Mex3c Mutation Reduces Adiposity and Increases Energy Expenditure

The function of MEX3C, the mammalian homolog of Caenorhabditis elegans RNA-binding protein muscle excess 3 (MEX-3), was unknown until our recent report that MEX3C is necessary for normal postnatal growth and enhances the expression of local bone Igf1 expression. Here we report the pivotal role of Mex3c in energy balance regulation. Mex3c mutation caused leanness in both heterozygous and homozygous transgenic mice, as well as a more beneficial blood glucose and lipid profile in homozygous transgenic mice, in both sexes. Although transgenic mice showed normal food intake and fecal lipid excretion, they had increased energy expenditure independent of physical activity. Mutant mice had normal body temperature, Ucp1 expression in brown adipose tissue, and muscle and liver fatty acid oxidation. Mex3c is expressed in neurons and is detectable in the arcuate nucleus, the ventromedial nucleus, and the dorsomedial nucleus of the hypothalamus. Mex3c was not detected in NPY or POMC neurons but was detected in leptin-responsive neurons in the ventromedial nucleus. Mex3c and Leptin double mutant mice were growth retarded and obese and had blood profiles similar to those of ob/ob mice but showed none of the steatosis observed in ob/ob mice. Our data show that Mex3c is involved in energy balance regulation.     

Roles of growth hormone and insulin-like growth factor 1 in mouse postnatal growth

To examine the relationship between growth hormone (GH) and insulin-like growth factor 1 (IGF1) in controlling postnatal growth, we performed a comparative analysis of dwarfing phenotypes manifested in mouse mutants lacking GH receptor, IGF1, or both. This genetic study has provided conclusive evidence demonstrating that GH and IGF1 promote postnatal growth by both independent and common functions, as the growth retardation of double Ghr/Igf1 nullizygotes is more severe than that observed with either class of single mutant. In fact, the body weight of these double-mutant mice is only approximately 17% of normal and, in absolute magnitude ( approximately 5 g), only twice that of the smallest known mammal. Thus, the growth control pathway in which the components of the GH/IGF1 signaling systems participate constitutes the major determinant of body size. To complement this conclusion mainly based on extensive growth curve analyses, we also present details concerning the involvement of the GH/IGF1 axis in linear growth derived by a developmental study of long bone ossification in the mutants.     

Igf1 promotes longitudinal bone growth by insulin-like actions augmenting chondrocyte hypertrophy.

Longitudinal bone growth, and hence stature, are functions of growth plate chondrocyte proliferation and hypertrophy. Insulin-like growth factor 1 (Igf1) is reputed to augment longitudinal bone growth by stimulating growth plate chondrocyte proliferation. In this study, however, we demonstrate that chondrocyte numbers and proliferation are normal in Igf1 null mice despite a 35% reduction in the rate of long bone growth. Igf1 null hypertrophic chondrocytes differentiate normally in terms of expressing specialized proteins such as collagen X and alkaline phosphatase, but are smaller than wild-type at all levels of the hypertrophic zone. The terminal hypertrophic chondrocytes, which form the scaffold on which long bone growth extends, are reduced in linear dimension by 30% in Igf1 null mice, accounting for most of their decreased longitudinal growth. The expression of the insulin-sensitive glucose transporter, GLUT4, is significantly decreased and the insulin-regulated enzyme glycogen synthase kinase 3beta (GSK3) is hypo-phosphorylated in Igf1 null chondrocytes. Glycogen levels were significantly decreased and ribosomal RNA levels were reduced by almost 75% in Igf1 null chondrocytes. These data suggest that Igf1 promotes longitudinal bone growth by 'insulin-like' anabolic actions which augment chondrocyte hypertrophy.     

Igf2r improves the survival and transmission ratio of Igf2 transgenic mice

Mammals with excess insulin-like growth factor 2 (IGFII) during embryogenesis have developmental defects that can lead to perinatal lethality. In adults, higher levels of IGFII increase the risk of cancer and may accelerate the development of atherosclerosis. IGFII can be increased as a consequence of genetic abnormalities and polymorphisms, and through epigenetic mechanisms. Decreasing IGFII levels thus can benefit human health. Degradation of IGFII is mediated by the insulin-like growth factor type 2 receptor (IGF2R). The growth-stimulatory effects of IGFII, and their attenuation by the IGF2R, are considered important for the evolution of IGFII/IGF2R interaction and imprinting. The IGFII/IGF2R interactions during development have been previously examined in mice carrying knock-out alleles of these genes or their regulators. Here we tested the ability of the IGF2R to ameliorate the negative effects of IGFII on development and survival in crosses between Igf2 and Igf2r transgenic mice, which may be a better model for natural variations in the levels of these genes' products. A fraction of hemizygous Igf2 transgenic mice die in the perinatal period, some with cleft palates, with an ensuing reduction in the frequency of transgenic mice among the surviving offspring. The Igf2r transgene lowers the frequency of cleft palate and increases the percentage of Igf2 transgenic mice among the live offspring. These findings draw attention to the fact that Igf2-associated lethality selects for the retention of IGFII/IGF2R binding in present day mammals; it may have played a similar role in the acquisition of IGFII/IGF2R binding in ancient mammals.     

Akt1 and insulin-like growth factor 2 (Igf2) regulate placentation and fetal/postnatal development

Phenotypic characterization of Akt1 and Igf2 null mice has revealed roles for each in the regulation of placentation, and fetal and postnatal growth. Insulin-like growth factor 2 (IGF2) is encoded by the Igf2 gene and influences cellular function, at least in part, through activation of an intracellular serine/threonine kinase called AKT1. Akt1 and Igf2 null mice were originally characterized on inbred and mixed genetic backgrounds, prohibiting direct comparisons of their phenotypes. The impact of loss of AKT1 or IGF2 on placental, fetal, and postnatal function were examined following transfer of Akt1 and Igf2 null mutations to an outbred CD1 genetic background. Disruption of IGF2 did not affect AKT expression or activation. Both Akt1-/- and Igf2-/- mice exhibited decreased placental weight, fetal weight and viability. Deregulation of placental growth was similar in Akt1 and Igf2 nulls; however, disruption of Igf2 had a more severe impact on prenatal survival and postnatal growth. Placental structure, including organization of junctional and labyrinth zones and development of the interstitial, invasive, trophoblast lineage, were similar in mutant and wild-type mice. Akt1 and Igf2 null mutations affected postnatal growth. The relative impact of each gene differed during pre-weaning versus post-weaning growth phases. AKT1 had a more significant role during pre-weaning growth, whereas IGF2 was a bigger contributor to post-weaning growth. Akt1 and Igf2 null mutations impact placental, fetal and postnatal growth. Placental phenotypes are similar; however, fetal and postnatal growth patterns are unique to each mutation.     

Intraspecific mating with CzechII/Ei mice rescue lethality associated with loss of function mutations of the imprinted genes, Igf2r and Cdkn1c

Maternal inheritance of targeted loss of function alleles encoding either the cyclin-dependent kinase inhibitor 1C (Cdkn1c) or the insulin-like growth factor 2 receptor (Igf2r) leads to fully penetrant perinatal lethality in C57BL/6J mice due to genomic imprinting. Here, we demonstrate that there is a marked enhancement in postnatal viability of F(1) mice carrying either the ablated Igf2r ( approximately 32%) or Cdkn1c ( approximately 83%) when the paternal genome was derived from the inbred Mus musculus musculus CzechII/Ei strain. Genetic and molecular analyses indicated that the increased viability was not caused by relaxation of imprinted gene expression, but is the consequence of unidentified polygenic modifiers that are not imprinted. In the course of this study, restriction-site polymorphisms between 129S1 and CzechII/Ei in 21 imprinted and 14 biallelically expressed genes were identified. These polymorphisms may prove useful in determining the effects of different mutant backgrounds on genomic imprinting.     

Meg1/Grb10 overexpression causes postnatal growth retardation and insulin resistance via negative modulation of the IGF1R and IR cascades

The Meg1/Grb10 protein has been implicated as an adapter protein in the signaling pathways from insulin receptor (IR) and insulin-like growth factor 1 receptor (IGF1R) in vitro. To elucidate its in vivo function, four independent Meg1/Grb10 transgenic mouse lines were established, and the effects of excess Meg1/Grb10 on both postnatal growth and glucose metabolism were examined. All of the Meg1/Grb10 transgenic mice showed growth retardation after weaning (3-4 weeks), which indicates that ectopic overexpression of Meg1/Grb10 inhibits postnatal growth that is mediated by IGF1 via IGF1R. In addition, the mice became hyperinsulinemic owing to high levels of insulin resistance, which demonstrates that Meg1/Grb10 also modulates the insulin receptor cascade negatively in vivo. Type II diabetes arose frequently in the two transgenic lines, which also showed impaired glucose tolerance. In these mice, severe atrophy of the pancreatic acinus cells was associated with high-level production of Meg1/Grb10 in the pancreas. These results suggest that Meg1/Grb10 inhibits the function of both insulin and IGF1 receptors in these cells, since a similar phenotype has been reported for Ir and Igf1r double knockout mice. Taken together, these results indicate that Meg1/Grb10 interacts with both insulin and IGF1 receptors in vivo, and negatively regulates the IGF growth pathways via these receptors.     

PTEN deficiency causes dyschondroplasia in mice by enhanced hypoxia-inducible factor 1alpha signaling and endoplasmic reticulum stress

Chondrocytes within the growth plates acclimatize themselves to a variety of stresses that might otherwise disturb cell fate. The tumor suppressor PTEN (phosphatase and tensin homolog deleted from chromosome 10) has been implicated in the maintenance of cell homeostasis. However, the functions of PTEN in regulating chondrocytic adaptation to stresses remain largely unknown. In this study, we have created chondrocyte-specific Pten knockout mice (Pten(co/co);Col2a1-Cre) using the Cre-loxP system. Following AKT activation, Pten mutant mice exhibited dyschondroplasia resembling human enchondroma. Cartilaginous nodules originated from Pten mutant resting chondrocytes that suffered from impaired proliferation and differentiation, and this was coupled with enhanced endoplasmic reticulum (ER) stress. We further found that ER stress in Pten mutant chondrocytes only occurred under hypoxic stress, characterized by an upregulation of unfolded protein response-related genes as well as an engorged and fragmented ER in which collagens were trapped. An upregulation of hypoxia-inducible factor 1alpha (HIF1alpha) and downstream targets followed by ER stress induction was also observed in Pten mutant growth plates and in cultured chondrocytes, suggesting that PI3K/AKT signaling modulates chondrocytic adaptation to hypoxic stress via regulation of the HIF1alpha pathway. These data demonstrate that PTEN function in chondrocytes is essential for their adaptation to stresses and for the inhibition of dyschondroplasia.     

Arginine deficiency causes runting in the suckling period by selectively activating the stress kinase GCN2

Suckling "F/A2" mice, which overexpress arginase-I in their enterocytes, develop a syndrome (hypoargininemia, reduced hair and muscle growth, impaired B-cell maturation) that resembles IGF1 deficiency. The syndrome may result from an impaired function of the GH-IGF1 axis, activation of the stress-kinase GCN2, and/or blocking of the mTORC1-signaling pathway. Arginine deficiency inhibited GH secretion and decreased liver Igf1 mRNA and plasma IGF1 concentration, but did not change muscle IGF1 concentration. GH supplementation induced Igf1 mRNA synthesis, but did not restore growth, ruling out direct involvement of the GH-IGF1 axis. In C2C12 muscle cells, arginine withdrawal activated GCN2 signaling, without impacting mTORC1 signaling. In F/A2 mice, the reduction of plasma and tissue arginine concentrations to ～25% of wild-type values activated GCN2 signaling, but mTORC1-mediated signaling remained unaffected. Gcn2-deficient F/A2 mice suffered from hypoglycemia and died shortly after birth. Because common targets of all stress kinases (eIF2α phosphorylation, Chop mRNA expression) were not increased in these mice, the effects of arginine deficiency were solely mediated by GCN2.     

Perinatal lethality in H19 enhancers-Igf2 transgenic mice

The insulin-like growth factor II (IGFII) is a mitogen for a number of cell types in vitro and is required for normal embryonic growth. It has been hypothesized that overexpression of IGF2 is responsible for the increased growth and tumor predisposition in patients with Beckwith-Wiedemann syndrome. Association of increased levels of IGFII with increased growth is also incorporated in a current model for the evolution of Igf2 imprinting. Different experimental approaches to increasing IGFII levels in the mouse have yielded different results with respect to its effects on growth, viability, and tumor development. To investigate the consequences of Igf2 overexpression in the embryonic period, without alterations in the activity of other genes, we produced transgenic mice that express the Igf2 gene under the control of the H19 enhancers. Transgene expression in the embryonic period had no significant effect on the overall size of the embryos, but was associated with perinatal lethality in homozygous, and some heterozygous, mice. A large fraction of homozygous mice also developed a cleft palate. These findings indicate that overexpression of Igf2 can have an adverse effect on viability in the absence of a pronounced effect on overall body growth. The results are consistent with the view that growth and perinatal viability are affected differently by Igf2 overexpression in endodermal and mesodermal tissues. Mol. Reprod. Dev. 48:194–207, 1997. © 1997 Wiley-Liss, Inc.     

Genetic analysis of type-1 insulin-like growth factor receptor signaling through insulin receptor substrate-1 and -2 in pancreatic beta cells

Signaling by receptor tyrosine kinases regulates pancreatic β cell function. Inactivation of insulin receptor (InsR), IGF1 receptor (Igf1r), or Irs1 in β cells impairs insulin secretion. Conversely, Irs2 ablation impairs β cell replication. In this study, we examined aspects of the Igf1r regulatory signaling cascade in β cells. To examine genetically the involvement of Irs1 and Irs2 in Igf1r signaling, we generated double mutant mice lacking Igf1r specifically in pancreatic β cells in an Irs1- or Irs2-null background. We show that Igf1r/Irs1 double mutants do not differ phenotypically from Irs1 single mutants and exhibit hyperinsulinemia, while maintaining normal β cell mass and glucose tolerance. In contrast, lack of Igf1r function in β cells aggravates the consequences of Irs2 ablation in double mutants and results in lethal diabetes by 6 weeks of age. This additivity of phenotypic manifestations indicates that Irs2 serves a pathway that is largely independent of Igf1r signaling. Consistent with the view that the latter is the InsR pathway, we show that combined β cell-specific knock-out of both Insr and Igf1r results in a phenocopy of double mutants lacking Igf1r and Irs2. We conclude that Igf1r signals primarily through Irs1 and affects insulin secretion, whereas β cell proliferation is mainly regulated by InsR using Irs2 as a downstream signaling effector. The insulin and IGF pathways appear to control β cell functions independently and selectively.     

A thyrotoxic skeletal phenotype of advanced bone formation in mice with resistance to thyroid hormone

Thyroid hormone (T3) regulates bone turnover and mineralization in adults and is essential for skeletal development during childhood. Hyperthyroidism is an established risk factor for osteoporosis. Nevertheless, T3 actions in bone remain poorly understood. Patients with resistance to thyroid hormone, due to mutations of the T3-receptor beta (TRbeta) gene, display variable phenotypic abnormalities, particularly in the skeleton. To investigate the actions of T3 during bone development, we characterized the skeleton in TRbetaPV mutant mice. TRbetaPV mice harbor a targeted resistance to thyroid hormone mutation in TRbeta and recapitulate the human condition. A severe phenotype, which includes shortened body length, was evident in homozygous TRbetaPV/PV animals. Accelerated growth in utero was associated with advanced endochondral and intramembranous ossification. Advanced bone formation resulted in postnatal growth retardation, premature quiescence of the growth plates, and shortened bone length, together with increased bone mineralization and craniosynostosis. In situ hybridization demonstrated increased expression of fibroblast growth factor receptor-1, a T3-regulated gene in bone, in TRbetaPV/PV perichondrium, growth plate chondrocytes, and osteoblasts. Thus, the skeleton in TRbetaPV/PV mice is thyrotoxic and displays phenotypic features typical of juvenile hyperthyroidism.     

Mex3c mutation affects lactation through impairing milk ejection in female mice

Mouse Mex3c encodes RNA-binding proteins of variant length through alternative splicing. Its mutation results in multiple defects including growth retardation, perturbed energy balance, and defective antiviral innate immunity. Here we report that Mex3c mutation affects mammary gland development and lactation in female mice. Pups of Mex3c mutant dams die of starvation soon after birth. Milk contents are present in the alveoli but deficient in the ducts of the mammary glands in mutant mice. Mutant mice do not show prolactin or oxytocin deficiency. They also develop myoepithelial cells in the mammary glands. Mex3c is expressed in the mammary gland epithelium. Our data suggest that functional defects in mammary gland epithelium or myoepithelial cells could cause lactation defects.     

Matrix IGF-1 maintains bone mass by activation of mTOR in mesenchymal stem cells

Insulin-like growth factor 1 (IGF-1), the most abundant growth factor in the bone matrix, maintains bone mass in adulthood. We now report that IGF-1 released from the bone matrix during bone remodeling stimulates osteoblastic differentiation of recruited mesenchymal stem cells (MSCs) by activation of mammalian target of rapamycin (mTOR), thus maintaining proper bone microarchitecture and mass. Mice with knockout of the IGF-1 receptor (Igf1r) in their pre-osteoblastic cells showed lower bone mass and mineral deposition rates than wild-type mice. Further, MSCs from Igf1rflox/flox mice with Igf1r deleted by a Cre adenovirus in vitro, although recruited to the bone surface after implantation, were unable to differentiate into osteoblasts. We also found that the concentrations of IGF-1 in the bone matrix and marrow of aged rats were lower than in those of young rats and directly correlated with the age-related decrease in bone mass. Likewise, in age-related osteoporosis in humans, we found that bone marrow IGF-1 concentrations were 40% lower in individuals with osteoporosis than in individuals without osteoporosis. Notably, injection of IGF-1 plus IGF binding protein 3 (IGFBP3), but not injection of IGF-1 alone, increased the concentration of IGF-1 in the bone matrix and stimulated new bone formation in aged rats. Together, these results provide mechanistic insight into how IGF-1 maintains adult bone mass, while also providing a further rationale for its therapeutic targeting to treat age-related osteoporosis.