Fetal hyperinsulinemia increases farnesylation of p21 Ras in fetal tissues

Insight into the post-translational modifications in pregnancy and related complications†

Successful pregnancy is dependent on a number of essential events, including embryo implantation, decidualization, and placentation. Failure of the above process may lead to pregnancy-related complications, including preeclampsia, gestational diabetes mellitus, preterm birth, and fetal growth restriction, may affect 15% of pregnancies, and lead to increased mortality and morbidity of pregnant women and perinatal infants, as well as the occurrence of short-term and long-term diseases. These complications have distinct etiology and pathogenesis, and the present comprehension is still lacking. Post-translational modifications are important events in epigenetics, altering the properties of proteins through protein hydrolysis or the addition of modification groups to one or more amino acids, with different modification states regulating subcellular localization, protein degradation, protein-protein interaction, signal transduction, and gene transcription. In this review, we focus on the impact of various post-translational modifications on the progress of embryo and placenta development and pregnancy-related complications, which will provide important experimental bases for exploring new insights into the physiology of pregnancy and pathogenesis associated with pregnancy complications.

Hyperinsulinemia in Obesity, Inflammation, and Cancer

The relative insufficiency of insulin secretion and/or insulin action causes diabetes. However, obesity and type 2 diabetes mellitus can be associated with an absolute increase in circulating insulin, a state known as hyperinsulinemia. Studies are beginning to elucidate the cause-effect relationships between hyperinsulinemia and numerous consequences of metabolic dysfunctions. Here, we review recent evidence demonstrating that hyperinsulinemia may play a role in inflammation, aging and development of cancers. In this review, we will focus on the consequences and mechanisms of excess insulin production and action, placing recent findings that have challenged dogma in the context of the existing body of literature. Where relevant, we elaborate on the role of specific signal transduction components in the actions of insulin and consequences of chronic hyperinsulinemia. By discussing the involvement of hyperinsulinemia in various metabolic and other chronic diseases, we may identify more effective therapeutics or lifestyle interventions for preventing or treating obesity, diabetes and cancer. We also seek to identify pertinent questions that are ripe for future investigation.

Responses of the embryonic epigenome to maternal diabetes

Maternal diabetes and obesity are independent risk factors for neural tube defects, although it is unclear whether the effects are mediated by common pathogenic mechanisms. In this manuscript, we report a genome-wide survey of histone acetylation in neurulation stage embryos from mouse pregnancies with different metabolic conditions: maternal diabetes, and maternal consumption of a high fat content diet. We find that maternal diabetes, and independently, exposure to high-fat diet, are associated with increases and decreases of H3 and H4 histone acetylation in the embryo. Intriguingly, changes of H3K27 acetylation marks are significantly enriched near genes known to cause neural tube defects in mouse mutants. These data suggest that epigenetic changes in response to diet and metabolic condition may contribute to increased risk for neural tube defects in diabetic and obese pregnancies. Importantly, the responses to high-fat diet and maternal diabetes were distinct, suggesting that perturbed embryonic development under these conditions is mediated by different molecular pathways. This conclusion is supported by morphometric analyses that reveal a trend for maternal diabetes to delay embryonic development in the C57BL/6 strain, while high-fat diet appears to be associated with accelerated development. Taken together, our results link changes in histone acetylation to metabolic conditions during pregnancy, and implicate distinct epigenetic mechanisms in susceptibility to neural tube defects under conditions of maternal diabetes and obesity.

Mechanism of the mitogenic influence of hyperinsulinemia

Either endogenous or exogenous hyperinsulinemia in the setting of insulin resistance promotes phosphorylation and activation of farnesyltransferase, a ubiquitous enzyme that farnesylates Ras protein. Increased availability of farnesylated Ras at the plasma membrane enhances mitogenic responsiveness of cells to various growth factors, thus contributing to progression of cancer and atherosclerosis. This effect is specific to insulin, but is not related to the type of insulin used. Stimulatory effect of hyperinsulinemia on farnesyltransferase in the presence of insulin resistance represents one potential mechanism responsible for mitogenicity and atherogenicity of insulin.

Diabetic embryopathy: a role for the epigenome?

Embryonic development under adverse conditions, such as maternal diabetes or obesity during pregnancy, constitutes a major risk factor for birth defects, as well as for long-term health consequences and disease susceptibility in the offspring. While contributions from epigenetic changes have been invoked previously to explain the long-term changes in terms of developmental programming, we here review how maternal metabolism may directly affect the embryonic epigenome in relationship to teratogenic processes. We consider four epigenetic modalities--DNA methylation, non-coding RNA, transcription factors, and histone modifications--and their contribution to epigenetic memory, and discuss how epigenomic changes may mediate the altered control of embryonic gene expression brought about by maternal diabetes. In combination, the epigenomic modalities serve to define transcription-permissive domains of the genome, resulting in distinct epigenomic landscapes in different developmental cell types. We evaluate experimental approaches to characterize the epigenome in adverse pregnancy conditions, highlighting the role of next-generation sequencing on the technological side, while emphasizing the necessity to study defined cell populations in terms of biologic impact. Finally, we outline the challenges in moving from findings that correlate epigenomics to developmental phenotypes to scenarios that establish teratogenic causality.

Mitogenic action of insulin: friend, foe or 'frenemy'?

Either endogenous or exogenous hyperinsulinaemia in the setting of insulin resistance promotes phosphorylation and activation of farnesyltransferase, a ubiquitous enzyme that farnesylates Ras proteins. Increased availability of farnesylated Ras at the plasma membrane enhances mitogenic responsiveness of cells to various growth factors, thus contributing to progression of cancer and atherosclerosis. This effect is specific to insulin, but is not related to the type of insulin used. The stimulatory effect of hyperinsulinaemia on farnesyltransferase in the presence of insulin resistance represents one potential mechanism responsible for mitogenicity and atherogenicity of insulin.

Translocation of H-Ras and its implications in the development of diabetic retinopathy

H-Ras, a small molecular weight G-protein, undergoes post-translational modifications enabling its translocation from cytosol to the membrane. Hyperglycemia increases apoptosis of retinal capillary cells via activation of H-Ras, which can be ameliorated by farnesylation inhibitors. Our aim is to investigate the mechanism of retinal H-Ras activation in diabetes. H-Ras and Raf-1 were quantified in the retinal membrane and cytosol fractions obtained from streptozotocin-induced diabetes rats, and the role of post-translation modification was determined by investigating the effect of simvastatin on diabetes-induced alterations. The effect of H-Ras-siRNA on membrane translocation and apoptosis was also determined in bovine retinal endothelial cells (BRECs). Diabetes increased expressions of H-Ras and Raf-1 in the retinal membranes, and simvastatin prevented such translocation. Glucose-exposure of BRECs increased membrane H-Ras expression and H-Ras-siRNA prevented this translocation, and also decreased their apoptosis. Thus, membrane translocation of H-Ras is a plausible mechanism responsible for accelerated apoptosis of retinal capillary cells in diabetes.

Diabetes regulates small molecular weight G-protein, H-Ras, in the microvasculature of the retina: implication in the development of retinopathy

Retinopathy, a largely microvascular complication, affects over 80% of patients with diabetes for 20 years. The purpose of this study is to investigate the effect of diabetes on the activation of H-Ras, a small molecular weight G-protein that regulates cell fate, in the retinal microvessels. Microvessels were prepared from freshly isolated retina from streptozotocin diabetic rats or 30% galactose-fed rats by hypotonic lysis method. Ras activation was quantified by Raf-1 binding assay, and the activation of the signaling proteins, Raf-1 and mitogen activated protein (MAP) kinase, by quantifying their gene transcripts (RTPCR) and/or by protein expression (western blot). Two months of diabetes or experimental galactosemia activated H-Ras (Raf-binding assay) in the retinal microvessels by over 40% and 70% respectively compared to the values obtained from normal rat retinal microvessels. In the same diabetic rats the gene transcripts of H-Ras and its effector protein Raf-1 were elevated by 30% and 135% respectively with their protein expressions elevated by about 25% each, and this was paralleled by similar increases in the protein expressions of H-Ras and Raf-1 in experimentally galactosemic rats. Diabetes increased the gene expression of Ras-Raf-1 downstream signaling protein MAP kinase by over 50%, and that of nuclear transcriptional factor by 25-30%. This activation of H-Ras in retinal microvessels implies that its signaling pathway, in part, could be contributing to the microvascular pathology characteristic of diabetic retinopathy. Comparable activation of H-Ras and its signaling cascade in the retinal microvessels from experimentally galactosemic rats suggests that H-Ras activation is not due to insulin deficiency. Regulation of Ras function could provide important target in the complex approach to inhibit the pathogenesis of diabetic retinopathy.

Recent observations on the regulation of fetal metabolism by glucose

Glucose is the principal energy substrate for the the fetus and is essential for normal fetal metabolism and growth. Fetal glucose metabolism is directly dependent on the fetal plasma glucose concentration. Fetal glucose utilization is augmented by insulin produced by the developing fetal pancreas in increasing amounts as gestation proceeds, which enhances glucose utilization among the insulin-sensitive tissues (skeletal muscle, liver, heart, adipose tissue) that increase in mass and thus glucose need during late gestation. Glucose-stimulated insulin secretion increases over gestation. Both insulin secretion and insulin action are affected by prevailing glucose concentrations and the amount and activity of tissue glucose transporters. In cases of intrauterine growth restriction (IUGR), fetal weight-specific tissue glucose uptake rates and glucose transporters are maintained or increased, while synthesis of amino acids into protein and corresponding insulin-IGF signal transduction proteins are decreased. These observations demonstrate the mixed phenotype of the IUGR fetus that includes enhanced glucose utilization capacity, but diminished protein synthesis and growth. Thus, the fetus has considerable capacity to adapt to changes in glucose supply by relatively common and understandable mechanisms that regulate fetal metabolism and growth and could underlie certain later life metabolic disorders such as insulin resistance, obesity and diabetes mellitus.

Effects of acute hyperinsulinemia on insulin signal transduction and glucose transporters in ovine fetal skeletal muscle

To test the effects of acute fetal hyperinsulinemia on the pattern and time course of insulin signaling in ovine fetal skeletal muscle, we measured selected signal transduction proteins in the mitogenic, protein synthetic, and metabolic pathways in the skeletal muscle of normally growing fetal sheep in utero. In experiment 1, 4-h hyperinsulinemic-euglycemic clamps were conducted in anesthetized twin fetuses to produce selective fetal hyperinsulinemia-euglycemia in one twin and euinsulinemia-euglycemia in the other. Serial skeletal muscle biopsies were taken from each fetus during the clamp and assayed by Western blot for selected insulin signal transduction proteins. Tyrosine phosphorylation of the insulin receptor, insulin receptor substrate-1, and the p85 subunit of phosphatidylinositol 3-kinase doubled at 30 min and gradually returned to control values by 240 min. Phosphorylation of extracellular signal-regulated kinase 1,2 was increased fivefold through 120 min of insulin infusion and decreased to control concentration by 240 min. Protein kinase B phosphorylation doubled at 30 min and remained elevated throughout the study. Phosphorylation of p70 S6K increased fourfold at 30, 60, and 120 min. In the second experiment, a separate group of nonanesthetized singleton fetuses was clamped to intermediate and high hyperinsulinemic-euglycemic conditions for 1 h. GLUT4 increased fourfold in the plasma membrane at 1 h, and hindlimb glucose uptake increased significantly at the higher insulin concentration. These data demonstrate that an acute increase in fetal plasma insulin concentration stimulates a unique pattern of insulin signal transduction proteins in intact skeletal muscle, thereby increasing pathways for mRNA translation, glucose transport, and cell growth.

Potential contributory role of H-Ras, a small G-protein, in the development of retinopathy in diabetic rats

Hyperglycemia is thought to be the underlying factor in the development of diabetic retinopathy, but the mechanisms involved remain partially understood. Diabetes increases oxidative stress, and reactive oxygen species affect the interactions between a small-molecular- weight G-protein, H-Ras, and several of its effector proteins. The purpose of this study was to examine the regulatory role of H-Ras in glucose-induced apoptosis of retinal endothelial cells. The expressions of H-Ras and its effector protein (Raf-1) were compared in the retina obtained from diabetic rats (2-8 months' duration) and age-matched normal rats and in retinal endothelial cells exposed to high-glucose medium. The effect of inhibition of H-Ras function on glucose-induced capillary cell death and the potential involvement of oxidative stress in diabetes-induced activation of H-Ras were also determined. The expressions of H-Ras and Raf-1 were increased in the retina in diabetes, and antioxidant therapy prevented diabetes-induced increased protein and mRNA expressions. The inhibitors of Ras farnesylation inhibited glucose-induced nitric oxides and apoptosis in isolated retinal endothelial cells. Thus, the results suggest that functional activation of H-Ras might be one of the signaling steps involved in glucose-induced capillary cell apoptosis and supports the role of H-Ras in the development of retinopathy in diabetes.

Dominant negative alpha-subunit of farnesyl- and geranylgeranyl-transferase I inhibits insulin-induced differentiation of 3T3-L1 pre-adipocytes

OBJECTIVE

To investigate whether the expression of a dominant negative (DN) farnesyl- and geranygeranyl-transferase I (FTase/GGTase I) alpha-subunit in 3T3-L1 pre-adipocytes can inhibit insulin's ability to induce differentiation.

DESIGN

3T3-L1 pre-adipocytes were stably transfected with vector alone or vector expressing a mutated DN FTase/GGTase I alpha-subunit (S60A)(S62A) and incubated in serum-free medium in the absence and presence of insulin.

MEASUREMENTS

Various assays were performed to determine the effect of DN FTase/GGTase I alpha-subunit expression in 3T3-L1 pre-adipocyte on insulin-induced DNA synthesis, cell count, phosphorylation of the FTase/GGTase I alpha-subunit, FTase and GGTase I activity, amounts of prenylated p21Ras and RhoA, phosphorylation of MAP kinase and Akt, and differentiation to mature fat cells.

RESULTS

Expression of DN FTase/GGTase I alpha-subunit inhibited insulin's ability to increase DNA synthesis, cell count, FTase and GGTase I activity, amounts of prenylated p21Ras and RhoA, and magnitude of phosphorylation of MAP kinase. Expression of DN FTase/GGTase I alpha-subunit in 3T3-L1 pre-adipocytes was without effect on insulin-induced Akt phosphorylation.

CONCLUSION

Expression of DN FTase/GGTase I alpha-subunit inhibits insulin-induced differentiation of 3T3-L1 pre-adipocytes to mature adipocytes, and thus could indicate potential therapeutic avenues to assuage the deleterious effects of obesity and type 2 diabetes.

Dominant negative alpha-subunit of FTase inhibits effects of insulin and IGF-I in MCF-7 cells

We recently designed a dominant negative (DN) farnesyltransferase (FTase)/geranyl-gerahyltransferase I (GGTase I) alpha-subunit that when expressed in vascular smooth muscle cells decreased insulin-stimulated phosphorylation of FTase, FTase activity, amounts of farnesylated p21Ras, DNA synthesis, and cell migration. Currently, we explored the inhibitory effects of DN FTase/GGTase I alpha-subunit in MCF-7 cells on IGF-1- and insulin-stimulated DNA synthesis and cell proliferation. Expression of the DN FTase/GGTase I alpha-subunit completely blocked IGF-1- and insulin-stimulated BrdU incorporation and cell count. DN FTase/GGTase I alpha-subunit inhibited insulin-stimulated phosphorylation of FTase/GGTase I alpha-subunit, FTase and GGTase I activity, and prenylation of p21Ras and RhoA. Expression of DN FTase/GGTase I alpha-subunit diminished IGF-1- and insulin-stimulated phosphorylation of ERK (extracellular signal-regulated kinase), but had no effect on IGF-1- and insulin-stimulated phosphorylation of Akt. Taken together, these data suggest that DN FTase/GGTase I alpha-subunit can assuage the mitogenic effects of IGF-1 and insulin on MCF-7 breast cancer cells.