Effect of aminoglutethimide on ACTH plasma levels in Cushing's disease and Nelson syndrome]

Out of all steroidogenesis inhibitors aminoglutethimide is most frequently used agent for so-called chemical adrenalectomy, especially in oncological cases. The present studies aimed at assessing an effect of the inhibition of cortisol synthesis on plasma ACTH in patients treated with aminoglutethimide. According to the rules of negative feedback, an increase in plasma ACTH should be expected. Aminoglutethimide has been administered to 24 patients with Cushing's disease for 1-6 months. Plasma ACTH did not increase but statistically significantly decreased despite a decrease in blood cortisol. It indicates that aminoglutethimide directly inhibits ACTH secretion. No return of the normal circadian rhythm of cortisol and ACTH release suggests that the drug exerts an effect on ACTH release regulating mechanisms. No definite results were achieved in patients with Nelson syndrome treated with aminoglutethimide for a short period of time. Plasma ACTH levels tend to decrease but no statistical significance was observed in comparison with placebo. It may depend on markedly increased corticotrophin secretion in Nelson tumors.     

Generation of the Sotos syndrome deletion in mice

Haploinsufficiency of the human 5q35 region spanning the NSD1 gene results in a rare genomic disorder known as Sotos syndrome (Sotos), with patients displaying a variety of clinical features, including pre- and postnatal overgrowth, intellectual disability, and urinary/renal abnormalities. We used chromosome engineering to generate a segmental monosomy, i.e., mice carrying a heterozygous 1.5-Mb deletion of 36 genes on mouse chromosome 13 (4732471D19Rik-B4galt7), syntenic with 5q35.2–q35.3 in humans (Df(13)Ms2Dja ^+/− mice). Surprisingly Df(13)Ms2Dja ^+/− mice were significantly smaller for their gestational age and also showed decreased postnatal growth, in contrast to Sotos patients. Df(13)Ms2Dja ^+/− mice did, however, display deficits in long-term memory retention and dilation of the pelvicalyceal system, which in part may model the learning difficulties and renal abnormalities observed in Sotos patients. Thus, haploinsufficiency of genes within the mouse 4732471D19Rik–B4galt7 deletion interval play important roles in growth, memory retention, and the development of the renal pelvicalyceal system.

     

Modeling partial monosomy for human chromosome 21q11.2-q21.1 reveals haploinsufficient genes influencing behavior and fat deposition

Haploinsufficiency of part of human chromosome 21 results in a rare condition known as Monosomy 21. This disease displays a variety of clinical phenotypes, including intellectual disability, craniofacial dysmorphology, skeletal and cardiac abnormalities, and respiratory complications. To search for dosage-sensitive genes involved in this disorder, we used chromosome engineering to generate a mouse model carrying a deletion of the Lipi-Usp25 interval, syntenic with 21q11.2-q21.1 in humans. Haploinsufficiency for the 6 genes in this interval resulted in no gross morphological defects and behavioral analysis performed using an open field test, a test of anxiety, and tests for social interaction were normal in monosomic mice. Monosomic mice did, however, display impaired memory retention compared to control animals. Moreover, when fed a high-fat diet (HFD) monosomic mice exhibited a significant increase in fat mass/fat percentage estimate compared with controls, severe fatty changes in their livers, and thickened subcutaneous fat. Thus, genes within the Lipi-Usp25 interval may participate in memory retention and in the regulation of fat deposition.     

Generation of the Sotos syndrome deletion in mice

Haploinsufficiency of the human 5q35 region spanning the NSD1 gene results in a rare genomic disorder known as Sotos syndrome (Sotos), with patients displaying a variety of clinical features, including pre- and postnatal overgrowth, intellectual disability, and urinary/renal abnormalities. We used chromosome engineering to generate a segmental monosomy, i.e., mice carrying a heterozygous 1.5-Mb deletion of 36 genes on mouse chromosome 13 (4732471D19Rik-B4galt7), syntenic with 5q35.2?Cq35.3 in humans (Df(13)Ms2Dja ^+/? mice). Surprisingly Df(13)Ms2Dja ^+/? mice were significantly smaller for their gestational age and also showed decreased postnatal growth, in contrast to Sotos patients. Df(13)Ms2Dja ^+/? mice did, however, display deficits in long-term memory retention and dilation of the pelvicalyceal system, which in part may model the learning difficulties and renal abnormalities observed in Sotos patients. Thus, haploinsufficiency of genes within the mouse 4732471D19Rik?CB4galt7 deletion interval play important roles in growth, memory retention, and the development of the renal pelvicalyceal system.