Insulin-like growth factor binding protein (IGFBP-1) involvement in intrauterine growth retardation: study on IGFBP-1 overexpressing transgenic mice.

In humans, intrauterine growth retardation is correlated to high levels of serum IGF binding protein-1 (IGFBP-1). This present study analyzes in vivo the impact of circulating IGFBP-1 on body growth associated to bone mineralization and carbohydrate resources. Transgenic mice used in this work overexpressed human IGFBP-1 in liver from embryonic day (E)14.5, concomitantly to the appearance of ossification centers, through to adulthood. Growth retardation was observed as early as E17.5 in homozygous (HM) mice being 20% smaller at birth (postnatal d 1). Anatomical analysis of the skeletons by alizarin red and alcian blue staining showed that the mice exhibited pleiotropic defects of several skeletal units. Some bones were small and dysmorphic. Our results showed reduced mineralization in the posterior area of the skull (delayed suture closure), as well as in the appendicular and axial skeleton. Heterozygous crossings showed a loss of HM animals. Moreover, IGFBP-1 overexpression contributed to decreased fetal hepatic glycogen and neonate blood glucose levels which constitute the main reservoir of carbohydrate resources for neonates. Thus, this reduced carbohydrate pool contributed to perinatal mortality. Maternal IGFBP-1 expression was also clearly associated with neonate growth retardation (newborn weights from HM mothers were 20% smaller than newborns from NT mothers) and reduced fetal carbohydrate resources. In conclusion, antenatal growth retardation and delayed mineralization in transgenic mice are related to overexpressed fetal and maternal circulating human IGFBP-1. Similar perturbations could be observed in human intrauterine growth retardation suggesting the IGF/IGFBP system is involved in fetal growth, biomineralization, and energetic status in humans.

Reproductive abnormalities in human insulin-like growth factor-binding protein-1 transgenic male mice.

Adult transgenic mice overexpressing human insulin-like growth factor-binding protein-1 in the liver present reproductive abnormalities in both sexes. In the present work, we have investigated the mechanisms responsible for limiting breeding capacity in these transgenic male mice. Homozygous adult transgenic male mice (3-6 months old) exhibited irregular copulatory behavior and a reduction of the number of pregnancies per female as well as of litter size per pregnancy. Genital tract weight, more specifically epididymal and seminal vesicle weights, were reduced by 45% in homozygous transgenic vs. nontransgenic mice. Homozygous transgenic mice exhibited a 30% reduction of the length of seminiferous tubules (P = 0.007), a 30% decrease in daily sperm production per testis (P = 0.019), and a 50% decrease in the number of spermatozoa in testis (P = 0.037), associated with morphological abnormalities of the sperm heads leading to an approximately 50% reduction of fertilized two-cell eggs (P = 0.002) and of implanted embryos on d 5.5 after mating (P = 0.004). The round spermatids also appeared altered in their morphology. In addition, Leydig cells in homozygous transgenic mice exhibited an altered appearance, with a 1.8-fold increase in lipid droplets in their cytoplasm (P < 0.001). Moreover, the concentration of 3beta-hydroxysteroid dehydrogenase was 66% lower in testis from transgenics compared with those from normal mice (P = 0.01), leading to a tendency toward lower plasma testosterone levels (P = 0.1). Interestingly, LH concentrations were increased by 40% in transgenic pituitary extracts (P = 0.02), and basal LH secretion by pituitary explants in vitro was increased by 60% in homozygous transgenic vs. normal mice (P = 0.04), suggesting an alteration of LH pulsatile secretion in vivo. In conclusion, these data suggest that the breeding impairment of human insulin-like growth factor-binding protein-1 transgenic males is due at least in part to an alteration of the process of spermatogenesis, leading to a diminution of sperm production and of its quality. Minor impairment of steroidogenesis may also contribute to the reduced reproductive capacity of these animals. Our observations are consistent with the idea that normal spermatogenesis and perhaps also steroidogenesis are dependent on the actions of sufficient concentrations of unbound IGF-I.

Insulin-like growth factor binding protein-6 transgenic mice: postnatal growth, brain development, and reproduction abnormalities.

In biological fluids, IGFs bind to six distinct binding proteins (IGFBP-1 to -6). IGFBP-6 is of particular interest because it has been shown to inhibit proliferation in many cell types and to be synthesized in the central nervous system (CNS). It also has the strongest affinity for IGF-II among the IGFBPs. To study IGFBP-6 function in vivo, we established IGFBP-6 transgenic mice in which human IGFBP-6 (hIGFBP-6) cDNA is expressed under the control of the glial fibrillary acidic protein (GFAP) promoter. Northern and Western blot analysis revealed strong transgene expression in the CNS. With histological examination of the CNS, cerebellum size and weight proved to be reduced by about 25% and 35%, respectively, and there were smaller numbers of differentiated, GFAP-expressing astrocytes than in wild-type mice. Between birth and 1 month of age, transgenic mice had high levels of circulating hIGFBP-6 and reduced plasma IGF-I, and, as a result, body weight was significantly reduced. Reproductive physiology was also affected. Litter size was reduced by 27% when wild-type males were mated with 3-month-old transgenic females and by 66% when mated with 6-month-old transgenic females. Histological examination of ovaries of transgenic mice revealed a marked decrease in weight and in the number of corpora lutea, suggesting altered ovulation, and circulating LH levels were reduced by 50%. Our results indicate that this new model of transgenic mouse may prove to be a useful tool in elucidating the in vivo role of IGFBP-6 in the brain, especially in regard to hypothalamic control, and in reproductive physiology.

Reproductive abnormalities in human IGF binding protein-1 transgenic female mice.

The mechanisms responsible for reproductive abnormalities in transgenic female mice overexpressing human IGF binding protein-1 (IGFBP-1) in the liver have been investigated. At 2 months of age, none of these transgenic mice exhibited ovarian cyclicity. Genital tract and ovary tissue weights were reduced in transgenic mice, this weight reduction being disproportionate with the reduction of body weight. Examination of ovarian follicular population revealed a marked decrease in the number of corpora lutea and gonadotropin-dependent follicles, suggesting an alteration of terminal follicular growth and ovulation. Stimulation of ovaries by exogenous gonadotropins revealed that ovaries from transgenic mice ovulated less oocytes than nontransgenic mice. This lower responsiveness of ovaries from transgenic mice to gonadotropins was not associated with a decrease in FSH-, LH- or IGF-I receptor expression. Transgenic and nontransgenic mice have similar circulating LH and FSH concentrations at dioestrus, after castration, 46 h after equine CG administration, or 15 min after GnRH injection. However, LH concentrations were 8-fold higher in pituitaries from transgenic vs. nontransgenic mice. Moreover, the size of LH-immunoreactive cells was reduced and their number was increased, suggesting a subtle alteration of LH secretion. Overall, these data indicate that reduced fertility in transgenic female mice overexpressing human IGFBP-1 are mainly due to an alteration of terminal follicular growth leading to a decrease in natural and induced ovulation rate, likely due to an impairment of IGF-I action on follicular cells. Increased circulating IGFBP-1 concentrations may additionally lead to altered GnRH and LH pulsatility and thereby exacerbate the ovulation defect.

Insulin-like growth factor binding proteins increase intracellular calcium levels in two different cell lines.

BACKGROUND: Insulin-like growth factor binding proteins (IGFBPs) are six related secreted proteins that share IGF-dependent and -independent functions. If the former functions begin to be well described, the latter are somewhat more difficult to investigate and to characterize. At the cellular level, IGFBPs were shown to modulate numerous processes including cell growth, differentiation and apoptosis. However, the molecular mechanisms implicated remain largely unknown. We previously demonstrated that IGFBP-3, but not IGFBP-1 or IGFBP-5, increase intracellular calcium concentration in MCF-7 cells (Ricort J-M et al. (2002) FEBS lett 527: 293-297). METHODOLOGY/PRINCIPAL FINDINGS: We perform a global analysis in which we studied, by two different approaches, the binding of each IGFBP isoform (i.e., IGFBP-1 to -6) to the surface of two different cellular models, MCF-7 breast adenocarcinoma cells and C2 myoblast proliferative cells, as well as the IGFBP-induced increase of intracellular calcium concentration. Using both confocal fluorescence microscopy and flow cytometry analysis, we showed that all IGFBPs bind to MCF-7 cell surface. By contrast, only four IGFBPs can bind to C2 cell surface since neither IGFBP-2 nor IGFBP-4 were detected. Among the six IGFBPs tested, only IGFBP-1 did not increased intracellular calcium concentration whatever the cellular model studied. By contrast, IGFBP-2, -3, -4 and -6, in MCF-7 cells, and IGFBP-3, -5 and -6, in C2 proliferative cells, induce a rapid and transient increase in intracellular free calcium concentration. Moreover, IGFBP-2 and -3 (in MCF-7 cells) and IGFBP-5 (in C2 cells) increase intracellular free calcium concentration by a pertussis toxin sensitive signaling pathway. CONCLUSIONS: Our results demonstrate that IGFBPs are able to bind to cell surface and increase intracellular calcium concentration. By characterizing the IGFBPs-induced cell responses and intracellular couplings, we highlight the cellular specificity and complexity of the IGF-independent actions of these IGF binding proteins.

Partial primary deficiency of insulin-like growth factor (IGF)-I activity associated with IGF1 mutation demonstrates its critical role in growth and brain development.

CONTEXT: IGF-I is essential for fetal and postnatal development. Only three IGF1 defects leading to dramatic loss of binding to its type 1 receptor, IGF-1R, have been reported. PATIENT: We describe a very lean boy who has intrauterine growth restriction and progressive postnatal growth failure associated with normal hearing, microcephaly, and mild intellectual impairment. He had markedly reduced concentrations of IGF-I, with IGFBP-3 and ALS serum levels in the upper normal range or above. IGF-I serum concentrations differed according to the immunoassay used. A higher than average GH dose was required for catch-up growth. Given the mismatch between IGF-I and IGFBP-3 levels, we sequenced his IGF1 gene. RESULT: We identified a homozygous missense IGF1 mutation. This causes the replacement of a highly conserved amino acid (arginine 36) by a glutamine (R36Q) in the C domain of the predicted peptide. We showed that the abnormal IGF-I peptide has reduced mitogenic activity and partial loss of binding to its receptor IGF-1R. The patient's IGF-I level was undetectable in a highly specific monoclonal assay but elevated in a polyclonal assay. CONCLUSION: This first report of mild deficiency of IGF-I activity demonstrates that the integrity of IGF-I signaling is important for normal growth and brain development. Molecular defects leading to partial loss of IGF-I activity may not be uncommon in patients born small for gestational age. The characterization of this complex phenotype and identification of such molecular defects have therapeutic implications, particularly now that, in addition to GH, recombinant IGF-I is available for clinical use.

Functional alteration of the somatotrophic axis in transgenic mice with liver-specific expression of human insulin-like growth factor binding protein-1.

In earlier work, postnatal growth restriction (more marked in males) was observed in a model of transgenic mice with liver-specific expression of human IGF binding protein-1. This was associated with diminished plasma IGF-I levels, the cause of which remained unexplained. Subsequently, abnormalities of CNS development were ascertained, justifying investigation of the somatotrophic axis. Pituitary gland weight in transgenic animals was reduced proportionally to body weight. Immunohistochemical examination of the pituitaries in 3- to 4-mo-old mice revealed somatotrophs of normal size in homozygotes, but density was decreased to approximately two thirds of that in wild-type siblings (p = 0.001). The same was true of lactotrophs. The GH content of the pituitary was significantly reduced in heterozygotes (p < 0.02) and more so in homozygotes (p < 0.0003), although the GH/total protein ratio was similar to that in wild types. Pituitary perifusion experiments showed that in vitro the amounts of GH secreted under basal conditions and under GH-releasing hormone stimulation were similar in transgenic and wild-type mice. Ten days of treatment with human GH (100 microg/d) in 45-d-old transgenic and wild-type mice provoked significant weight gain (p = 0.02) in all animals, the means being 12.4% for homozygotes and 10.4% in heterozygotes, as opposed to 5.8% in wild-type mice. The increase in weight tended to correlate with an increase in plasma IGF-I. From these results, we conclude that the reduced plasma IGF-I in IGF binding protein-1 transgenic mice may result from insufficient GH production by the depressed number of somatotrophs, possibly associated with functional alteration of hypothalamic control.