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E Nieves-Martinez Neuroscience Program, Physiology and Pharmacology, Department of Internal Medicine, Reynolds Oklahoma Center on Aging, Neurobiology and Anatomy

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W E Sonntag Neuroscience Program, Physiology and Pharmacology, Department of Internal Medicine, Reynolds Oklahoma Center on Aging, Neurobiology and Anatomy

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A Wilson Neuroscience Program, Physiology and Pharmacology, Department of Internal Medicine, Reynolds Oklahoma Center on Aging, Neurobiology and Anatomy

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A Donahue Neuroscience Program, Physiology and Pharmacology, Department of Internal Medicine, Reynolds Oklahoma Center on Aging, Neurobiology and Anatomy

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D P Molina Neuroscience Program, Physiology and Pharmacology, Department of Internal Medicine, Reynolds Oklahoma Center on Aging, Neurobiology and Anatomy

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J Brunso-Bechtold Neuroscience Program, Physiology and Pharmacology, Department of Internal Medicine, Reynolds Oklahoma Center on Aging, Neurobiology and Anatomy
Neuroscience Program, Physiology and Pharmacology, Department of Internal Medicine, Reynolds Oklahoma Center on Aging, Neurobiology and Anatomy

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M M Nicolle Neuroscience Program, Physiology and Pharmacology, Department of Internal Medicine, Reynolds Oklahoma Center on Aging, Neurobiology and Anatomy
Neuroscience Program, Physiology and Pharmacology, Department of Internal Medicine, Reynolds Oklahoma Center on Aging, Neurobiology and Anatomy
Neuroscience Program, Physiology and Pharmacology, Department of Internal Medicine, Reynolds Oklahoma Center on Aging, Neurobiology and Anatomy

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GH levels increase to high concentrations immediately before puberty then progressively decline with age. GH deficiency (GHD) originating in childhood is treated with GH supplementation to foster somatic development during adolescence. It is not clear if or how early GH replacement affects memory in adulthood, or whether it can prevent the cognitive deficits commonly observed in adults with childhood-onset GHD. Rats homozygous for the Dw-4 mutation (dwarf) do not exhibit the normal increase in GH at 4 weeks of age when GH levels normally rise and are used to model childhood or early-onset GHD (EOGHD). One group of these rats was injected with GH from 4 to 14 weeks of age to model GH supplementation during adolescence with GHD beginning in adulthood (adult-onset GHD; AOGHD). Another group received GH from 4 weeks throughout the lifespan to model normal lifespan GH (GH-replete). Age-matched, Dw-4 heterozygous rats (HZ) do not express the dwarf phenotype and were used as controls. At 8 and 18 months of age, spatial learning in the water maze was assessed. At 8 months of age all experimental groups were equally proficient. However, at 18 months of age, the EOGHD group had poor spatial learning compared to the AOGHD, GH-replete, and HZ groups. Our data indicate that GHD during adolescence has negative effects on learning and memory that emerge by middle-age unless prevented by GH supplementation.

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Victoria E DeMambro
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Masanobu Kawai The Jackson Laboratory, Medical Center Research Institute, John Hopkins University, Massachusetts General Hospital, Department of Research, 600 Main Street, Bar Harbor, Maine 04609, USA

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Thomas L Clemens The Jackson Laboratory, Medical Center Research Institute, John Hopkins University, Massachusetts General Hospital, Department of Research, 600 Main Street, Bar Harbor, Maine 04609, USA

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Keertik Fulzele The Jackson Laboratory, Medical Center Research Institute, John Hopkins University, Massachusetts General Hospital, Department of Research, 600 Main Street, Bar Harbor, Maine 04609, USA

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Jane A Maynard
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Caralina Marín de Evsikova
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Kenneth R Johnson
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Ernesto Canalis The Jackson Laboratory, Medical Center Research Institute, John Hopkins University, Massachusetts General Hospital, Department of Research, 600 Main Street, Bar Harbor, Maine 04609, USA

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Wesley G Beamer
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Clifford J Rosen The Jackson Laboratory, Medical Center Research Institute, John Hopkins University, Massachusetts General Hospital, Department of Research, 600 Main Street, Bar Harbor, Maine 04609, USA

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Leah Rae Donahue
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A spontaneous mouse mutant, designated ‘small’ (sml), was recognized by reduced body size suggesting a defect in the IGF1/GH axis. The mutation was mapped to the chromosome 1 region containing Irs1, a viable candidate gene whose sequence revealed a single nucleotide deletion resulting in a premature stop codon. Despite normal mRNA levels in mutant and control littermate livers, western blot analysis revealed no detectable protein in mutant liver lysates. When compared with the control littermates, Irs1 sml /Irs1 sml (Irs1 sml/sml ) mice were small, lean, hearing impaired; had 20% less serum IGF1; were hyperinsulinemic; and were mildly insulin resistant. Irs1 sml/sml mice had low bone mineral density, reduced trabecular and cortical thicknesses, and low bone formation rates, while osteoblast and osteoclast numbers were increased in the females but not different in the males compared with the Irs1 +/+ controls. In vitro, Irs1 sml/sml bone marrow stromal cell cultures showed decreased alkaline phosphatase-positive colony forming units (pre-osteoblasts; CFU-AP+) and normal numbers of tartrate-resistant acid phosphatase-positive osteoclasts. Irs1 sml/sml stromal cells treated with IGF1 exhibited a 50% decrease in AKT phosphorylation, indicative of defective downstream signaling. Similarities between engineered knockouts and the spontaneous mutation of Irs1 sml were identified as well as significant differences with respect to heterozygosity and gender. In sum, we have identified a spontaneous mutation in the Irs1 gene associated with a major skeletal phenotype. Changes in the heterozygous Irs1 + /sml mice raise the possibility that similar mutations in humans are associated with short stature or osteoporosis.

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