Linda Tillmar1, Nils Welsh. 1. Department of Medical Cell Biology, Uppsala University, Uppsala, Sweden. Linda.Tillmar@medcellbiol.uu.se
Abstract
BACKGROUND: Recent reports identify the 3'-UTR of insulin mRNA as crucial for control of insulin messenger stability. This region contains a pyrimidine-rich sequence, which is similar to the hypoxia-responsive mRNA-stabilizing element of tyrosine hydroxylase. This study aimed to determine whether hypoxia affects insulin mRNA levels. MATERIALS AND METHODS: Rat islets were incubated at normoxic or hypoxic conditions and with or without hydrogen peroxide and a nitric oxide donor. Insulin mRNA was determined by Northern hybridization. Islet homogenates were used for electrophoretic mobility shift assay with an RNA-oligonucleotide, corresponding to the pyrimidine-rich sequence of the 3'-UTR of rat insulin I mRNA. The expression of reporter gene mRNA, in islets transfected with reporter gene constructs containing the wild-type or mutated insulin mRNA pyrimidine-rich sequences, was measured by semiquantitive RT-PCR. RESULTS: Insulin mRNA was increased in response to hypoxia. This was paralleled by increased binding of the polypyrimidine tract-binding protein (PTB) to the pyrimidine-rich sequence of the 3'-UTR of insulin mRNA, which was counteracted by hydrogen peroxide. The reporter gene mRNA level containing the wild-type binding site was not increased in response to hypoxia, but mutation of the site resulted in a destabilization of the mRNA. CONCLUSIONS: The complete understanding of different diabetic conditions requires the elucidation of mechanisms that control insulin gene expression. Our data show that hypoxia may increase insulin mRNA levels by promoting the binding of PTB to the insulin mRNA 3'-UTR. Hydrogen peroxide abolishes the hypoxic effect indicating involvement of reactive oxygen species and/or the redox potential in the oxygen-signaling pathway.
BACKGROUND: Recent reports identify the 3'-UTR of insulin mRNA as crucial for control of insulin messenger stability. This region contains a pyrimidine-rich sequence, which is similar to the hypoxia-responsive mRNA-stabilizing element of tyrosine hydroxylase. This study aimed to determine whether hypoxia affects insulin mRNA levels. MATERIALS AND METHODS:Rat islets were incubated at normoxic or hypoxic conditions and with or without hydrogen peroxide and a nitric oxidedonor. Insulin mRNA was determined by Northern hybridization. Islet homogenates were used for electrophoretic mobility shift assay with an RNA-oligonucleotide, corresponding to the pyrimidine-rich sequence of the 3'-UTR of rat insulin I mRNA. The expression of reporter gene mRNA, in islets transfected with reporter gene constructs containing the wild-type or mutated insulin mRNA pyrimidine-rich sequences, was measured by semiquantitive RT-PCR. RESULTS: Insulin mRNA was increased in response to hypoxia. This was paralleled by increased binding of the polypyrimidine tract-binding protein (PTB) to the pyrimidine-rich sequence of the 3'-UTR of insulin mRNA, which was counteracted by hydrogen peroxide. The reporter gene mRNA level containing the wild-type binding site was not increased in response to hypoxia, but mutation of the site resulted in a destabilization of the mRNA. CONCLUSIONS: The complete understanding of different diabetic conditions requires the elucidation of mechanisms that control insulin gene expression. Our data show that hypoxia may increase insulin mRNA levels by promoting the binding of PTB to the insulin mRNA 3'-UTR. Hydrogen peroxide abolishes the hypoxic effect indicating involvement of reactive oxygen species and/or the redox potential in the oxygen-signaling pathway.
Authors: Eun Kyung Lee; Wook Kim; Kumiko Tominaga; Jennifer L Martindale; Xiaoling Yang; Sarah S Subaran; Olga D Carlson; Evi M Mercken; Rohit N Kulkarni; Wado Akamatsu; Hideyuki Okano; Nora I Perrone-Bizzozero; Rafael de Cabo; Josephine M Egan; Myriam Gorospe Journal: Mol Cell Date: 2012-03-01 Impact factor: 17.970
Authors: Daniel C Reid; Brian L Chang; Samuel I Gunderson; Lauren Alpert; William A Thompson; William G Fairbrother Journal: RNA Date: 2009-10-27 Impact factor: 4.942