Glutathione <Emphasis Type="BoldItalic">S</Emphasis>-transferase P1 gene polymorphisms and susceptibility to coronary artery disease in a subgroup of north Indian population

The present study aimed to investigate the association of \(\hbox {g}.313\hbox {A}{>}\hbox {G}\) and \(\hbox {g}.341\hbox {C}{>}\hbox {T}\) polymorphisms of GSTP1 with coronary artery disease (CAD) in a subgroup of north Indian population. In the present case–control study, CAD patients (\(n = 200\)) and age-matched, sex-matched and ethnicity-matched healthy controls (\(n = 200\)) were genotyped for polymorphisms in GSTP1 using polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) method. Genotype distribution of \(\hbox {g}.313\hbox {A}{>}\hbox {G}\) and \(\hbox {g}.341\hbox {C}{>}\hbox {T}\) polymorphisms of GSTP1 gene was significantly different between cases and controls (\(P = 0.005\) and 0.024, respectively). Binary logistic regression analysis showed significant association of A/G (odds ratio (OR): 1.6, 95% CI: 1.08–2.49, \(P = 0.020\)) and G/G (OR: 3.1, 95% CI: 1.41–6.71, P \(=\) 0.005) genotypes of GSTP1 \(\hbox {g}.313\hbox {A}{\!>\!}\hbox {G}\), and C/T (OR: 5.8, 95% CI: 1.26–26.34, \(P = 0.024\)) genotype of GSTP1 \(\hbox {g}.341\hbox {C}{>}\hbox {T}\) with CAD. The A/G and G/G genotypes of \(\hbox {g}.313\hbox {A}{>}\hbox {G}\) and C/T genotype of \(\hbox {g}.341\hbox {C}{>}\hbox {T}\) conferred 6.5-fold increased risk for CAD (OR: 6.5, 95% CI: 1.37–31.27, \(P = 0.018\)). Moreover, the recessive model of GSTP1 \(\hbox {g}.313\hbox {A}{>}\hbox {G}\) is the best fit inheritance model to predict the susceptible gene effect (OR: 2.3, 95% CI: 1.11–4.92, \(P = 0.020\)). In conclusion, statistically significant associations of GSTP1 \(\hbox {g}.313\hbox {A}{>}\hbox {G}\) (A/G, G/G) and \(\hbox {g}.341\hbox {C}{>}\hbox {T}\) (C/T) genotypes with CAD were observed.     

Heterogeneous nanomechanical properties of type I collagen in longitudinal direction

Biomechanics and Modeling in Mechanobiology - Collagen is an abundant structural biopolymer in mammal vertebrates, providing structural support as well as mechanical integrity for connective...     

In vitro anti- biofilm and anti-bacterial activity of Sesbania grandiflora extract against Staphylococcus aureus

The main objective of this research is to investigate the anti-biofilm and anti-bacterial activity of Sesbania grandiflora (S. grandiflora) against Staphylococcus aureus. S. grandiflora extract were prepared and analyzed with UV –Vis spectroscopy, Fourier transform infrared spectroscopy, Dynamic light scattering. Biofilm forming pathogens were identified by congo-red assay. Quantification of Extracellular polymeric substance (EPS) particularly protein and carbohydrate were calculated. The efficacy of the herbal extract S. grandiflora and its inhibition against the pathogenic strain of S. aureus was also evaluated. The gradual decrease or disappearance of peaks reveals the reduction of protein and carbohydrate content in the EPS of S. aureus when treated with S. grandiflora. The antibacterial activity of S. grandiflora extract against the bacterial strain S. aureus showed that the extract were more active against the strain. To conclude, anti-biofilm and antibacterial efficacy of S. grandiflora plays a vital role over biofilm producing pathogens and act as a good source for controlling the microbial population.     

Facile synthesis, ex-vivo and in vitro screening of 3-sulfonamide derivative of 5-(4-chlorophenyl)-1-(2,4-dichlorophenyl)-4-methyl-1H-pyrazole-3-carboxylic acid piperidin-1-ylamide (SR141716) a potent CB1 receptor antagonist

Facile synthesis of biaryl pyrazole sulfonamide derivative of 5-(4-chlorophenyl)-1-(2,4-dichlorophenyl)-4-methyl-1H-pyrazole-3-carboxylic acid piperidin-1-ylamide (SR141716, 1) and an investigation of the effect of replacement of the –CO group in the compound 1 by the –SO₂ group in the aminopiperidine region is reported. Primary ex-vivo pharmacological testing and in vitro screening of sulfonamide derivative 2 showed the loss of CB1 receptor antagonism.     

Identification of the major TG4 cross‐linking sites in the androgen‐dependent SVS I exclusively expressed in mouse seminal vesicle

SVS I was exclusively expressed in seminal vesicle in which the protein was immunolocalized primarily to the luminal epithelium of mucosal folds. The developmental profile of its mRNA expression was shown to be androgen‐dependent, manifesting a positive correlation with the animal's maturation. There are 43 glutamine and 43 lysine residues in one molecule of SVS I, which is one of the seven major monomer proteins tentatively assigned on reducing SDS–PAGE during the resolution of mouse seminal vesicle secretion. Based on the fact that SVS I‐deduced protein sequence consists of 796 amino acid residues, we produced 7 recombinant polypeptide fragments including residues 1–78/F1, residues 79–259/F2, residues 260–405/F3, residues 406–500/F4, residues 501–650/F5, residues 651–715/F6, and residues 716–796/F7, and measured the covalent incorporation of 5‐(biotinamido)pentylamine (BPNH₂) or biotin‐TVQQEL (A25 peptide) to each of F1‐to‐F7 by type 4 transglutaminase (TG₄) from the coagulating gland secretion. F2 was active to a greater extent than the other fragments during the BPNH₂‐glutamine incorporation, and a relatively low extent of A25‐lysine cross link was observed with all of the seven fragments. The MS analysis of BPNH₂‐F2 conjugate identified Q²³² and Q²⁵⁴ as the two major TG₄ cross‐linking sites. This was substantiated by the result that much less BPNH₂ was cross‐linked to any one of the three F2 mutants, including Q232G and Q254G obtained from single‐site mutation, and Q232G/Q254G from double‐site mutation. J. Cell. Biochem. 107: 899–907, 2009. © 2009 Wiley‐Liss, Inc.     

Astrocytes are poised for lactate trafficking and release from activated brain and for supply of glucose to neurons

Brain is a highly-oxidative organ, but during activation, glycolytic flux is preferentially up-regulated even though oxygen supply is adequate. The biochemical and cellular basis of metabolic changes during brain activation and the fate of lactate produced within brain are important, unresolved issues central to understanding brain function, brain images, and spectroscopic data. Because in vivo brain imaging studies reveal rapid efflux of labeled glucose metabolites during activation, lactate trafficking among astrocytes and between astrocytes and neurons was examined after devising specific, real-time, sensitive enzymatic fluorescent assays to measure lactate and glucose levels in single cells in adult rat brain slices. Astrocytes have a 2- to 4-fold faster and higher capacity for lactate uptake from extracellular fluid and for lactate dispersal via the astrocytic syncytium compared to neuronal lactate uptake from extracellular fluid or shuttling of lactate to neurons from neighboring astrocytes. Astrocytes can also supply glucose to neurons as well as glucose can be taken up by neurons from extracellular fluid. Astrocytic networks can provide neuronal fuel and quickly remove lactate from activated glycolytic domains, and the lactate can be dispersed widely throughout the syncytium to endfeet along the vasculature for release to blood or other brain regions via perivascular fluid flow.     

Stabilization of the E* Form Turns Thrombin into an Anticoagulant

Previous studies have shown that deletion of nine residues in the autolysis loop of thrombin produces a mutant with an anticoagulant propensity of potential clinical relevance, but the molecular origin of the effect has remained unresolved. The x-ray crystal structure of this mutant solved in the free form at 1.55 Å resolution reveals an inactive conformation that is practically identical (root mean square deviation of 0.154 Å) to the recently identified E* form. The side chain of Trp²¹⁵ collapses into the active site by shifting >10 Å from its position in the active E form, and the oxyanion hole is disrupted by a flip of the Glu¹⁹²–Gly¹⁹³ peptide bond. This finding confirms the existence of the inactive form E* in essentially the same incarnation as first identified in the structure of the thrombin mutant D102N. In addition, it demonstrates that the anticoagulant profile often caused by a mutation of the thrombin scaffold finds its likely molecular origin in the stabilization of the inactive E* form that is selectively shifted to the active E form upon thrombomodulin and protein C binding.Serine proteases of the trypsin family are responsible for digestion, blood coagulation, fibrinolysis, development, fertilization, apoptosis, and immunity (1). Activation of the protease requires the transition from a zymogen form (2) and formation of an ion pair between the newly formed amino terminus of the catalytic chain and the side chain of the highly conserved residue Asp¹⁹⁴ (chymotrypsinogen numbering) next to the catalytic Ser¹⁹⁵. This ensures substrate access to the active site and proper formation of the oxyanion hole contributed by the backbone N atoms of Ser¹⁹⁵ and Gly¹⁹³ (3). The zymogen → protease conversion is classically associated with the onset of catalytic activity (3, 4) and provides a useful paradigm for understanding key features of protease function and regulation.Recent kinetic (5) and structural (6, 7) studies of thrombin, the key protease in the blood coagulation cascade (8), have drawn attention to a significant plasticity of the trypsin fold that impacts the function of the enzyme in a decisive manner. The active form of the protease, E, coexists with an inactive form, E*, that is distinct from the zymogen conformation (9). The E* form features a collapse of the 215–217 β-strand into the active site and a flip of the peptide bond between residues Glu¹⁹² and Gly¹⁹³ that disrupts the oxyanion hole. Importantly, the ion pair between Ile¹⁶ and Asp¹⁹⁴ remains intact, suggesting that E* is not equivalent to the zymogen form of the protease and that the E*-E equilibrium is established after the conversion from the zymogen form has taken place. Indeed, existing structures of the zymogen forms of trypsin (10), chymotrypsin (11), and chymase (12) feature a broken Ile¹⁶–Asp¹⁹⁴ ion pair but no collapse of the 215–217 β-strand. Stopped-flow experiments show that the E*-E conversion takes place on a time scale of <10 ms (5), as opposed to the much longer (100–1000 ms) time scale required for the zymogen-protease conversion (13, 14).The E* form is not a peculiarity of thrombin. The collapse of the 215–217 β-strand into the active site is observed in the inactive form of αI-tryptase (15), the high temperature requirement-like protease (16), complement factor D (17), granzyme K (18), hepatocyte growth factor activator (19), prostate kallikrein (20), and prostasin (21). A disrupted oxyanion hole is observed in complement factor B (22) and the arterivirus protease Nsp4 (23). The most likely explanation for the widespread occurrence of inactive conformations of trypsin-like proteases is that the E*-E equilibrium is a basic property of the trypsin fold that fine tunes activity and specificity once the zymogen → protease conversion has taken place (9).The new paradigm established by the E*-E equilibrium has obvious physiological relevance. In the case of complement factors, kallikreins, tryptase, and some coagulation factors must be kept to a minimum until binding of a trigger factor ensues. Stabilization of E* may afford a resting state of the protease waiting for action, as seen for other systems (24–28). For example, factor B is mostly inactive until binding of complement factor C3 unleashes catalytic activity at the site where amplification of C3 activation is most needed prior to formation of the membrane attack complex (29). Indeed, the crystal structure of factor B reveals a conformation with the oxyanion hole disrupted by a flip of the 192–193 peptide bond (22), as observed in the E* form of thrombin (6, 7).The allosteric equilibrium as shown in Scheme 1, involves the rates for the E* → E transition, k₁, and backward, k₋₁, that define the equilibrium constant r = k₋₁/k₁ = [E*]/[E] (5). The value of k_cat/K_m for an enzyme undergoing the E*-E equilibrium is as shown in Equation 1 (30), where s_E is the value of s for the E form, and obviously s_E* = 0. Likewise, the binding of an inhibitor to the enzyme undergoing the E*-E equilibrium is shown in Equation 2, where K_E is the value of the equilibrium association constant K for the E form, and K_E* = 0. As the value of r increases upon stabilization of E*, the values of s and K in Equations 1 and 2 decrease without limits. Hence, stabilization of E* has the potential to completely abrogate substrate hydrolysis (s → 0) or inhibitor binding (K → 0). However, binding of a suitable cofactor could restore activity by triggering the E* → E transition. This suggests a simple explanation for the anticoagulant profile observed in a number of thrombin mutants that have poor activity toward all physiological substrates but retain activity toward the anticoagulant protein C in the presence of the cofactor thrombomodulin (31–34). Here we report evidence that stabilization of E* provides a molecular mechanism to turn thrombin into an anticoagulant.     

Kinetic and structural studies of the role of the active site residue Asp235 of human pyridoxal kinase

Pyridoxal kinase catalyzes the phosphorylation of pyridoxal (PL) to pyridoxal 5′-phosphate (PLP). A D235A variant shows 7-fold and 15-fold decreases in substrate affinity and activity, respectively. A D235N variant shows ∼2-fold decrease in both PL affinity and activity. The crystal structure of D235A (2.5 Å) shows bound ATP, PL and PLP, while D235N (2.3 Å) shows bound ATP and sulfate. These results document the role of Asp235 in PL kinase activity. The observation that the active site of PL kinase can accommodate both ATP and PLP suggests that formation of a ternary Enz·PLP·ATP complex could occur in the wild-type enzyme, consistent with severe MgATP substrate inhibition of PL kinase in the presence of PLP.     

Mechanism of the Anticoagulant Activity of Thrombin Mutant W215A/E217A

The thrombin mutant W215A/E217A (WE) is a potent anticoagulant both in vitro and in vivo. Previous x-ray structural studies have shown that WE assumes a partially collapsed conformation that is similar to the inactive E* form, which explains its drastically reduced activity toward substrate. Whether this collapsed conformation is genuine, rather than the result of crystal packing or the mutation introduced in the critical 215–217 β-strand, and whether binding of thrombomodulin to exosite I can allosterically shift the E* form to the active E form to restore activity toward protein C are issues of considerable mechanistic importance to improve the design of an anticoagulant thrombin mutant for therapeutic applications. Here we present four crystal structures of WE in the human and murine forms that confirm the collapsed conformation reported previously under different experimental conditions and crystal packing. We also present structures of human and murine WE bound to exosite I with a fragment of the platelet receptor PAR1, which is unable to shift WE to the E form. These structural findings, along with kinetic and calorimetry data, indicate that WE is strongly stabilized in the E* form and explain why binding of ligands to exosite I has only a modest effect on the E*-E equilibrium for this mutant. The E* → E transition requires the combined binding of thrombomodulin and protein C and restores activity of the mutant WE in the anticoagulant pathway.Thrombin is the pivotal protease of blood coagulation and is endowed with both procoagulant and anticoagulant roles in vivo (1). Thrombin acts as a procoagulant when it converts fibrinogen into an insoluble fibrin clot, activates clotting factors V, VIII, XI, and XIII, and cleaves PAR1² and PAR4 on the surface of human platelets thereby promoting platelet aggregation (2). Upon binding to thrombomodulin, a receptor present on the membrane of endothelial cells, thrombin becomes unable to interact with fibrinogen and PAR1 but increases >1,000-fold its activity toward the zymogen protein C (3). Activated protein C generated from the thrombin-thrombomodulin complex down-regulates both the amplification and progression of the coagulation cascade (3) and acts as a potent cytoprotective agent upon engagement of EPCR and PAR1 (4).The dual nature of thrombin has long motivated interest in dissociating its procoagulant and anticoagulant activities (5–12). Thrombin mutants with anticoagulant activity help rationalize the bleeding phenotypes of several naturally occurring mutations and could eventually provide new tools for pharmacological intervention (13) by exploiting the natural protein C pathway (3, 14, 15). Previous mutagenesis studies have led to the identification of the E217A and E217K mutations that significantly shift thrombin specificity from fibrinogen toward protein C relative to the wild type (10–12). Both constructs were found to display anticoagulant activity in vivo (10, 12). The subsequent discovery of the role of Trp-215 in controlling the balance between pro- and anti-coagulant activities of thrombin (16) made it possible to construct the double mutant W215A/E217A (WE) featuring >19,000-fold reduced activity toward fibrinogen but only 7-fold loss of activity toward protein C (7). These properties make WE the most potent anticoagulant thrombin mutant engineered to date and a prototype for a new class of anticoagulants (13). In vivo studies have revealed an extraordinary potency, efficacy, and safety profile of WE when compared with direct administration of activated protein C or heparin (17–19). Importantly, WE elicits cytoprotective effects (20) and acts as an antithrombotic by antagonizing the platelet receptor GpIb in its interaction with von Willebrand factor (21).What is the molecular mechanism underscoring the remarkable functional properties of WE? The mutant features very low activity toward synthetic and physiological substrates, including protein C. However, in the presence of thrombomodulin, protein C is activated efficiently (7). A possible explanation is that WE assumes an inactive conformation when free but is converted into an active form in the presence of thrombomodulin. The ability of WE to switch from inactive to active forms is consistent with recent kinetic (22) and structural (23, 24) evidence of the significant plasticity of the trypsin fold. The active form of the protease, E, coexists with an inactive form, E*, that is distinct from the zymogen conformation (25). Biological activity of the protease depends on the equilibrium distribution of E* and E, which is obviously different for different proteases depending on their physiological role and environmental conditions (25). The E* form features a collapse of the 215–217 β-strand into the active site and a flip of the peptide bond between residues Glu-192 and Gly-193, which disrupts the oxyanion hole. These changes have been documented crystallographically in thrombin and other trypsin-like proteases such as αI-tryptase (26), the high temperature requirement-like protease (27), complement factor D (28), granzyme K (29), hepatocyte growth factor activator (30), prostate kallikrein (31), prostasin (32, 33), complement factor B (34), and the arterivirus protease nsp4 (35). Hence, the questions that arise about the molecular mechanism of WE function are whether the mutant is indeed stabilized in the inactive E* form and whether it can be converted to the active E form upon thrombomodulin binding.Structural studies of the anticoagulant mutants E217K (36) and WE (37) show a partial collapse of the 215–217 β-strand into the active site that abrogates substrate binding. The collapse is similar to, but less pronounced than, that observed in the structure of the inactive E* form of thrombin where Trp-215 relinquishes its hydrophobic interaction with Phe-227 to engage the catalytic His-57 and residues of the 60-loop after a 10 Å shift in its position (24). These more substantial changes have been observed recently in the structure of the anticoagulant mutant Δ146–149e (38), which has proved that stabilization of E* is indeed a molecular mechanism capable of switching thrombin into an anticoagulant. It would be simple to assume that both E217K and WE, like Δ146–149e, are stabilized in the E* form. However, unlike Δ146–149e, both E217K and WE carry substitutions in the critical 215–217 β-strand that could result into additional functional effects overlapping with or mimicking a perturbation of the E*-E equilibrium. A significant concern is that both structures suffer from crystal packing interactions that may have biased the conformation of side chains and loops near the active site (24). The collapsed structures of E217K and WE may be artifactual unless validated by additional structural studies where crystal packing is substantially different.To address the second question, kinetic measurements of chromogenic substrate hydrolysis by WE in the presence of saturating amounts of thrombomodulin have been carried out (37), but these show only a modest improvement of the k_cat/K_m as opposed to >57,000-fold increase observed when protein C is used as a substrate (7, 37). The modest effect of thrombomodulin on the hydrolysis of chromogenic substrates is practically identical to that seen upon binding of hirugen to exosite I (37) and echoes the results obtained with the wild type (39) and other anticoagulant thrombin mutants (7, 9, 10, 12, 38). That argues against the ability of thrombomodulin alone to significantly shift the E*-E equilibrium in favor of the E form. Binding of a fragment of the platelet receptor PAR1 to exosite I in the D102N mutant stabilized in the E* form (24) does trigger the transition to the E form (23), but evidence that a similar long-range effect exists for the E217K or WE mutants has not been presented.In this study we have addressed the two unresolved questions about the mechanism of action of the anticoagulant thrombin mutant WE. Here we present new structures of the mutant in its human and murine versions, free and bound to a fragment of the thrombin receptor PAR1 at exosite I. The structures are complemented by direct energetic assessment of the binding of ligands to exosite I and its effect on the E*-E equilibrium.