Ming-Xiang Zhang

Free Fatty Acids Inhibit Insulin Signaling–Stimulated Endothelial Nitric Oxide Synthase Activation Through Upregulating PTEN or Inhibiting Akt Kinase

In metabolic syndrome, a systemic deregulation of the insulin pathway leads to a combined deregulation of insulin-regulated metabolism and cardiovascular functions. Free fatty acids (FFAs), which are increased in metabolic syndrome, inhibit insulin signaling and induce metabolic insulin resistance. This study was designed to examine FFAs’ effects on vascular insulin signaling and endothelial nitric oxide (NO) synthase (eNOS) activation in endothelial cells. We showed that FFAs inhibited insulin signaling and eNOS activation through different mechanisms. While linoleic acid inhibited Akt-mediated eNOS phosphorylation, palmitic acid appeared to affect the upstream signaling. Upregulation of PTEN (phosphatase and tensin homolog deleted on chromosome 10) activity and transcription by palmitic acid mediated the inhibitory effects on insulin signaling. We further found that activated stress signaling p38, but not Jun NH2-terminal kinase, was involved in PTEN upregulation. The p38 target transcriptional factor activating transcription factor (ATF)-2 bound to the PTEN promoter, which was increased by palmitic acid treatment. In summary, both palmitic acid and linoleic acid exert inhibitory effect on insulin signaling and eNOS activation in endothelial cells. Palmitic acid inhibits insulin signaling by promoting PTEN activity and its transcription through p38 and its downstream transcription factor ATF-2. Our findings suggest that FFA-mediated inhibition of vascular insulin signaling and eNOS activation may contribute to cardiovascular diseases in metabolic syndrome.

Biogenesis of Short Intronic Repeat 27-Nucleotide Small RNA from Endothelial Nitric-oxide Synthase Gene

Endothelial nitric-oxide synthase (eNOS) is a constitutively expressed gene in endothelium that produces NO and is critical for vascular integrity. Previously, we reported that the 27-nucleotide (nt) repeat polymorphism in eNOS intron 4, a source of 27-nt small RNA, which inhibits eNOS expression, were associated with cardiovascular risk and expression of the eNOS gene. In the current study, we investigated the biogenesis of the intron 4-derived 27-nt small RNA. Using Northern blot, we showed that the eNOS-derived 27-nt short intronic repeat RNA (sir-RNA) expressed only in the eNOS expressing endothelial cells. Cells containing 10 × 27- or 5 × 27-nt repeats produced higher levels of 27nt sir-RNA and lower levels of eNOS mRNA than the cells with 4 × 27-nt repeats. The 27nt sir-RNA was mostly present within the endothelial nuclei. When the splicing junctions of the 27-nt repeat containing intron 4 in the full-length eNOS cDNA vector were mutated, 27nt sir-RNA biogenesis was abolished. Suppression of Drosha or Dicer diminished the biogenesis of the 27nt sir-RNA. Our study suggests that the 27nt sir-RNA derived through eNOS pre-mRNA splicing may represent a new class of small RNA. The more eNOS is transcribed or higher number of the 27-nt repeats, the more 27nt sir-RNA is produced, which functions as a negative feedback self-regulator by specifically inhibiting the host gene eNOS expression. This novel molecular model may be responsible for quantitative differences between individuals carrying different numbers of the polymorphic repeats hence the cardiovascular risk.