4 research outputs found
<i>Prop1</i>-defiency results in low blood glucose levels.
<p>Blood glucose levels were measured in normal and <i>Prop1</i> mutant mice at four ages. (A) Basal glucose levels in 3.5 to 5 week <i>Prop1<sup>-/-</sup></i> mice (nβ=β6) were lower than <i>Prop1<sup>+/+</sup></i> (nβ=β10) and <i>Prop1<sup>+/β</sup></i> (nβ=β10) mice from mixed genetic backgrounds, but the difference was not statistically significant at this age. (B) On mixed genetic backgrounds the blood-glucose measurements from 5 to 6.5 wk old <i>Prop1<sup>+/+</sup></i> (nβ=β6) and <i>Prop1</i><sup>df/df</sup> (nβ=β6) were normal, but <i>Prop1</i><sup>df/-</sup> (nβ=β3), <i>Prop1<sup>-/-</sup></i> healthy (nβ=β12) and <i>Prop1<sup>-/-</sup></i> wasting (nβ=β7) mice had significantly decreased blood-glucose levels. Values represent the mean blood glucose levels (mg glucose/dL blood) Β± SE. *, <i>P</i><0.01; **, <i>P</i><0.005. (C) The low glucose levels in mutants shown in panel B are associated with elevated corticosterone levels (ng corticosterone/ml blood +/β SE.) (D) Blood-glucose levels were measured in 8 to 10 week old mice of the N4 B6 background prior to (white bars) and following restraint stress (black bars). <i>Prop1<sup>-/-</sup></i> (nβ=β8) mice had decreased basal and post-stress blood-glucose levels compared to <i>Prop1<sup>+/+</sup></i> (nβ=β9) and <i>Prop1<sup>+/β</sup></i> (nβ=β11). Values represent the mean blood glucose levels (mg glucose/dL blood) Β± SE. *, <i>P</i><0.0001; **, <i>P</i><0.0005. (E) Blood-glucose levels in 34 to 52 wk old mice on mixed genetic background were decreased in all genotypes of <i>Prop1</i> mutants, <i>Prop1<sup>df/df</sup></i> (nβ=β4), <i>Prop1<sup>df/-</sup></i> (nβ=β11), <i>Prop1<sup>-/-</sup></i> (nβ=β7), compared to normals, <i>Prop1<sup>+/+</sup></i> (nβ=β4). Values represent the mean blood glucose levels (mg glucose/dL blood) Β± SE. *, <i>P</i><0.005; **, <i>P</i><0.0005; ***, <i>P</i><0.0001.</p
Elevated basal corticosterone levels in young adult <i>Prop1</i> deficient mice become higher in response to restraint stress.
<p>RIA analysis of circulating corticosterone was carried out on serum from 8 to 10 week males (A) and females (B) of segregating the <i>Prop1</i> null allele at N4 B6 prior to (white bars) and following restraint stress (black bars). Male <i>Prop1</i><sup>-/-</sup> (nβ=β6) had significantly elevated basal and post-stress levels of corticosterone compared to <i>Prop1<sup>+/β</sup></i> (nβ=β7) and <i>Prop1<sup>+/+</sup></i> (nβ=β3). Values represent the mean corticosterone (ng/mL of blood) Β± SE. *, <i>P</i><0.0001. Female <i>Prop1<sup>-/-</sup></i> (nβ=β3) mice had both elevated basal and post-stress levels of corticosterone compared to <i>Prop1<sup>+/β</sup></i> (nβ=β5) and <i>Prop1<sup>+/+</sup></i> (nβ=β6). Values represent the mean corticosterone (ng/mL of blood) Β± SE. *, <i>P</i><0.005.</p
Adrenal glands of <i>Prop1</i> deficient mice are not hypotrophic.
<p>Adrenal glands were dissected from 5 and 8 week old female N4 B6 <i>Prop1<sup>+/+</sup></i> and <i>Prop1<sup>-/-</sup></i> mice, fixed, embedded, sectioned, and stained with hemotoxylin and eosin (Panels A, C, E, G) and immunostained for 20Ξ±-hydroxysteroid dehydrogenase <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0028355#pone.0028355-Hershkovitz1" target="_blank">[59]</a> and developed with diaminobenzidine (brown, Panels B, D, F, H) to visualize the X-zone (brackets). The ratio of adrenal weight to body weight (Panel I) was increased in <i>Prop1</i><sup>-/-</sup> (nβ=β5) compared to <i>Prop1<sup>+/β</sup></i> (nβ=β6) or <i>Prop1<sup>+/+</sup></i> (nβ=β3) N4 B6 male mice at 8 to 10 wks. Values represent the mean adrenal weight (mg) per body weight (g) Β± SE. *, <i>P</i><0.0001; **, <i>P</i><0.0005.</p
No evidence for evolving hypocortisolism in <i>Prop1</i> deficient animals.
<p>Blood plasma was collected from 3.5 to 5 wk N4B6 (Panel A) and 34 to 52 wk mixed genetic background (Panel B) animals from and the circulating ACTH levels were determined by RIA. Males and females were included together because the individual analysis showed no difference in the ACTH levels of aged-matched animals of the same genotype. At 3.5 to 5 weeks <i>Prop1<sup>-/-</sup></i> (nβ=β6) animals tended to have higher circulating levels of ACTH than <i>Prop1<sup>+/</sup></i><sup>β</sup> (nβ=β10) or <i>Prop1<sup>+/+</sup></i> (nβ=β10) animals, but the difference was not statistically significant (top). At 34 to 52 weeks three different genotypes of <i>Prop1</i> mutant animals, <i>Prop1</i><sup>-/-</sup> (nβ=β8), <i>Prop1</i><sup>df/-</sup> (nβ=β20), and <i>Prop1</i><sup>df/df</sup> (nβ=β12), exhibited an increase in circulating ACTH levels compared to <i>Prop1<sup>+/+</sup></i> (nβ=β9) (bottom). Values represent the mean ACTH production (pg/mL) Β± SE. *, <i>P</i><0.01; **, <i>P</i><0.005; ***, <i>P</i><0.0005. Corticosterone levels were measured in serum from aged male <i>Prop1<sup>+/+</sup></i> (nβ=β4), <i>Prop1</i><sup>df/df</sup> (nβ=β4), <i>Prop1</i><sup>df/-</sup> (nβ=β11), and <i>Prop1</i><sup>-/-</sup> (nβ=β7) mice (Panel C). All three genotypes of <i>Prop1</i> deficient mice show elevated basal levels of corticosterone compared to wild type. <i>Prop1</i><sup>df/df</sup> mice have statistically higher basal levels of corticosterone compared to <i>Prop1</i><sup>df/-</sup> or <i>Prop1</i><sup>-/-</sup> mice. Values represent the mean corticosterone (ng/mL of blood) Β± SE. *, <i>P</i><0.005; **, <i>P</i><0.0005; ***, <i>P</i><0.05.</p