Getting to the heart of the matter: CCN2 plays a role in cardiomyocyte hypertrophy

Connective tissue growth factor (CTGF/CCN2) is overexpressed in diabetes. Diabetic rats possess myocardial and cardiomyocyte hypertrophy. In a recent report, Wang and colleagues (Am J Physiol Cell Physiol. 2009 Jul 22. [Epub ahead of print]) show that CCN2 directly mediates cardiomyocyte hypertrophy as well as that induced by high glucose and fatty acid. CCN2 acted via the TrkA receptor. These data are the subject of this commentary, and emphasize that CCN2 may be an excellent target for therapy in diabetes.     

MODY 2: Mutation identification and molecular ancestry in a Brazilian family

Maturity Onset Diabetes of the Young (MODY) is a heterogeneous group of genetic diseases characterized by a primary defect in insulin secretion and hyperglycemia, non-ketotic disease, monogenic autosomal dominant mode of inheritance, age at onset less than 25 years, and lack of auto-antibodies. It accounts for 2–5% of all cases of non-type 1 diabetes. MODY subtype 2 is caused by mutations in the glucokinase (GCK) gene. In this study, we sequenced the GCK gene of two volunteers with clinical diagnosis for MODY2 and we were able to identify four mutations including one for a premature stop codon (c.76C>T). Based on these results, we have developed a specific PCR-RFLP assay to detect this mutation and tested 122 related volunteers from the same family. This mutation in the GCK gene was detected in 21 additional subjects who also had the clinical features of this genetic disease. In conclusion, we identified new GCK gene mutations in a Brazilian family of Italian descendance, with one due to a premature stop codon located in the second exon of the gene. We also developed a specific assay that is fast, cheap and reliable to detect this mutation. Finally, we built a molecular ancestry model based on our results for the migration of individuals carrying this genetic mutation from Northern Italy to Brazil.     

Synthesis,biological evaluation and in silico studies of 5-(3-methoxybenzylidene)thiazolidine-2,4-dione analogues as PTP1B inhibitors

PTP1B (protein tyrosine phosphatase 1B) dephosphorylates the insulin receptor substrate and thus acts as a negative regulator of the insulin and leptin signalling pathway. Recently, it has been considered as a new therapeutic target of intervention for the treatment of type2 diabetes. A series of aryl/alkylsulfonyloxy-5-(3-methoxybenzylidene)thiazolidine-2,4-dione derivatives were synthesized, screened in vitro for their PTP1B inhibitory activity and in vivo for anti-hyperglycaemic activity. Docking results further helped in understanding the nature of interactions governing the binding mode of ligands inside the active site of PTP1B. Among the synthesized compounds, 13 and 16 were found to be potent PTP1B inhibitors having IC₅₀ of 7.31 and 8.73 μM respectively. Significant lowering of blood glucose level was observed in some of the synthesized compounds in in vivo study.     

STZ诱导的糖尿病模型小鼠肾脏的上皮-间质转分化研究

目的:探讨STZ诱导的糖尿病小鼠肾脏发生上皮-间质转分化(EMT)的情况。方法:将80只C57BL小鼠随机分为正常对照组(NC组)和糖尿病组(DM组),每组40只。DM组小鼠用1%STZ(streptozotocin,链脲佐菌素)溶液按60mg/kg体质量的剂量进行腹腔注射,每天1次,连续6天。NC组小鼠平行腹腔注射同等体积0.1mol/L的柠檬酸钠缓冲液。再将成模小鼠随机分为A、B批次,A批次用于动态观察生存率、小鼠体质量及随机血糖的监测;B批次用于在造模后第4、8、12周末观察肾组织的病理变化,并用Western blot、免疫荧光染色的方法观察肾组织中EMT标志蛋白α-SMA和E-cadherin的表达。结果:STZ诱导的糖尿病模型小鼠出现糖尿病典型症状如多饮、多尿等,血糖持续在高水平状态,体质量增长缓慢。在造模后12周末,DM组小鼠较NC组小鼠累积生存率显著降低,两组比较差异具有统计学意义(P0.001)。在造模后的第8周末,DM组小鼠肾脏出现明显的病理改变,到第12周末时,绝大部分肾小管上皮细胞被梭形的肌成纤维细胞取代,肾小球空泡,基底膜增厚。造模后的第4、8、12周末时,DM组小鼠E-cadherin表达量均显著低于NC组小鼠(P=0.004,0.026,0.004);而在第8和12周末时,DM组α-SMA表达量显著升高(P=0.009,0.015)。在第12周末,肾组织冰冻切片E-cadherin和α-SMA、免疫荧光染色结果与上述结果一致。结论:STZ诱导的糖尿病模型小鼠有较典型的糖尿病临床改变,且肾组织发生了EMT。     

Signaling steps in the induction of genomic damage by insulin in colon and kidney cells

Diabetes mellitus (DM), a disease with almost 350 million people affected worldwide, will be the seventh leading cause of death by 2030. Diabetic patients develop various types of complications, among them an increased rate of malignancies. Studies reported the strong correlation between DM and several cancer types, of which colon and kidney cancers are the most common. Hyperinsulinemia, the high insulin blood level characteristic of early diabetes type 2, was identified as a risk factor for cancer development. In previous studies, we showed that an elevated insulin level can induce oxidative stress, resulting in DNA damage in colon cells in vitro and in kidney cells in vitro and in vivo. In the present study, we elucidate the signaling pathway of insulin-mediated genotoxicity, which is effective through oxidative stress induction in colon and kidney. The signaling mechanism is starting by phosphorylation of the insulin and insulin-like growth factor-1 receptors, followed by activation of phosphatidylinositide 3-kinase (PI3K), which in turn activates AKT. Subsequently, mitochondria and nicotinamide adenine dinucleotide phosphate oxidase (NADPH) isoforms (Nox1 and Nox4 in colon and kidney, respectively) are activated for reactive oxygen species (ROS) production, and the resulting excess ROS can attack the DNA, causing DNA oxidation. We conclude that hyperinsulinemia represents an important risk factor for cancer initiation or progression as well as a target for cancer prevention in diabetic patients.     

Vanadate enhances insulin-receptor binding in gestational diabetic human placenta

Although vanadium is found abundantly in animal and plant kingdoms its biological effects are not clear. Vanadate compounds have been shown to normalize blood glucose levels in streptozotocin treated rats, enhance glucose oxidation and improve the sensitivity to insulin by enhanced receptor binding in rat adipocytes. The aim of the present study was to investigate the effect of vanadate, at high (0–8 mmol l^?1) and low (0–1·0 mmol l^?1) physiological concentrations, on [¹²⁵I]-insulin binding in the placenta of three groups of pateints, namely from normal (N) controls, gestational diabetics (GDM) and women with risk factors in their medical history for developing diabetes mellitus (RF). Vanadate at low concentrations (0·2–0·6 mmol l^?1) enhanced the maximal binding 2-fold in GDM placenta but only increased (up to 1·2-fold) the binding slightly at high cncentrations (5 mmol l^?1). However with placenta from normal or women at risk, vanadate increased the [¹²⁵I]-insulin binding up to 1·2-fold both at low and high concentrations. Thus it appears that vanadate augements insulin binding in the placenta from women with gestational diabetes mellitus.     

The insulin secretory action of novel polycyclic guanidines: Discovery through open innovation phenotypic screening,and exploration of structure–activity relationships

We report the discovery of the glucose-dependent insulin secretogogue activity of a novel class of polycyclic guanidines through phenotypic screening as part of the Lilly Open Innovation Drug Discovery platform. Three compounds from the University of California, Irvine, 1–3, having the 3-arylhexahydropyrrolo[1,2-c]pyrimidin-1-amine scaffold acted as insulin secretagogues under high, but not low, glucose conditions. Exploration of the structure–activity relationship around the scaffold demonstrated the key role of the guanidine moiety, as well as the importance of two lipophilic regions, and led to the identification of 9h, which stimulated insulin secretion in isolated rat pancreatic islets in a glucose-dependent manner.     

Evidence Against Impaired Brain Microtubule Protein Polymerization at High Glucose Concentrations or During Diabetes Mellitus

Previous studies suggest that brain microtubule protein exposed to high glucose levels or isolated from diabetic rats can become glucosylated and that this impairs GTP-induced microtubule polymerization. We set out to extend that investigation to define the mechanistic basis for inhibition of microtubule assembly during diabetes or on incubation at high glucose levels. Rat and bovine brain microtubule protein was purified by cycles of polymerization/depolymerization. When microtubules were incubated for 1 h in either buffer or buffer containing glucose (up to 165 mM), there was no difference in polymerization, a finding contrary to the earlier study. Other rats were injected with vehicle or streptozotocin (90 mg/kg) to induce diabetes as evidenced by serum glucose in excess of 300 mg%, and at 4 weeks, brain microtubule protein was isolated by the polymerization cycling method. Again, there was no difference in the amount or purity of isolated microtubule protein between control or diabetic rats. We also observed no increase in microtubule glucosylation, and GTP-induced polymerization in vitro was indistinguishable for protein derived from brains of normal rats and rats with diabetes as measured by turbidity or electron microscopy. Our results suggest that in vitro incubation with glucose or in vivo elevation of glucose during diabetes fails to impair microtubule polymerization, pointing to other mechanisms for the neuropathy associated with diabetes.     

Homology modeling and explicit membrane molecular dynamics simulation to delineate the mode of binding of thiazolidinediones into FFAR1 and the mechanism of receptor activation

Free fatty acid receptor 1 (FFAR1) is a member of a previously characterized cluster of orphan G protein-coupled receptors (GPCRs). Later, this orphan receptor was identified as a target of medium- to long-chain free fatty acids in β-cells of the pancreas. Administration of FFAR1 agonists has been proved to potentiate glucose-stimulated insulin secretion from pancreatic β-cells. It was reported that some thiazolidinediones (TZDs), the best studied PPARγ agonists, are also able to stimulate FFAR1 in a dose-dependent manner. In the present study, a homology model of the human FFAR1 was constructed and inserted into a pre-equilibrated DPPC/TIP3P membrane system. This system was then simulated for 20 ns in complex with the FFAR1 agonist GW9085, as well as rosiglitazone and pioglitazone. We noticed that the salt bridge between Glu172 and Arg258 and the H bond between Glu145 and His153 could be responsible for the stabilization of the receptor in the inactive state. Moreover, we described for the first time the binding mode of TZDs in the binding site of FFAR1. The thiazolidinedione head forms a hydrogen bonding network with the critical polar residues in the binding site, Arg258 and Asn244, while the rest of the molecule is embedded into the receptor hydrophobic pocket. Based on this modeling study, we arrived at a proposal of the pharmacophore required for binding to both PPARγ and FFAR1. Insights gained from this investigation should provide future directions for the design of novel dual acting antidiabetic agents.