Vanadium and insulin: Partners in metabolic regulation.

Since the 1970s, the biological role of vanadium compounds has been discussed as insulin-mimetic or insulin-enhancer agents. The action of vanadium compounds has been investigated to determine how they influence the insulin signaling pathway. Khan and coworkers proposed key proteins for the insulin pathway study, introducing the concept "critical nodes". In this review, we also considered critical kinases and phosphatases that participate in this pathway, which will permit a better comprehension of a critical node, where vanadium can act: a) insulin receptor, insulin receptor substrates, and protein tyrosine phosphatases; b) phosphatidylinositol 3'-kinase, 3-phosphoinositide-dependent protein kinase and mammalian target of rapamycin complex, protein kinase B, and phosphatase and tensin homolog; and c) insulin receptor substrates and mitogen-activated protein kinases, each node having specific negative modulators. Additionally, leptin signaling was considered because together with insulin, it modulates glucose and lipid homeostasis. Even in recent literature, the possibility of vanadium acting against metabolic diseases or cancer is confirmed although the mechanisms of action are not well understood because these critical nodes have not been systematically investigated. Through this review, we establish that vanadium compounds mainly act as phosphatase inhibitors and hypothesize on their capacity to affect kinases, which are critical to other hormones that also act on common parts of the insulin pathway.

Molecular and Cellular Mechanisms of Cytotoxic Activity of Vanadium Compounds against Cancer Cells.

Discovering that metals are essential for the structure and function of biomolecules has given a completely new perspective on the role of metal ions in living organisms. Nowadays, the design and synthesis of new metal-based compounds, as well as metal ion binding components, for the treatment of human diseases is one of the main aims of bioinorganic chemistry. One of the areas in vanadium-based compound research is their potential anticancer activity. In this review, we summarize recent molecular and cellular mechanisms in the cytotoxic activity of many different synthetic vanadium complexes as well as inorganic salts. Such mechanisms shall include DNA binding, oxidative stress, cell cycle regulation and programed cell death. We focus mainly on cellular studies involving many type of cancer cell lines trying to highlight some new significant advances.

In vitro Studies of Antitumor Activity of Vanadium Complexes with Orotic and Glutamic Acids / Estudos in vitro da Atividade Antitumoral de Complexos de Vanádio com Ácidos Órotico e Glutâmico / Estudios in vitro de la Actividad Antitumoral de Complejos de Vanadio con Ácidos Orótico y Glutámico

Introduction: Three vanadium complexes with orotic and glutamic acids, in their anion forms, were prepared and their in vitro cytotoxicity toward human lung fibroblasts (MRC-5), human hepatocellular carcinoma (HepG2) and human colorectal adenocarcinoma (Caco-2) are reported. Objective: Describe the synthesis and characterization of new vanadium complexes with orotic and glutamic acids, and test its antitumor activity against HepG2 and Caco-2. Method: The complexes were formulated as VO (oro), VO (α-glu) and VO (γ-glu) based on chemical, thermogravimetric analyses and infrared spectra. Results: Resazurin assay demonstrates its cytotoxicity against the HepG2 and Caco-2 cell lines with the IC50 ranging from 7.90 to 44.56 µmol.L-1. The cytotoxicity profiles indicate that the tumoral lines show more activity than the cells MRC-5, with selectivity indexes ranging from 1.58 to 8.96. Conclusion: The three complexes had better in vitro activity than cisplatin for both normal and cancer cell lines. The IC50 values are two to six times better for the cancer cell ines and five to seven times better for the normal cell lines. This study indicates that the complexes obtained are promising candidates for antitumor drugs.

Introdução: Foram preparados três complexos de vanádio com ácidos orótico e glutâmico, em suas formas aniônicas, e foi testada sua citotoxicidade in vitro para fibroblastos pulmonares humanos (MRC-5), carcinoma hepatocelular humano (HepG2) e adenocarcinoma colorretal humano (Caco-2). Objetivo: Descrever a síntese e caracterização de novos complexos de vanádio com ácidos orótico e glutâmico e testar sua atividade antitumoral contra HepG2 e Caco-2. Método: Os complexos foram formulados como VO (oro), VO (α-glu) e VO (γ-glu) com base em análises químicas, termogravimétricas e espectros no infravermelho. Resultados: O ensaio de resazurina demonstrou sua citotoxicidade contra as linhagens celulares HepG2 e Caco-2 com o IC50 variando de 7,90 a 44,56 µmol.L-1. Os perfis de citotoxicidade indicam que as linhas tumorais apresentam maior atividade que as células MRC-5, com índices de seletividade variando de 1,58 a 8,96. Conclusão: Os três complexos tiveram melhor atividade in vitro do que a cisplatina, tanto para linhagens celulares normais como cancerosas. Os valores de IC50 são de duas a seis vezes melhores para as linhagens celulares cancerosas e de cinco a sete vezes melhores para as linhagens celulares normais. Este estudo indica que os complexos obtidos são promissores candidatos a fármacos antitumorais.

Introducción: Tres complejos de vanadio con ácidos orótico y glutámico, en sus formas aniónicas, fueram preparados. Su citotoxicidad in vitro hacia los fibroblastos pulmonares humanos (MRC-5), el carcinoma hepatocelular humano (HepG2) y el adenocarcinoma colorrectal humano (Caco-2) son reportados. Objetivo: Los principales objetivos de este trabajo son describir la síntesis y caracterización de nuevos complejos de vanadio con ácidos orótico y glutámico y probar su actividad antitumoral contra el HepG2 y el Caco-2. Método: Los complejos fueron formulados como VO (oro), VO (α-glu) y VO (γ-glu) basados en análisis químicos, termogravimétricos y espectros infrarrojos. El ensayo de resazurina demuestra su citotoxicidad contra las líneas celulares HepG2 y Caco-2 con el IC50 que van de 7,90 a 44,56 µmol.L-1. Los perfiles de citotoxicidad indican que las líneas tumorales presentan mayor actividad que los MRC-5, con índices de selectividad que van de 1,58 a 8,96. Conclusión: Los tres complejos tuvieron mejor actividad in vitro que el cisplatino, tanto para líneas celulares normales como para líneas celulares cancerosas. Los valores del IC50 son de dos a seis veces mejores para las líneas celulares de cáncer y de cinco a siete veces mejores para las líneas celulares normales. Este estudio indica que los complejos obtenidos son candidatos prometedores para fármacos antitumorales.

[The effect of vanadium compounds on carbohydrate and lipid metabolism disorders].

At this stage in the development of nutriciological science, it has not been established if biologically active substances are essential to the human body; however, an explanation of the physiological role of minor biologically active substances is necessary to clarify the qualitative composition of Nutrioma. Of particular interest is the transition metal, vanadium. Adding vanadium to the diet of animals with induced or genetically determined type 2 diabetes mellitus normalizes glucose and blood insulin levels, reduces insulin resistance, promotes ß-cell regeneration, and has a beneficial effect on lipid metabolism. Clinical studies of the effectiveness of vanadium are not convincing, in most part, because of their insufficient duration. The review briefly discusses the main mechanisms of the action of vanadium compounds. Therapeutic doses of vanadium compounds may overlap with toxic doses. Organic vanadium compounds could be used in significantly lower doses. The main problem with the possible use of vanadium compounds in antidiabetic therapy is the balance between their beneficial effects and the connected risks of side effects.

Vanadium compounds induced damage of human umbilical vein endothelial cells and the protective effect of berberine.

This study was conducted to investigate the damage caused by vanadium compounds and to explore the protective effects of berberine (BBR) in human umbilical vein endothelial cells (HUVECs). BBR is a biologically active small molecule found in Coptis rhizome, a remedy used in traditional Chinese medicine to treat diabetes. BBR has also been shown to lower blood glucose in diabetic patients. MTT assay was performed to observe the influence of bis(acetylacetonato)-oxidovanadium [VO(acac)2] or sodium metavanadate (NaVO3) and BBR on viability of HUVECs. The monolayer permeability of the HUVECs was assessed by measuring the transendothelial electrical resistance (TER). The endothelial nitric oxide synthase (eNOS) activity was detected by ELISA. Flow cytometry was performed to detect the generation of reactive oxygen species (ROS). The results showed that the viability of HUVECs was decreased by treatment with vanadium compounds 50-400 µM in a concentration-dependent manner, while 0.01-1 µM BBR effectively protected HUVECs from the inhibitory effects of vanadium compounds on cell viability. Also 100 and 200 µM VO(acac)2 induced high permeability and decreased eNOS activity in HUVECs. While 0.01-1 µM BBR showed no improvement in the permeability, and failed to reverse the VO(acac)2-induced changes of eNOS activity, but BBR treatment increased the eNOS activity in control cells. The addition of 200 µM VO(acac)2 significantly induced ROS generation in HUVECs, while 0.01 or 0.1 µM BBR reversed the change of ROS. In summary, BBR has protective effects in HUVECs damage induced by vanadium compounds, which is not mediated by eNOS, but related to reduced intracellular ROS.

Bis(acetylacetonato)-oxidovanadium(IV) and sodium metavanadate inhibit cell proliferation via ROS-induced sustained MAPK/ERK activation but with elevated AKT activity in human pancreatic cancer AsPC-1 cells.

In this study, the antiproliferative effect of bis(acetylacetonato)-oxidovanadium(IV) and sodium metavanadate and the underlying mechanisms were investigated in human pancreatic cancer cell line AsPC-1. The results showed that both exhibited an antiproliferative effect through inducing G2/M cell cycle arrest and can also cause elevation of reactive oxygen species (ROS) levels in cells. Moreover, the two vanadium compounds induced the activation of both PI3K/AKT and MAPK/ERK signaling pathways dose- and time-dependently, which could be counteracted with the antioxidant N-acetylcysteine. In the presence of MEK-1 inhibitor, the degradation of Cdc25C, inactivation of Cdc2 and accumulation of p21 were relieved. However, the treatment of AKT inhibitor did not cause any significant effect. Therefore, it demonstrated that the ROS-induced sustained MAPK/ERK activation rather than AKT contributed to vanadium compounds-induced G2/M cell cycle arrest. The current results also exhibited that the two vanadium compounds did not induce a sustained increase of ROS generation, but the level of ROS reached a plateau instead. The results revealed that an intracellular feedback loop may be against the elevated ROS level induced by vanadate or VO(acac)2, evidenced by the increased GSH content, the unchanged level at the expression of antioxidant enzymes. Therefore, vanadium compounds can be regarded as a novel type of anticancer drugs through the prolonged activation of MAPK/ERK pathway but retained AKT activity. The present results provided a proof-of-concept evidence that vanadium-based compounds may have the potential as both antidiabetic and antipancreatic cancer agents to prevent or treat patients suffering from both diseases.

Vanadium compounds for the treatment of human diabetes mellitus: A scientific curiosity? A review of thirty years of research.

In the second part of the 1980s, and in the 1990s, a number of investigators demonstrated -mainly in streptozotocin-induced (STZ) diabetic rats-that the vanadate and vanadyl forms of vanadium possessed a number of insulin-like effects in various cells. It was hypothesized that oral vanadium could be an alternative treatment to parenteral insulin in the therapy of diabetes mellitus. However, the long-term and/or chronic administration of vanadium compounds should also mean tissue vanadium accumulation and risks of toxicity. The purpose of this review was to revise the current-state-of-the-art on the use of vanadium in the treatment of human diabetes. It has been conducted more than three decades after the first report on the beneficial insulin-mimetic effects of oral vanadium administration in STZ-diabetic rats. Although the antidiabetic effects of vanadium in STZ-diabetic rodents are well supported, in the few studies on human patients with positive results, that are available in the literature, vanadium compounds were administered during very short periods. We conclude that vanadium administration for the treatment of human diabetes is misplaced.

Effect of Vanadyl Rosiglitazone, a New Insulin-Mimetic Vanadium Complexes, on Glucose Homeostasis of Diabetic Mice.

Diabetes has been cited as the most challenging health problem in the twenty-first century. Accordingly, it is urgent to develop a new type of efficient and low-toxic antidiabetic medication. Since vanadium compounds have insulin-mimetic and potential hypoglycemic activities for type 1 and type 2 diabetes, a new trend has been developed using vanadium and organic ligands to form a new compound in order to increase the intestinal absorption and reduce the toxicity of vanadium compound. In the current investigation, a new organic vanadium compounds, vanadyl rosiglitazone, was synthesized and determined by infrared spectra. Vanadyl rosiglitazone and three other organic vanadium compounds were administered to the diabetic mice through oral administration for 5 weeks. The results of mouse model test indicated that vanadyl rosiglitazone could regulate the blood glucose level and relieve the symptoms of polydipsia, polyphagia, polyuria, and weight loss without side effects and was more effective than the other three organic vanadium compounds including vanadyl trehalose, vanadyl metformin, and vanadyl quercetin. The study indicated that vanadyl rosiglitazone presents insulin-mimetic activities, and it will be a good potential candidate for the development of a new type of oral drug for type 2 diabetes.

Perspectives for vanadium in health issues.

Vanadium is omnipresent in trace amounts in the environment, in food and also in the human body, where it might serve as a regulator for phosphate-dependent proteins. Potential vanadium-based formulations--inorganic and coordination compounds with organic ligands--commonly underlie speciation in the body, that is, they are converted to vanadate(V), oxidovanadium(IV) and to complexes with the body's own ligand systems. Vanadium compounds have been shown to be potentially effective against diabetes Type 2, malign tumors including cancer, endemic tropical diseases (such as trypanosomiasis, leishmaniasis and amoebiasis), bacterial infections (tuberculosis and pneumonia) and HIV infections. Furthermore, vanadium drugs can be operative in cardio- and neuro-protection. So far, vanadium compounds have not yet been approved as pharmaceuticals for clinical use.

Comparison of toxicity and teratogenic effects of salen and vo-salen on chicken embryo.

OBJECTIVES: The toxic and teratogenic effects of salen (C16H16N2O2) and salen vanadium oxide (VOS) (C16H14N2O3V) were evaluated against chicken embryos along with chicken hepatic and fibroblastic cells in vitro cultures. METHODS: Salen and VOS complexes were injected in the following concentrations: 5, 10, 20, 40, 80, 160, and 300 µM/egg for salen and 7.5, 15, 75, 120, 150, 240, and 300 µM/egg for VOS. In order to screen for skeletal malformations, the alizarin red clearing and staining method was employed. For studying the cytotoxic effects of these compounds, hepatic and fibroblastic cells were cultured and treated. RESULTS: Our results show that injecting salen with various concentrations leads to a significant increase in embryonic mortality. Skeletal and morphological malformations resulting from salen injections included ectopic viscera and club foot. Our results show that embryonic mortality increased relative to the control group. In addition, alizarin red staining showed skeletal malformations like deletion of caudal vertebrae. DISCUSSION: Our comparison showed that salen was a stronger teratogen than VOS, which may be due roles of the vanadium element, whose derivatives show physiological particulars and at low concentrations plays anticancer specifications without toxic effect. CONCLUSION: Results show that chicken embryos were sensitive to the toxicity of salen and VOS, and these compounds can affect the growth and ossification of the chicken embryos. Moreover, the cytotoxicity of salen and VOS shows that the viability of both salen and VOS-treated cells significantly decreased in a dose-dependent manner.

Thirty years through vanadium chemistry.

The relevance of vanadium in biological systems is known for many years and vanadium-based catalysts have important industrial applications, however, till the beginning of the 80s research on vanadium chemistry and biochemistry did not receive much attention from the scientific community. The understanding of the broad bioinorganic implications resulting from the similarities between phosphate and vanadate(V) and the discovery of vanadium dependent enzymes gave rise to an enormous increase in interest in the chemistry and biological relevance of vanadium. Thereupon the last 30years corresponded to a period of enormous research effort in these fields, as well as in medicinal applications of vanadium and in the development of catalysts for use in fine-chemical synthesis, some of these inspired by enzymatic active sites. Since the 80s my group in collaboration with others made contributions, described throughout this text, namely in the understanding of the speciation of vanadium compounds in aqueous solution and in biological fluids, and to the transport of vanadium compounds in blood plasma and their uptake by cells. Several new types of vanadium compounds were also synthesized and characterized, with applications either as prospective therapeutic drugs or as homogeneous or heterogenized catalysts for the production of fine chemicals. The developments made are described also considering the international context of the evolution of the knowledge in the chemistry and bioinorganic chemistry of vanadium compounds during the last 30years. This article was compiled based on the Vanadis Award presentation at the 9th International Vanadium Symposium.

Targeting PTEN using small molecule inhibitors.

PTEN (phosphatase and tensin homologue deleted on chromosome 10) is well known as a tumour suppressor. It's PI(3,4,5)P3 lipid phosphatase activity is an important counteracting mechanism in PI 3-kinase (phosphoinositide 3-kinase) signalling. Furthermore, PTEN lies upstream of Akt kinase, a key enzyme in insulin signalling regulating glucose uptake and cell growth. Therefore, PTEN has recently gained attention as a valuable drug target for the treatment of diabetes, stroke, cardiac infarct and fertility. This review summarizes the use of small molecules as PTEN inhibitors. Currently available methodologies and techniques for accessing PTEN inhibition in vitro and in cellulo will be discussed.

Neuroprotective effect of PTEN inhibitor BPV on cerebral ischemia-reperfusion injury in rats and its mechanism / 国际脑血管病杂志

Objective To investigated the neuroprotective effect of PTEN inhibitor BPV on cerebral ischemia-reperfusion injury in rats and its mechanism. Methods Male Sprague-Dawley rats were used to induce a reperfusion model of middle cerebral artery occlusion for 1 h. During the reperfusion, the BPV solution (0. 2 mg/kg daily) or the equal volume of saline was injected intraperitonealy immediately. The neurological deficit scores were conducted at day 1, 3,5, and 7 after ischemia-reperfusion. At day 4, triphenyl tetrazolium chloride staining was used to assess cerebral infarction volume. Enzyme-linked immunosorbent assay was used to detect the levels of interleukin 10 (IL-10) and tumor necrosis factor α(TNF-α) in cortical ischemic border zones. Real-time quantitative polymerase chain reaction was used to detect the expression level of PTEN mRNA. Western blotting was used to detect the expression levels of PI3K, Akt, and p-GSK-3β. At day 7, Bielschowsky silver staining was used to detect the axonal distribution in the ischemic border zone of the striatum. Immunohistochemical staining was used to detect the expression of myelin basic protein (MBP). Results At day 4 after ischemia-reperfusion, the infarct volume (32. 27% ± 1. 71% vs. 45. 49% ± 2. 12% ; P < 0. 001), TNF-α concentration in the cortical ischemic border zones (134. 17 ± 10. 38 pg/ml vs. 264. 17 ± 24. 84 pg/ml; P < ), and PTEN mRNA level (1. 19 ± 0. 08 vs. 2. 50 ± 0. 06; P < 0. 001) in the rats of the BPV group were al significantly lower than those of the normal saline group. The IL-10 concentration (186. 83 ± 10. 83 pg/ml vs. 147. 83 ± 11. 62 pg/ml; P < 0. 001), and the expression levels of PI3K (0. 43 ± 0. 08 vs. 0. 26 ± 0. 06; P = 0. 004), Akt (0. 52 ± 0. 05 vs. 0. 40 ± 0. 04;P = 0. 001), and p-GSK-3β (0. 75 ± 0. 08 vs. 0. 38 ± 0. 06; P < 0. 001) were al significantly higher than those of the normal saline group. At day 7 after ischemia-reperfusion, the neurological deficit score (4. 83 ± 0. 41 vs. 6. 33 ± 0. 52; P < 0. 001) in the rats of the BPV group was significantly lower than that of the normal saline group. The axon densities in the ischemic border zones (35. 51% ± 2. 45% vs. 25. 31% ± 2. 79% ; P < 0. 001) and the expression level of MBP (32. 56% ± 3. 46% vs. 27. 81% ± 4. 18% ; P = 0. 037) were significantly higher than those of the normal saline group. Conclusions BPV has neuroprotective effect for cerebral ischemia-reperfusion injury in rats. Its mechanism may be associated with the up-regulation of PTEN downstream proteins PI3K, Akt and p-GSK-3β expression to regulate inflammatory mediators and reduce the inflammatory response.

Antidiabetic Bis-Maltolato-OxoVanadium(IV): conversion of inactive trans- to bioactive cis-BMOV for possible binding to target PTP-1B.

The postulated transition of Bis-Maltolato-OxoVanadium(IV) (BMOV) from its inactive trans- into its cis-aquo-BMOV isomeric form in solution was simulated by means of computational molecular modeling. The rotational barrier was calculated with DFT - B3LYP under a stepwise optimization protocol with STO-3G, 3-21G, 3-21G*, and 6-31G ab initio basis sets. Our computed results are consistent with reports on the putative molecular mechanism of BMOV triggering the insulin-like cellular response (insulin mimetic) as a potent inhibitor of the protein tyrosine phosphatase-1B (PTP-1B). Initially, trans-BMOV is present in its solid dosage form but in aqueous solution, and during oral administration, it is readily converted into a mixture of "open-type" and "closed-type" complexes of cis-aquo-BMOV under equilibrium conditions. However, in the same measure as the "closed-type" complex binds to the cytosolic PTP-1B, it disappears from solution, and the equilibrium shifts towards the "closed-type" species. In full accordance, the computed binding mode of cis-BMOV is energetically favored over sterically hindered trans-BMOV. In view of our earlier report on prodrug hypothesis of vanadium organic compounds the present results suggest that cis-BMOV is the bioactive species.