Active-site directed peptide l-Phe-d-His-l-Leu inhibits angiotensin converting enzyme activity and dexamethasone-induced hypertension in rats.

Hypertension is the fundamental cause of cardiovascular and cerebrovascular disorders. Several natural and synthetic peptides are being used as antihypertensive agents, which target angiotensin converting enzyme (ACE), the master regulator of angiotensin (Ang) II production. In this study, we have evaluated ACE-inhibitory potential of the tripeptide l-Phenylalanyl-d-Histidyl-l-Leucine (l-Phe-d-His-l-Leu) in vitro and its antihypertensive effect in rat model of dexamethasone-induced hypertension. l-Phe-d-His-l-Leu was custom-designed by changing the configuration of penultimate amino acid residue (histidine) from C-terminal of Ang I, the site at which ACE acts upon and generates Ang II. l-Phe-d-His-l-Leu effectively inhibited ACE activity in a dose-dependent and competitive manner with an IC50 of 53.32 ± 0.13 nmol/L. Both fluorescence spectra and circular dichroism data revealed the direct interaction between l-Phe-d-His-l-Leu and ACE. In addition, molecular docking studies revealed the strong interaction of l-Phe-d-His-l-Leu with the critical active site amino acid residues of ACE. Further, the administration of l-Phe-d-His-l-Leu resulted in decrease in blood pressure (142 ± 3 mmHg) compared to dexamethasone alone group (167 ± 2 mmHg). Besides, l-Phe-d-His-l-Leu decreased the levels of circulating Ang II, and reduced fibrosis in heart and kidney, as evidenced by decreases in collagen deposition. Thus, the strategy of incorporation of d-amino acids in ACE-inhibitory peptides could be valuable in the development of antihypertensive drugs.

Genes Controlling 2-deoxyglucose Induced Lysis and Formation of Reactive Oxygen Species in Schizosaccharomyces pombe.

Schizosaccharomyces pombe cells of strains each carrying a deletion of one of the genes snf5, ypa1, pho7 and pas1 and of a strain overexpressing gene odr1, have been previously shown to grow in presence of the toxic glucose analogue 2-deoxyglucose (2-DG). Here we report that these genes control 2-DG induced lysis and are, with the exception of odr1, also involved in control of formation of reactive oxygen species (ROS) upon exposure of cells to H2O2. Lysis of deletion strains, but not of strain overexpressing odr1, is dependent on glucose concentration of the medium whereas ROS formation is glucose independent.

MTNR1B gene polymorphisms and susceptibility to Type 2 Diabetes: A pilot study in South Indians.

Type 2 Diabetes (T2D) is the major health concern in the Indian subcontinent. A genome-wide association study carried out with non-diabetic Indians showed association of MTNR1B variants with fasting glucose. MTNR1B mediates the effect of melatonin on insulin secretion. In light of the growing importance of MTNR1B in the etiology of T2D, we sought to test its association with the disease in the south Indian type 2 diabetics. Five single nucleotide polymorphisms of MTNR1B (rs10830962, rs10830963, rs3847554, rs1387153 and rs2166706) were genotyped in 346 T2D patients and 341 non-diabetic controls. None of the SNPs differed significantly between patients and controls with respect to allele and genotype frequencies. Linear regression analysis after adjustment for age, sex and BMI showed a significant positive association of rs3847554 with fasting glucose under recessive model (ß=14.98, p=0.012). Haplotypes constituted by minor alleles of rs3847554, rs1387153, rs2166706, rs10830963 and major allele of rs10830962 showed significant positive correlation with fasting glucose (p<0.05). Though the results obtained are suggestive of MTNR1B role in T2D etiology, they need to be confirmed with much larger sample sizes.

Vanillin analog--vanillyl mandelic acid, a novel specific inhibitor of snake venom 5'-nucleotidase.

Snake venom 5'-nucleotidase (5'NUC) plays a very important role in envenomation strategies; however, apart from its modulation of hemostatic functions, its other pharmacological effects are not yet well characterized. Several studies have used specific inhibitors of enzyme toxins as a biochemical or pharmacological tool to characterize or establish its mechanism of action. We report here for the first time vanillin mandelic acid (VMA), an analog of vanillin, to potentially, selectively, and specifically inhibit venom 5'NUC activity among other enzymes present in venoms. VMA is much more potent in inhibiting 5'NUC activity than vanillyl acid (VA). The experimental results obtained are in good agreement with the in silico molecular docking interaction data. Both VA and VMA are competitive inhibitors as evident by the inhibition-relieving effect upon increasing the substrate concentration. VMA also dose-dependently inhibited the anticoagulant effect in Naja naja venom. In this study, we report novel non-nucleoside specific inhibitors of snake venom 5'NUC and experimentally demonstrate their involvement in the anticoagulant activity of N. naja venom. Hence, we hypothesize that VMA can be used as a molecular tool to evaluate the role of 5'NUC in snake envenomation and to develop prototypes and lead compounds with potential therapeutic applications against snake bites.

Homology modeling, molecular dynamics and atomic level interaction study of snake venom 5' nucleotidase.

5' Nucleotidase (5' NUC) is a ubiquitously distributed enzyme known to be present in snake venoms (SV) that is responsible primarily for causing dysregulation of physiological homeostasis in humans by inducing anticoagulant effects and by inhibiting platelet aggregation. It is also known to act synergistically with other toxins to exert a more pronounced anti-coagulant effect during envenomation. Its structural and functional role is not yet ascertained clearly. The 3D structure of snake venom 5' nucleotidase (SV-5' NUC) is not yet known and was predicted by us for the first time using a comparative homology modeling approach using Demansia vestigiata protein sequence. The accuracy and stability of the predicted SV-5' NUC structure were validated using several computational approaches. Key interactions of SV-5' NUC were studied using experimental studies/molecular docking analysis of the inhibitors vanillin, vanillic acid and maltol. All these inhibitors were found to dock favorably following pharmacologically relevant absorption, distribution, metabolism and excretion (ADME) profiles. Further, atomic level docking interaction studies using inhibitors of the SV-5' NUC active site revealed amino acid residues Y65 and T72 as important for inhibitor-(SV-5' NUC) interactions. Our in silico analysis is in good agreement with experimental inhibition results of SV-5' NUC with vanillin, vanillic acid and maltol. The present study should therefore play a guiding role in the experimental design of new SV-5' NUC inhibitors for snake bite management. We also identified a few pharmacophoric features essential for SV-5' NUC inhibitory activity that can be utilized further for the discovery of putative anti-venom agents of therapeutic value for snake bite management.

Correlation between Cholinesterase and Paraoxonase 1 Activities:Case Series of Pesticide Poisoning Subjects.

INTRODUCTION: Acute exposure to pesticide due to suicidal poisoning is the most extensive cause of pesticide exposure, compared with all other causes including agricultural or industrial exposure. Organophosphate (OP) and carbamate group of pesticides can inhibit acetylcholinesterase; on the other hand, paraoxonase1 can detoxify organophosphate poisoning by hydrolyzing organophosphate metabolites. METHODS: We have compared the serum paraoxonase1 status and cholinesterase activity of subjects who attempted to commit suicide by consuming OP pesticide. Cholinesterase and paraoxonase1 activity were measured spectrophotometrically using butyrylthiocholine and phenyl acetate as substrates, respectively. RESULTS: A positive correlation was found between serum paraoxonase1 activity and cholinesterase activity among pesticide consumed subjects. CONCLUSION: Our results suggest that subjects with higher paraoxonase1 activity may have a better chance of detoxifying the lethal effect of acute organophosphate poisoning.

Blood glucose determination: plasma or serum?

BACKGROUND: Blood glucose determination is one of the most common clinical diagnostic tests. Often, blood is collected in a field station and analysis is carried out in a remote laboratory. Because blood cells can continue to metabolize glucose, the time of determination of blood glucose after drawing the blood is important. METHOD: In order to test the relative suitability of plasma and serum for blood glucose determination, fluoride plasma and Ethylene Diamine Tetra Acetic acid (EDTA) plasma were compared with the serum of the same patient. The analyses were carried out within 10 min of drawing the blood and, thereafter, with a gap of 4 hr and 8 hr. RESULTS: Serum gave values lower than fluoride plasma by 1.15%. Although this difference was statistically significant, it may not be physiologically relevant. Hence, serum may be used for blood glucose determination with an error of 1.15%. On storing the sample at room temperature for 8 hr, the serum glucose value decreased by 8%. Even fluoride plasma had 4.3% lower glucose. CONCLUSION: Hence, blood glucose should be determined within as short a time as possible after drawing the blood.

Anti-venom potential of aqueous extract of stem bark of Mangifera indica L. against Daboia russellii (Russell's viper) venom.

Several plant extracts rich in pharmacologically active compounds have shown to antagonize venom of several species. Mangifera indica has been used against snakebite by the traditional healers. However, there is paucity of scientific data in support. In this study, we evaluated the antivenom potential of aqueous extract of stem bark of M. indica against D. russellii venom-induced pharmacological effects such as life myotoxicity, edema, LD50 etc. The extract inhibited the phospholipase, protease, hyaluronidase, 5'nucleotidase, ATPase and alkaline phosphomonoesterase activities with varying IC50 values. It significantly inhibited both metalloproteases and serine proteases activities. Further, the extract significantly reduced the myotoxicity of the venom, as evident by the reduction of serum creatin kinase and lactate dehydrogenase activities. Though the extract completely inhibited in vitro PLA2 activity, it was unable to completely inhibit in situ hemolytic and in vivo edema-inducing activities, usually brought about by PLA2s. In lethality studies, co-injection of the venom preincubated with the extract showed higher protection than the independent injection of venom, followed by the extract in the mice. However, in both the cases the extract -a cocktail of inhibitors significantly increased the survival time, when compared to that of mice injected (i.p) with the venom alone. These results encourage further studies on the potential use of cocktail of inhibitors in improving the treatment of snake envenomation. Further, this study substantiates the use of M. indica as an antidote against snakebite by the traditional healers.

The pharmacological role of phosphatases (acid and alkaline phosphomonoesterases) in snake venoms related to release of purines - a multitoxin.

Snake venom components, acting in concert in the prey, cause their immobilization and initiate digestion. To achieve this, several hydrolytic enzymes of snake venom have evolved to interfere in various physiological processes, which are well defined. However, hydrolytic enzymes such as phosphatases (acid and alkaline phosphomonoesterases) are less studied and their pharmacological role in venoms is not clearly defined. Also, they show overlapping substrate specificities and have other common biochemical properties causing uncertainty about their identity in venoms. The near-ubiquitous distribution of these enzymes in venoms, suggests a significant role for these enzymes in envenomation. It appears that these enzymes may play a central role in liberating purines (mainly adenosine) - a multitoxin and through the action of purines help in prey immobilization. However, apart from this, these enzymes could also possess other pharmacological activities as venom enzymes have been evolved to interfere in diverse physiological processes. This has not been verified by pharmacological studies using purified enzymes. Further research is needed to biologically characterize these enzymes in snake venoms, such that their role in venom is clearly established.

Evidence for existence of venom 5' nucleotidase in multiple forms through inhibition of concanavalin A.

Pharmacologically active 5' nucleotidase is a ubiquitously distributed enzyme in snake venoms. In this study the effect of concanavalin A (Con-A) on different snake venoms 5' nucleotidase activity is tested in order to know the protein nature which will ultimately help in purification of the enzyme with high yield. Con-A inhibited Naja naja, Naja kauthia, Naja melanoleuca, Naja naja sputatrix, Agistrodon halys blomhoffii, Bothrops asper and Oxyranus scutellas venom 5' nucleotidase activity at different concentrations. This indicates the presence of glycopart in the protein, thus glycoprotein in nature. Vipera russellii, Vipera plaestenae, Agistrodon contratrix, Bitis orientis, Echis carinatus and Trimeresures malabaricus was not inhibited by Con-A, indicating absence of glycopart in the protein. This study for the first time shows existence of 5' nucleotidase in multimeric forms.

The pharmacological role of nucleotidases in snake venoms.

Several hydrolytic enzymes of snake venom have evolved to interfere in various physiological processes, which are well defined. However, hydrolytic enzymes such as nucleotidases (5'nucleotidase, ATPase, and ADPase) are less studied and their pharmacological role in venoms is not clearly defined. Very few studies have shown the pharmacological importance of these endogenous purine release related enzymes in venoms. The near-ubiquitous distribution of these enzymes in venoms, suggests a significant role for these enzymes in envenomation. It is suggested that their major function is in the generation of purines (mainly adenosine)-a multitoxin. Therefore, it appears that these enzymes play a central role in liberating adenosine and through the action of adenosine help in prey immobilization. However, apart from this, these enzymes could also possess other pharmacological activities. Further research is needed to biologically characterize these enzymes in snake venoms, such that their role in venom is clearly established.

Plasmid loss in plasmid-carrying strains of Escherichia coli treated with phenoxazines and an approach to study their DNA binding properties.

The effect of subinhibitory concentrations of 2-trifluoromethyl-N(10)-substituted phenoxazines on plasmid-coded antibiotic resistance in Escherichia coli was investigated. Phenoxazine treatment resulted in the loss of resistance markers to an extent of 8-63% in all the strains tested, and the disappearance of plasmid DNA in phenoxazine sensitive colonies was evidenced by agarose gel electrophoresis. The resistant strains were sensitized in the presence of phenoxazines with a concomitant reduction in the MIC (minimum inhibitory concentration) values. The UV, fluorescence spectral, and ethidium bromide displacement agarose gel assay methods revealed that phenoxazines are intercalated with plasmid DNA. Progressive addition of DNA led to a significant reduction in the peak intensity of the absorption maximum of phenoxazine derivative. Further, destabilization of ethidium bromide-DNA complex as seen from fluorescence microscopy in the presence of phenoxazines was observed. The potency of phenoxazines to sensitize the resistant organisms follows the order butyl > propyl > acetyl derivatives.

Anticoagulant effect of Naja naja venom 5'nucleotidase: demonstration through the use of novel specific inhibitor, vanillic acid.

The snake venom proteins affect hemostasis by either advancing/delaying blood coagulation. Apart from proteases and phospholipase A(2)s (PLA(2)s), 5'nucleotidase is known to affect hemostasis by inhibiting platelet aggregation. In this study, the possible involvement of Naja naja venom 5'nucleotidase in mediating anticoagulant affect is evaluated. Vanillic acid selectively and specifically inhibited 5'nucleotidase activity among other enzymes present in N. naja venom. It is a competitive inhibitor as evident of inhibition relieving upon increased substrate concentration. Vanillic acid dose dependently inhibited the anticoagulant effect of N. naja venom up to 40%. This partial involvement of 5'nucleotidase in mediating anticoagulant effect is substantiated by concanavalin-A (Con-A) inhibition studies. Con-A, competitively inhibited in vitro protease and 5'nucleotidase activity up to 100%. However, it did not exhibit inhibitory activity on PLA(2). The complete inhibition of anticoagulant effect by Con-A upon recalcification time suggests the participation of both 5'nucleotidase and protease in mediating anticoagulant effect of N. naja venom. Vanillic acid and Con-A inhibition studies together suggest that probably 5'nucleotidase interacts with one or more factors of intrinsic pathway of blood coagulation to bring about anticoagulant effect. Thus, this study for the first time demonstrates the involvement of 5'nucleotidase in mediating N. naja venom anticoagulant effect.

Inhibition of calmodulin-dependent cyclic AMP phosphodiesterase by phenoxazines.

Phenoxazine derivatives were examined for their ability to inhibit the calmodulin-mediated activation of phosphodiesterase, which is based on the hydrolysis of cAMP to AMP by phosphodiesterase in the presence or absence of inhibitor, followed by quantitative analysis by HPLC method. Anticalmodulin activity of phenoxazines with respect to substitution at C-2 position follows the order: 2-trifluoromethyl>2-chloro>unsubstituted phenoxazines. The interaction of phenoxazines with calmodulin using fluorescence spectroscopy has been performed. Binding study showed that calmodulin has two types of binding sites for phenoxazines. One is high affinity binding site (Kd value 0.07-0.46 microM) and the other, a low affinity binding site (Kd value 0.7-34.5 microM). The change in secondary structure of calmodulin upon binding to phenoxazines was studied by circular dichroism (CD) method, which showed that the percentage of helicity decreased with an extensive change in tertiary structure of calmodulin. Kinetic analysis of the phenoxazine-calmodulin interaction showed that phenoxazines competitively inhibited the activation of phosphodiesterase without affecting Vmax. Thus, these studies showed a good correlation between the ability of phenoxazines to block the activation of phosphodiesterase and their ability to bind to the activator.

Interaction of 2-chloro-N10-substituted phenoxazine with DNA and effect on DNA melting.

Five N10-substituted phenoxazines having different R groups and -Cl substitution at C-2 were found to bind to calf -thymus DNA and plasmid DNA with high affinity as seen from by UV and CD spectroscopy. The effect of phenoxazines on DNA were studied using DNA-ethidium bromide complexes. Upon addition of phenoxazines, the ethidium bromide dissociated from the complex with DNA. The binding of phenoxazines to plasmid PUC18 reduced ethidium bromide binding as seen from the agarose gel electrophoresis. Butyl, and propyl substituted phenoxazines were able to release more ethidium bromide compared with that of acetyl substitution. Addition of phenoxazines also enhanced melting temperature of DNA.