal cells. Therefore the immunoreactive cells identified in this study may define sites of action of Sm/IGFs.

Expanding the Mind: Insulin-Like Growth Factor I and Brain Development

Signaling through the type 1 IGF receptor (IGF1R) after interaction with IGF-I is crucial to the normal brain development. Manipulations of the mouse genome leading to changes in the expression of IGF-I or IGF1R significantly alters brain growth, such that IGF-I overexpression leads to brain overgrowth, whereas null mutations in either IGF-I or the IGF1R result in brain growth retardation. IGF-I signaling stimulates the proliferation, survival, and differentiation of each of the major neural lineages, neurons, oligodendrocytes, and astrocytes, as well as possibly influencing neural stem cells. During embryonic life, IGF-I stimulates neuron progenitor proliferation, whereas later it promotes neuron survival, neuritic outgrowth, and synaptogenesis. IGF-I also stimulates oligodendrocyte progenitor proliferation although inhibiting apoptosis in oligodendrocyte lineage cells and stimulating myelin production. These pleiotropic IGF-I activities indicate that other factors provide instructive signals for specific cellular events and that IGF-I acts to facilitate them. Studies of the few humans with IGF-I and/or IGF1R gene mutations indicate that IGF-I serves a similar role in man.

Overexpression of Parathyroid Hormone-related Protein in the Pancreatic Islets of Transgenic Mice Causes Islet Hyperplasia, Hyperinsulinemia, and Hypoglycemia

Parathyroid hormone-related protein (PTHrP) is produced by the pancreatic islet. It also has receptors on islet cells, suggesting that it may serve a paracrine or autocrine role within the islet. We have developed transgenic mice, which overexpress PTHrP in the islet through the use of the rat insulin II promoter (RIP). Glucose homeostasis in these mice is markedly abnormal; RIP-PTHrP mice are hypoglycemic in the post-prandial and fasting states and display inappropriate hyperinsulinemia. At the end of a 24-hour fast, blood glucose values are 49 mg/dl in RIP-PTHrP mice, as compared to 77 mg/dl in normal littermates; insulin concentrations at this time are 6.3 and 3.9 ng/ml, respectively. Islet perifusion studies failed to demonstrate abnormalities in insulin secretion. In contrast, quantitative islet histomorphometry demonstrates that the total islet number and total islet mass are 2-fold higher in RIP-PTHrP mice than in their normal littermates. PTHrP very likely plays a normal physiologic role within the pancreatic islet. This role is most likely paracrine or autocrine. PTHrP appears to regulate insulin secretion either directly or indirectly, through developmental or growth effects on islet mass. PTHrP may have a role as an agent that enhances islet mass and/or enhances insulin secretion.

In vivo effects of insulin‐like growth factor‐I (IGF‐I) on prenatal and early postnatal development of the central nervous system

The in vivo actions of insulin‐like growth factor‐I (IGF‐I) on prenatal and early postnatal brain development were investigated in transgenic (Tg) mice that overexpress IGF‐I prenatally under the control of regulatory sequences from the nestin gene. Tg mice demonstrated increases in brain weight of 6% by embryonic day (E) 18 and 27% by postnatal day (P) 12. In Tg embryos at E16, the volume of the cortical plate was significantly increased by 52% and total cell number was increased by 54%. S‐phase labeling with 5‐bromo‐2′‐deoxyuridine revealed a 13–15% increase in the proportion of labeled neuroepithelial cells in Tg embryos at E14. In Tg mice at P12, significant increases in regional tissue volumes were detected in the cerebral cortex (29%), subcortical white matter (52%), caudate‐putamen (37%), hippocampus (49%), dentate gyrus (71%) and habenular complex (48%). Tg mice exhibited significant increases in the total number of neurons in the cerebral cortex (27%), caudate‐putamen (27%), dentate gyrus (69%), medial habenular nucleus (61%) and lateral habenular nucleus (36%). In the cerebral cortex and subcortical white matter of Tg mice, the total numbers of glial cells were significantly increased by 37% and 42%, respectively. The numerical density of apoptotic cells in the cerebral cortex, labeled by antibodies against active caspase‐3, was reduced by 26% in Tg mice at P7. Our results demonstrate that IGF‐I can both promote proliferation of neural cells in the embryonic central nervous system in vivo and inhibit their apoptosis during postnatal life.

3 Paracrine functions of somatomedins

Summary Evidence is growing that the somatomedins act by a paracrine and/or autocrine mechanism. The importance of these mechanisms relative to the traditional endocrine actions is not clear, and it is possible that these growth factors act through all three mechanisms. Supporting the possible paracrine/autocrine mechanisms are reports that production of somatomedins or somatomedin-like peptides is widespread throughout the body. Additionally, the somatomedins have biological actions on remarkably diverse cell types, and these responsive cells are found in close proximity to cells known to produce somatomedin. Finally, factors that alter the growth rate of cultured cells produce parallel changes in somatomedin secretion, suggesting that these phenomena are closely linked.

Insulin-like growth factor type 1 receptor signaling in the cells of oligodendrocyte lineage is required for normal in vivo oligodendrocyte development and myelination

Insulin‐like growth factor‐I (IGF‐I) has been shown to be a potent agent in promoting the growth and differentiation of oligodendrocyte precursors, and in stimulating myelination during development and following injury. To definitively determine whether IGF‐I acts directly on the cells of oligodendrocyte lineage, we generated lines of mice in which the type 1 IGF receptor gene (igf1r) was conditionally ablated either in Olig1 or proteolipid protein expressing cells (termed IGF1Rpre‐oligo‐ko and IGF1Roligo‐ko mice, respectively). Compared with wild type mice, IGF1Rpre‐oligo‐ko mice had a decreased volume (by 35–55%) and cell number (by 54–70%) in the corpus callosum (CC) and anterior commissure at 2 and 6 weeks of age, respectively. IGF1Roligo‐ko mice by 25 weeks of age also showed reductions, albeit less marked, in CC volume and cell number. Unlike astrocytes, the percentage of NG2+ oligodendrocyte precursors was decreased by ∼13% in 2‐week‐old IGF1Rpre‐oligo‐ko mice, while the percentage of CC1+ mature oligodendrocytes was decreased by ∼24% in 6‐week‐old IGF1Rpre‐oligo‐ko mice and ∼25% in 25‐week‐old IGF1Roligo‐ko mice. The reduction in these cells is apparently a result of decreased proliferation and increased apoptosis. These results indicate that IGF‐I directly affects oligodendrocytes and myelination in vivo via IGF1R, and that IGF1R signaling in the cells of oligodendrocyte lineage is required for normal oligodendrocyte development and myelination. These data also provide a fundamental basis for developing strategies with the potential to target IGF‐IGF1R signaling pathways in oligodendrocyte lineage cells for the treatment of demyelinating disorders.

Insulin-Like Growth Factor-I Accelerates the Cell Cycle by Decreasing G1 Phase Length and Increases Cell Cycle Reentry in the Embryonic Cerebral Cortex

Neurogenesis in the developing cerebral cortex of mice occurs in the dorsal telencephalon between embryonic day 11 (E11) and E17, during which time the majority of cortical projection neurons and some glia are produced from proliferating neuroepithelial cells in the ventricular zone. The number of cells produced by this process is governed by several factors, including cell cycle kinetics and the proportion of daughter cells exiting the cell cycle after a given round of cell division. The in vivo effects of IGF-I on cell cycle kinetics were investigated in nestin/IGF-I transgenic (Tg) embryos, in which IGF-I is overexpressed in the cerebral cortex and dorsal telencephalon. These Tg mice have been shown to exhibit increased cell number in the cortical plate by E16 and increased numbers of neurons and glia in the cerebral cortex during postnatal development. Cumulative S phase labeling with 5-bromo-2′-deoxyuridine revealed a decrease in total cell cycle length (TC) in Tg embryos on E14. This decrease in TC was found to result entirely from a reduction in the length of the G1 phase of the cell cycle from 10.66 to 8.81 hr, with no significant changes in the lengths of the S, G2, and M phases. Additionally, the proportion of daughter cells reentering the cell cycle was significantly increased by 15% in Tg embryos on E14-E15 compared with littermate controls. These data demonstrate that IGF-I regulates progenitor cell division in the ventricular zone by reducing G1 phase length and decreasing TC but increases cell cycle reentry.