Pseudogene-mediated posttranscriptional silencing of HMGA1 can result in insulin resistance and type 2 diabetes.

Processed pseudogenes are non-functional copies of normal genes that arise by a process of mRNA retrotransposition. The human genome contains thousands of pseudogenes; however, knowledge regarding their biological role is limited. Previously, we demonstrated that high mobility group A1 (HMGA1) protein regulates the insulin receptor (INSR) gene and that two diabetic patients demonstrated a marked destabilization of HMGA1 mRNA. In this paper we report that this destabilization of HMGA1 mRNA is triggered by enhanced expression of RNA from an HMGA1 pseudogene, HMGA1-p. Targeted knockdown of HMGA1-p mRNA in patient cells results in a reciprocal increase in HMGA1 mRNA stability and expression levels with a parallel correction in cell-surface INSR expression and insulin binding. These data provide evidence for a regulatory role of an expressed pseudogene in humans and establishes a novel mechanistic linkage between pseudogene HMGA1-p expression and type 2 diabetes mellitus.

The cAMP-HMGA1-RBP4 system: a novel biochemical pathway for modulating glucose homeostasis.

BACKGROUND: We previously showed that mice lacking the high mobility group A1 gene (Hmga1-knockout mice) developed a type 2-like diabetic phenotype, in which cell-surface insulin receptors were dramatically reduced (below 10% of those in the controls) in the major targets of insulin action, and glucose intolerance was associated with increased peripheral insulin sensitivity. This particular phenotype supports the existence of compensatory mechanisms of insulin resistance that promote glucose uptake and disposal in peripheral tissues by either insulin-dependent or insulin-independent mechanisms. We explored the role of these mechanisms in the regulation of glucose homeostasis by studying the Hmga1-knockout mouse model. Also, the hypothesis that increased insulin sensitivity in Hmga1-deficient mice could be related to the deficit of an insulin resistance factor is discussed. RESULTS: We first show that HMGA1 is needed for basal and cAMP-induced retinol-binding protein 4 (RBP4) gene and protein expression in living cells of both human and mouse origin. Then, by employing the Hmga1-knockout mouse model, we provide evidence for the identification of a novel biochemical pathway involving HMGA1 and the RBP4, whose activation by the cAMP-signaling pathway may play an essential role for maintaining glucose metabolism homeostasis in vivo, in certain adverse metabolic conditions in which insulin action is precluded. In comparative studies of normal and mutant mice, glucagon administration caused a considerable upregulation of HMGA1 and RBP4 expression both at the mRNA and protein level in wild-type animals. Conversely, in Hmga1-knockout mice, basal and glucagon-mediated expression of RBP4 was severely attenuated and correlated inversely with increased Glut4 mRNA and protein abundance in skeletal muscle and fat, in which the activation state of the protein kinase Akt, an important downstream mediator of the metabolic effects of insulin on Glut4 translocation and carbohydrate metabolism, was simultaneously increased. CONCLUSION: These results indicate that HMGA1 is an important modulator of RBP4 gene expression in vivo. Further, they provide evidence for the identification of a novel biochemical pathway involving the cAMP-HMGA1-RBP4 system, whose activation may play a role in glucose homeostasis in both rodents and humans. Elucidating these mechanisms has importance for both fundamental biology and therapeutic implications.

Serum and glucocorticoid-regulated kinase Sgk1 inhibits insulin-dependent activation of phosphomannomutase 2 in transfected COS-7 cells.

Serum- and glucocorticoid-regulated kinase (Sgk1) is considered to be an essential convergence point for peptide and steroid regulation of ENaC-mediated sodium transport. We tried to identify molecular partners of Sgk1 by yeast two-hybrid screening. Yeast two-hybrid screening showed a specific interaction between Sgk1 and phosphomannomutase (PMM)2, the latter of which is an enzyme involved in the regulation of glycoprotein biosynthesis. The interaction was confirmed in intact cells by coimmunoprecipitation and colocalization detected using confocal microscopy. We were then able to demonstrate that Sgk1 phosphorylated PMM2 in an in vitro assay. In addition, we found that the enzymatic activity of PMM2 is upregulated by insulin treatment and that Sgk1 completely inhibits PMM2 activity both in the absence and in the presence of insulin stimulation. These data provide evidence suggesting that Sgk1 may modulate insulin action on the cotranslational glycosylation of glycoproteins.

The tyrosine phosphatase PTPRJ/DEP-1 genotype affects thyroid carcinogenesis.

We recently isolated the r-PTPeta gene, which encodes a receptor-type tyrosine phosphatase protein that suppresses the neoplastic phenotype of retrovirally transformed rat thyroid cells. The human homologue gene PTPRJ/DEP-1 is deleted in various tumors. Moreover, the Gln276Pro polymorphism, located in the extracellular region of the gene, seems to play a critical role in susceptibility to some human neoplasias. Here we report the loss of heterozygosity (LOH) of PTPRJ in 11/76 (14.5%) informative thyroid tumors (including adenomas and carcinomas). We also looked for the Gln276Pro, Arg326Gln and Asp872Glu polymorphisms in exons 5, 6 and 13 of PTPRJ in 88 patients with thyroid tumors and in 54 healthy individuals. We found that the PTPRJ genotypes homozygous for the Gln276Pro and Arg326Gln polymorphisms, and the Asp872 allele were more frequent in thyroid carcinoma patients than in healthy individuals (P=0.032). In addition, PTPRJ LOH was more frequent in thyroid carcinomas of heterozygotes for Gln276Pro and Arg326Gln compared with homozygotes (P=0.006). This suggests that the presence of hemizygosity for these polymorphisms in the tumor facilitates tumor progression. These results indicate that the genotypic profile of PTPRJ affects susceptibility to thyroid carcinomas, and that allelic loss of this gene is involved in thyroid carcinogenesis.

An adenovirus carrying the rat protein tyrosine phosphatase eta suppresses the growth of human thyroid carcinoma cell lines in vitro and in vivo.

We demonstrated previously that rat tyrosine phosphatase r-PTPeta expression was suppressed in rat and human thyroid neoplastic cells, and that restoration of r-PTPeta expression reverted the malignant phenotype. To investigate the potential of this gene for cancer therapy, we generated an adenovirus carrying the r-PTPeta cDNA (Ad-r-PTPeta). This virus infected human thyroid carcinoma cells and overexpressed the r-PTPeta protein. Overexpression of r-PTPeta significantly inhibited the growth of four thyroid carcinoma cell lines. Cell growth inhibition was associated with down-regulation of extracellular signal-regulated kinase 1/2 activity, with increased levels of the cell-cycle inhibitor p27(kip1) protein and with dephosphorylation of PLCgamma1, a substrate of DEP-1, the human homologue of r-PTPeta. Finally, the growth of xenograft tumors induced in athymic mice by anaplastic thyroid carcinoma ARO cells transduced with the Ad-r-PTPeta virus was drastically reduced. These data suggest that gene therapy based on restoration of PTPeta function has potential in the treatment of human thyroid malignant neoplasias.

Inhibitory effects of peroxisome poliferator-activated receptor gamma on thyroid carcinoma cell growth.

Peroxisome proliferator-activated receptor gamma (PPAR gamma) is a nuclear receptor involved in such cellular processes as adipogenesis, inflammation, atherosclerosis, cell cycle control, apoptosis, and carcinogenesis. PPAR gamma gene mutations have been found in 4 of 55 sporadic colon cancers, and a chimeric PAX8-PPAR gamma 1 gene frequently generates a chromosomal translocation in thyroid follicular carcinomas, implicating PPAR gamma in tumor suppression. We investigated whether PPAR gamma is involved in the growth regulation of normal and tumor thyroid cells. We found no mutations in PPAR gamma exons 3 and 5 in human thyroid carcinoma cell lines and tissues. Moreover, 1 cell line (NPA) of 6 analyzed did not express PPAR gamma. Treatment of NPA with PPAR gamma agonists did not induce any inhibitory effect. Conversely, PPAR gamma agonists and PPAR gamma overexpression led to a drastic reduction of the cell growth rate in PPAR gamma-expressing thyroid carcinoma cells. Restoration of PPAR gamma expression in NPA cells induced cell growth inhibition; PPAR gamma agonists induced further inhibition. Growth inhibition induced by PPAR gamma agonists or by PPAR gamma gene overexpression in thyroid carcinoma cells was associated with increased p27 protein levels and apoptotic cell death. Should these data be confirmed, PPAR gamma could be a novel target for innovative therapy of thyroid carcinoma, particularly anaplastic carcinomas, which represent one of the most aggressive tumors in mankind and are unresponsive to conventional therapy.