Energetics of hydrogen bond switch, residue burial and cavity analysis reveals molecular basis of improved heparin binding to antithrombin

Antithrombin III (ATIII) is the main inhibitor of the coagulation proteases like factor Xa and thrombin. Anticoagulant activity of ATIII is increased by several thousand folds when activated by vascular wall heparan sulfate proteoglycans (HSPGs) and pharmaceutical heparins. ATIII isoforms in human plasma, alpha-ATIII and beta-ATIII differ in the amount of glycosylation which is the basis of differences in their heparin binding affinity and function. Crystal structures and site directed mutagenesis studies have mapped the heparin binding site in ATIII, however the hydrogen bond switch and energetics of interaction during the course of heparin dependent conformational change remains largely unclear. An analysis of heparin bound conformational states of ATIII using PEARLS software showed that in heparin bound intermediate state, Arg 47 and Arg 13 residues make hydrogen bonds with heparin but in the activated conformation Lys 11 and Lys 114 have more hydrogen bond interactions. In the protease bound-antithrombin-pentasaccharide complex Lys 114, Pro 12 and Lys 125 form important hydrogen bonding interactions. The results showed that A-helix and N-terminal end residues are more important in the initial interactions but D-helix is more important during the latter stage of conformational activation and during the process of protease inhibition. We carried out the residue wise Accessible Surface Area (ASA) analysis of alpha and beta ATIII native states and the results indicated major differences in burial of residues from Ser 112 to Ser 116 towards the N-terminal end. This region is involved in the P-helix formation on account of heparin binding. A cavity analysis showed a progressively larger cavity formation during activation in the region just adjacent to the heparin binding site towards the C-terminal end. We hypothesize that during the process of conformational change after heparin binding beta form of antithrombin has low energy barrier to form D-helix extension toward N and C-terminal end as compared to alpha isoform.     

Variable chain conformations of renatured β‐glucan in dimethylsulfoxide/water mixture

We have firstly demonstrated the renaturation process of dissociated single chains of lentinan (s‐LNT) and the variable conformations of the renatured LNT (r‐LNT). The results from ultrasensitive differential scanning calorimetry and circular dichroism revealed that the variable structures including perfect triple helix, defective triple helix containing duplex segment, and single chains occurred in the renaturation of s‐LNT, depending on the renaturation time, solvent composition, molecular weight, and the mode of renaturation. When water was added into s‐LNT/dimethylsulfoxide (DMSO) to reach 95% (v/v), the classic low‐temperature intra‐triple‐helical conformational transition at ～10^°C (T₁) appeared within 4 h, indicative of a rapid reconstruction of triple helical structure. Besides, one newly endothermic peak at ～43^°C (T₂) simultaneously occurred, which was first ascribed to the melting of duplex segment in the imperfect triplex. The duplex stretches disappeared when DMSO reached 50%, in which single chains coexisted with triplex. Moreover, the duplex segment disappeared by slowly dropping water into s‐LNT/DMSO. This work suggested that the structure of r‐LNT could be controllable, and provided important information for their successful development and application in polymer and life science. © 2012 Wiley Periodicals, Inc. Biopolymers 97:988–997, 2012.     

Examination, by 1H-n.m.r. spectroscopy, of the binding of a synthetic, high-affinity heparin pentasaccharide to human antithrombin III

Binding of a synthetic, high-affinity heparin pentasaccharide and of intact heparin to both native and elastase-modified human antithrombin III have been examined by 1H-n.m.r. spectroscopy. The pentasaccharide perturbs many protein resonances in the same way as does intact heparin. There are, however, differences that seem to arise both from fewer contacts in the heparin binding-site when the pentasaccharide binds and from dissimilar conformational changes in the protein. The resonance of the H-2 atom of the histidine, considered to be the N-terminal residue and to be located in the heparin binding-site, is strongly perturbed by heparin binding both to native and modified antithrombin. The pentasaccharide has little effect on this histidine in either protein. Resonances from two of the remaining four histidine units are sensitive to longer-range conformational changes, and show differences between binding of the two heparin species both in native and modified ATIII. It is concluded that the pentasaccharide only partly fills the heparin binding-site and does not produce a conformational change identical to that caused by intact heparin. This is particularly significant as regards the mechanism of action of heparin, because the synthetic pentasaccharide activates ATIII towards Factor Xa, but not towards thrombin.     

Manduca sexta hemolymph protease-1, activated by an unconventional non-proteolytic mechanism,mediates immune responses

Tissue damage or pathogen invasion triggers the auto-proteolysis of an initiating serine protease (SP), rapidly leading to sequential cleavage activation of other cascade members to set off innate immune responses in insects. Recently, we presented evidence that Manduca sexta hemolymph protease-1 zymogen (proHP1) is a member of the SP system in this species, and may activate proHP6. HP6 stimulates melanization and induces antimicrobial peptide synthesis. Here we report that proHP1 adopts an active conformation (*) to carry out its function, without a requirement for proteolytic activation. Affinity chromatography using HP1 antibodies isolated from induced hemolymph the 48 kDa proHP1 and also a 90 kDa band (detected by SDS-PAGE under reducing conditions) containing proHP1 and several serpins, as revealed by mass spectrometric analysis. Identification of tryptic peptides from these 90 kDa complexes included peptides from the amino-terminal regulatory part of proHP1, indicating that proHP1* was not cleaved, and that it had formed a complex with the serpins. As suicide inhibitors, serpins form SDS-stable, acyl-complexes when they are attacked by active proteases, indicating that proHP1* was catalytically active. Detection of M. sexta serpin-1, 4, 9, 13 and smaller amounts of serpin-3, 5, 6 in the complexes suggests that it is regulated by multiple serpins in hemolymph. We produced site-directed mutants of proHP1b for cleavage by bovine blood coagulation factor Xa at the designed proteolytic activation site, to generate a form of proHP1b that could be activated by Factor Xa. However, proHP1b cut by Factor Xa failed to activate proHP6 and, via HP6, proHP8 or proPAP1. This negative result is consistent with the suggestion that proHP1* is a physiological mediator of immune responses. Further research is needed to investigate the conformational change that results in conversion of proHP1 to active proHP1*.     

Heparan sulphate with no affinity for antithrombin III and the control of haemostasis

Heparan sulphate with no affinity for antithrombin III (ATIII) was observed to cause acceleration of the factor Xa:ATIII interaction by 1100-fold (k2, 7 X 10(7) M-1.min-1) and the prothrombinase:ATIII interaction by 2900-fold (k2, 2.5 X 10(7) M-1.min-1). Although high-affinity heparan sulphate catalyzed higher acceleration and at lower concentration, in natural mixtures of the two forms the activity of the no affinity form predominated. Heparan sulphate had no significant effect on the thrombin:ATIII interaction but inhibited its potentiation by heparin (Kd 0.3 microM). From the estimated concentration of heparan sulphate on the endothelial cell surface it is proposed that the non-thrombogenic property of blood vessels is due to the acceleration of the factor Xa or prothrombinase:ATIII interaction by the greater mass of surface-bound heparan sulphate rather than by the much smaller proportion of heparin-like molecules (with high affinity for antithrombin III) which may be present.     

Chelation affects the conformation, lability and aggregation of channel catfish (Ictalurus punctatus) phosphorylcholine-reactive protein (PRP).

1. Phosphorylcholine-reactive protein (PRP) affinity-purified from channel catfish (Ictalurus punctatus) serum on phosphorylcholine-Sepharose, eluted from Bio-Gel A-5M as a 94.6 +/- 2.4 kDa protein when the gel filtration column buffer (Tris-saline) contained 25mM ethylenediaminetetraacetic acid (EDTA). 2. PRP chelated with EDTA immediately after affinity purification and gel-filtered in Tris-saline-EDTA, eluted as a 75.5 +/- 2.67 kDa protein referred to as fast-PRP (F-PRP). 3. PRP and F-PRP were identical on SDS-PAGE. Both resolved as a broad band of protein (ca 86-100 kDa) on non-reducing gels or as a ca 100 kDa protein after reduction with 2-mercaptoethanol (2-ME). 4. After gel-filtration in Tris-saline-EDTA, nearly complete reduction of 100 kDa PRP was achieved on SDS-PAGE. However, the protein regained its resistance to reduction upon storage at -60 degrees C. 5. SDS-PAGE and native PAGE also revealed that during storage, PRP and F-PRP combined to form 3 different aggregates referred to as aggregated-PRP (aggPRP). These aggregates are readily dissociated in the presence of 2-ME, suggesting a covalent interaction between adjacent pentamers comprising decameric aggPRPs. 6. PRP, F-PRP, and aggPRP have similar amino acid compositions.     

Understanding the relevance of local conformational stability and dynamics to the aggregation propensity of an IgG1 and IgG2 monoclonal antibodies

Aggregation of monoclonal antibodies is often a multi‐step process involving structural alterations in monomeric proteins and subsequent formation of soluble or insoluble oligomers. The role of local conformational stability and dynamics of native and/or partially altered structures in determining the aggregation propensity of monoclonal antibodies, however, is not well understood. Here, we investigate the role of conformational stability and dynamics of regions with distinct solvent exposure in determining the aggregation propensity of an IgG1 and IgG2 monoclonal antibody. The temperatures employed span the pre‐unfolding range (10–40°C) and the onset temperatures (T_onset) for exposure of apolar residues (～50°C), alterations in secondary structures (～60°C) and initiation of visible aggregate formation (～60°C). Solvent‐exposed regions were found to precede solvent‐shielded regions in an initiation of aggregation for both proteins. Such a process was observed upon alterations in overall tertiary structure while retaining the secondary structures in both the proteins. In addition, a greater dynamic nature of solvent‐shielded regions in potential intermediates of IgG1 and the improved conformational stability increased its resistance to aggregation when compared to IgG2. These results suggest that local conformational stability and fluctuations of partially altered structures can influence the aggregation propensity of immunoglobulins.     

Toward elucidating the heat activation mechanism of the TRPV1 channel gating by molecular dynamics simulation

As a key cellular sensor, the TRPV1 cation channel undergoes a gating transition from a closed state to an open state in response to various physical and chemical stimuli including noxious heat. Despite years of study, the heat activation mechanism of TRPV1 gating remains enigmatic at the molecular level. Toward elucidating the structural and energetic basis of TRPV1 gating, we have performed molecular dynamics (MD) simulations (with cumulative simulation time of 3 μs), starting from the high‐resolution closed and open structures of TRPV1 solved by cryo‐electron microscopy. In the closed‐state simulations at 30°C, we observed a stably closed channel constricted at the lower gate (near residue I679), while the upper gate (near residues G643 and M644) is dynamic and undergoes flickery opening/closing. In the open‐state simulations at 60°C, we found higher conformational variation consistent with a large entropy increase required for the heat activation, and both the lower and upper gates are dynamic with transient opening/closing. Through ensemble‐based structural analyses of the closed state versus the open state, we revealed pronounced closed‐to‐open conformational changes involving the membrane proximal domain (MPD) linker, the outer pore, and the TRP helix, which are accompanied by breaking/forming of a network of closed/open‐state specific hydrogen bonds. By comparing the closed‐state simulations at 30°C and 60°C, we observed heat‐activated conformational changes in the MPD linker, the outer pore, and the TRP helix that resemble the closed‐to‐open conformational changes, along with partial formation of the open‐state specific hydrogen bonds. Some of the residues involved in the above key hydrogen bonds were validated by previous mutational studies. Taken together, our MD simulations have offered rich structural and dynamic details beyond the static structures of TRPV1, and promising targets for future mutagenesis and functional studies of the TRPV1 channel. Proteins 2016; 84:1938–1949. © 2016 Wiley Periodicals, Inc.     

Indications for post-translational regulation of Vitis vinifera L. arginine decarboxylase

In order to study arginine decarboxylase regulation, we produced an antiserum against a hybrid of a 615 amino acid residue fragment of grapevine arginine decarboxylase cDNA with maltose-binding protein. The antiserum generated recognized mainly a protein band of ca. 80 kDa in extracts from grapevine tissues. Extracts from leaves and internodes in different developmental stages showed differences in the quantity of the 80 kDa band recognized by the antiserum. However, these differences did not correspond with changes in arginine decarboxylase specific activity. Furthermore, western blot analysis of extracts from cell cultures, where enzyme-specific activity was induced or repressed, did not reveal respective changes in the quantity of the 80 kDa protein band. Digestion of the hybrid by the specific protease factor Xa resulted in a polypeptide of 90 kDa instead of the expected two polypeptides of 43 and 66 kDa. Finally, western blot analysis of shoot extract incubated with factor Xa or the hybrid protein previously digested by factor Xa revealed that factor Xa-digested hybrid protein cleaved the 80 kDa band, resulting in two bands of ca. 38 and 40 kDa, whereas factor Xa alone did not affect it. These results suggest that arginine decarboxylase protein levels and/or activity is post-translationally regulated, as has been shown for other enzymes of polyamine biosynthesis.     

Modulation of prothrombinase assembly and activity by phosphatidylethanolamine

Constituents of platelet membranes regulate the activity of the prothrombinase complex. We demonstrate that membranes containing phosphatidylcholine and phosphatidylethanolamine (PE) bind factor Va with high affinity (K(d) = ～10 nm) in the absence of phosphatidylserine (PS). These membranes support formation of a 60-70% functional prothrombinase complex at saturating factor Va concentrations. Although reduced interfacial packing does contribute to factor Va binding in the absence of PS, it does not correlate with the enhanced activity of the Xa-Va complex assembled on PE-containing membranes. Instead, specific protein-PE interactions appear to contribute to the effects of PE. In support of this, soluble C6PE binds to recombinant factor Va(2) (K(d) = ～6.5 μm) and to factor Xa (K(d) = ～91 μm). C6PE and C6PS binding sites of factor Xa are specific, distinct, and linked, because binding of one lipid enhances the binding and activity effects of the other. C6PE triggers assembly (K(d)(app) = ～40 nm) of a partially active prothrombinase complex between factor Xa and factor Va(2), compared with K(d)(app) for C6PS ～2 nm. These findings provide new insights into the possible synergistic roles of platelet PE and PS in regulating thrombin formation, particularly when exposed membrane PS may be limiting.     

Structural,thermodynamic, and phosphatidylinositol 3‐phosphate binding properties of Phafin2

Phafin2 is a phosphatidylinositol 3‐phosphate (PtdIns(3)P) binding protein involved in the regulation of endosomal cargo trafficking and lysosomal induction of autophagy. Binding of Phafin2 to PtdIns(3)P is mediated by both its PH and FYVE domains. However, there are no studies on the structural basis, conformational stability, and lipid interactions of Phafin2 to better understand how this protein participates in signaling at the surface of endomembrane compartments. Here, we show that human Phafin2 is a moderately elongated monomer of ～28 kDa with an intensity‐average hydrodynamic diameter of ～7 nm. Circular dichroism (CD) analysis indicates that Phafin2 exhibits an α/β structure and predicts ～40% random coil content in the protein. Heteronuclear NMR data indicates that a unique conformation of Phafin2 is present in solution and dispersion of resonances suggests that the protein exhibits random coiled regions, in agreement with the CD data. Phafin2 is stable, displaying a melting temperature of 48.4°C. The folding‐unfolding curves, obtained using urea‐ and guanidine hydrochloride‐mediated denaturation, indicate that Phafin2 undergoes a two‐state native‐to‐denatured transition. Analysis of these transitions shows that the free energy change for urea‐ and guanidine hydrochloride‐induced Phafin2 denaturation in water is ～4 kcal mol^?1. PtdIns(3)P binding to Phafin2 occurs with high affinity, triggering minor conformational changes in the protein. Taken together, these studies represent a platform for establishing the structural basis of Phafin2 molecular interactions and the role of the two potentially redundant PtdIns(3)P‐binding domains of the protein in endomembrane compartments.     

Studies of DNA dumbbells. V. A DNA triplex formed between a 28 base-pair DNA dumbbell substrate and a 16 base linear single strand

CD spectra and melting curves were collected for a 28 base-pair DNA fragment in the form of a DNA dumbbell (linked on both ends by T₄ single-strand loops) and the same DNA sequence in the linear form (without end loops). The central 16 base pairs (bp) of the 28-bp duplex region is the poly(pu) sequence: 5′-AGGAAGGAGGAAAGAG-3′. Mixtures of the dumbbell and linear DNAs with the 16-base single-strand sequence 5′-TCCTTCCTCCTTTCTC-3′ were also prepared and studied. At 22°C, CD measurements of the mixtures in 950 mM NaCl, 10 mM sodium acetate, 1 mM EDTA, pH 5.5, at a duplex concentration of 1.8 μM, provided evidence for triplex formation. Spectroscopic features of the triplexes formed with either a dumbbell or linear substrate were quite similar. Melting curves of the duplex molecules alone and in mixtures with the third strand were collected as a function of duplex concentration from 0.16 to 2.15 μM. Melting curves of the dumbbell alone and mixtures with the third strand were entirely independent of DNA concentration. In contrast, melting curves of the linear duplex alone or mixed with the third strand were concentration dependent. At identical duplex concentrations, the dumbbell alone melts ～20°C higher than the linear duplex. The curve of the linear duplex displayed a significant pretransition probably due to end fraying. On melting curves of mixtures of the dumbbell or linear duplex with the third strand, a low temperature transition with much lower relative hyperchromicity change (～ 5%) was observed. This transition was attributed to the melting of a new molecular species, e.g., the triplex formed between the duplex and single-strand DNA molecules. In the case of the dumbbell/single-strand mixture, these melting transitions of the triplex and the dumbbell were entirely resolvable. In contrast, the melting transitions of the linear duplex and the triplex overlapped, thereby preventing their clear distinction. To analyze the data, a three-state equilibrium model is presented. The analysis utilizes differences in relative absorbance vs temperature curves of dumbbells (or linear molecules) alone and in mixtures with the third strand. From the model analysis a straightforward derivation of f_T(T), the fraction of triplex as a function of temperature, was obtained. Analysis of f_T vs temperature curves, in effect melting curves of the triplexes, provided evaluation of thermodynamic parameters of the melting transition. For the triplex formed with the dumbbell substrate, the total transition enthalpy is ΔH_T = 118.4 ± 12.8 kcal/mol (7.4 ± 0.8 kcal/mol per triplet unit) and the total transition entropy is ΔS_T = 344 ± 36.8 cal/K · mol (eu) (21.5 ± 2.3 eu per triple unit). The transition curves of the triplex formed with the linear duplex substrate displayed two distinct regions. A broad pretransition region from f_T = 0 to 0.55 and a higher, sharper transition above f_T = 0.55. The transition parameters derived from the lower temperature region of the curve are ΔH′_T = 44.8 ± 9.6 kcal/mol and ΔS′_T = 112 ± 33.6 eu (or ΔH′ = 2.8 ± 0.6 kcal/mol and ΔS′ = 7.0 ± 2.1 eu per triplet). These values are probably too small to correspond to actual melting of the triplex but instead likely reveal effects of end fraying of the duplex substrate on triplex stability. Transition parameters of the upper transition are ΔH′_T = 128.0 ± 2.3 kcal/mol and ΔS′_T = 379.2 ± 6.4 eu (ΔH′ = 8.0 ± 0.2 kcal/mol and ΔS′ = 23.7 ± 0.4 eu per triplet) in good agreement (within experimental error) with the transition parameters of the triplex formed with the dumbbell substrate. Supposing this upper transition reflects actual dissociation of the third strand from the linear duplex substrate this triplex is comparable in thermodynamic stability to the triplex formed with a dumbbell substrate. Even so, the biphasic melting character of the linear triplex obscures the whole analysis, casting doubt on its absolute reliability. Apparently triplexes formed with a dumbbell substrate offer technical advantages over triplexes formed from linear or hairpin duplex substrates for studies of DNA triplex stability. © 1993 John Wiley & Sons, Inc.     

Disruption of a tight cluster surrounding tyrosine 131 in the native conformation of antithrombin III activates it for factor Xa inhibition

The native conformation of antithrombin III (ATIII) is a poor inhibitor of its coagulation pathway target enzymes because of the partial insertion of its reactive center loop (RCL) in its central A beta-sheet. This study focused on tyrosine 131, which is located at the helix D-sheet A interface, adjacent to the ATIII pentasaccharide and heparin cofactor-binding sites and some 17A away from the RCL insertion. Crystallographic structures show that the Tyr(131) ring is buried in native ATIII and then becomes exposed when pentasaccharide binds to the inhibitor and activates it. This change suggested that Tyr(131) might serve as a switch for ATIII conformational activation. The hypothesis is supported by results from this study, which progressively removed atoms from the Tyr(131) side chain. Rates of heparin-independent Y131L and Y131A factor Xa inhibition were 25 and 29 times faster than for the control and Y131F, suggesting that Tyr(131) ring interactions with neighboring helix D and strand 2A residues shift the uncatalyzed native-to-activated conformational equilibrium toward the RCL-inserted state. Thermal denaturation experiments showed Y131A and Y131L were less stable than the control and Y131F, implying an increased tendency toward A-sheet mobility in these genetically activated molecules. Thus, the tight Tyr(131)-Asn(127)-Leu(130)-Leu(140)-Ser(142) cluster at the helix D-strand 2A interface of native antithrombin contributes significantly to the stability of the ground state conformation, and tyrosine 131 serves as a heparin-responsive molecular switch during the allosteric activation of ATIII anticoagulant activity.     

Cloning,expression, and molecular dynamics simulations of a xylosidase obtained from Thermomyces lanuginosus

The aim of this study was to clone, express, and characterize a β-xylosidase (Tlxyn1) from the thermophilic fungus Thermomyces lanuginosus SSBP in Pichia pastoris GS115 as well as analyze optimal activity and stability using computational and experimental methods. The enzyme was constitutively expressed using the GAP promoter and secreted into the medium due to the alpha-mating factor secretion signal present on the expression vector pBGPI. The 1276 bp gene consists of an open reading frame that does not contain introns. A 12% SDS–PAGE gel revealed a major protein band at an estimated molecular mass of 50 kDa which corresponded to zymogram analysis. The three-dimensional structure of β-xylosidase was predicted, and molecular dynamics simulations at different ranges of temperature and pH were performed in order to predict optimal activity and folding energy. The results suggested a strong conformational temperature and pH dependence. The recombinant enzyme exhibited optimal activity at pH 7 and 50°C and retained 80% activity at 50°C, pH 7 for about 45 min. This is the first report of the cloning, functional expression, and simulations study of a β-xylosidase from Thermomyces species in a fungal host.     

Proton and phosphorus NMR studies of d-CpG(pCpG)n duplexes in solution. Helix-coil transition and complex formation with actinomycin-D.

The Watson–Crick imino and amino exchangeable protons, the nonexchangeable base and sugar protons, and the backbone phosphates for d-CpG(pCpG)_n, n = 1 and 2, have been monitored by high-resolution nmr spectroscopy in aqueous solution over the temperature range 0°–90°C. The temperature dependence of the chemical shifts of the tetramer and hexamer resonances is consistent with the formation of stable duplexes at low temperature in solution. Comparison of the spectral characteristics of the tetranucleotide with those of the hexanucleotide with temperature permits the differentiation and assignment of the cytosine proton resonances on base pairs located at the end of the helix from those in an interior position. There is fraying at the terminal base pairs in the tetranucleotide and hexanucleotide duplexes. The Watson–Crick ring imino protons exchange at a faster rate than the Watson–Crick side-chain amino protons, with exchange occurring by transient opening of the double helix. The structure of the d-CpG(pCpG)_n double helices has been probed by proton relaxation time measurements, sugar proton coupling constants, and the proton chemical shift changes associated with the helix–coil transition. The experimental data support a structural model in solution, which incorporates an anti conformation about the glycosyl bonds, C(3) exo sugar ring pucker, and base overlap geometries similar to the B-DNA helix. Rotational correlation times of 1.7 and 0.9 × 10^?9 sec have been computed for the hexanucleotide and tetranucleotide duplexes in 0.1 M salt, D₂O, pH 6.25 at 27°C. The well-resolved ³¹P resonances for the internucleotide phosphates of the tetramer and hexamer sequences at superconducting fields shift upfield by 0.2–0.5 ppm on helix formation. These shifts reflect a conformational change about the ω,ω′ phosphodiester bonds from gauche-gauche in the duplex structure to a distribution of gauche-trans states in the coil structure. Significant differences are observed in the transition width and midpoint of the chemical shift versus temperature profiles plotted in differentiated form for the various base and sugar proton and internucleotide phosphorous resonances monitoring the d-CpG(pCpG)_n helix–coil transition. The twofold symmetry of the d-CpGpCpG duplex is removed on complex formation with the antibiotic actinomycin-D. Two phosphorous resonances are shifted downfield by ～2.6 ppm and ～1.6 ppm on formation of the 1:2 Act-D:d-CpGpCpG complex in solution. Model studies on binding of the antibiotic to dinucleotides of varying sequence indicate that intercalation of the actinomycin-D occurs at the GpC site in the d-CpGpCpG duplex and that the magnitude of the downfield shifts reflects strain at the O-P-O backbone angles and hydrogen bonding between the phenoxazone and the phosphate oxygens. Actinomycin-D is known to bind to nucleic acids that exhibit a B-DNA conformation; this suggests that the d-CpG(pCpG)_n duplexes exhibit a B-DNA conformation in solution.     

Proteolytic modulation of factor Xa–antithrombin complex enhances fibrinolysis in plasma

Our previous work showed that purified coagulation factor Xa (FXa) acquires fibrinolysis cofactor activity after plasmin-mediated cleavage. The predominant functional species is a non-covalent heterodimer of 33 and 13 kDa, termed Xa33/13, which has predicted newly exposed C-terminal lysines that are important for tissue plasminogen activator (tPA)-mediated plasminogen activation to plasmin. To provide evidence that this mechanism occurs in a physiological context, here we demonstrated the appearance of Xa33 in clotting plasma by western blot analysis. Since the normal fate of FXa is stable association with antithrombin (AT), an AT western blot was conducted, which revealed a band of ~ 13 kDa higher apparent molecular weight than AT that appeared concurrent to Xa33. Sequencing of purified proteins confirmed the generation of Xa13 covalently bound to AT and Xa33 (Xa33/13-AT) by cleavages at Lys–Met339 and Lys–Asp389. Ligand blots demonstrated ¹²⁵I-plasminogen binding to the Xa33 subunit of plasmin-generated Xa33/13-AT. Purified XaAT added to plasma that was induced to clot enhanced the rate of tPA-mediated fibrinolysis by ~ 16-fold. Similarly, purified plasminogen activation by tPA was enhanced by ~ 16-fold by XaAT. Plasmin cleaves XaAT and exposes plasminogen binding sites at least 10-fold faster than FXa. Here we demonstrate a novel function for AT, which accelerates the modulation of FXa into the fibrinolytic form, Xa33/13. The consequent exposure of C-terminal lysine binding sites essential for plasminogen activation enhances fibrinolysis. These results are consistent with a model where auxiliary cofactors link coagulation to fibrinolysis by priming the accelerating role of fibrin.     

A peptide model for the heparin binding site of antithrombin III.

A peptide model for the heparin binding site of antithrombin III (ATIII) was synthesized to elucidate the structural consequences of heparin binding. This peptide [ATIII(123-139)] and a sequence-permuted analogue (ATIII random) showed similar conformational behavior (as analyzed by circular dichroism spectroscopy) in aqueous and organic media. In the presence of heparin, however, the peptide ATIII(123-139) assumed a stable conformation, whereas peptide ATIII random did not. Complex formation was saturable and sensitive to salt. The ATIII(123-139)-heparin complex contained beta-structure, rather than helical structure. This finding is incompatible with current models of heparin binding and suggests that heparin binding may induce nonnative structures at the binding site which could, in turn, lead to activation of ATIII. The peptide ATIII(123-139) was able to inhibit the binding of ATIII by heparin, consistent with the notion that this peptide may be a model for the heparin binding site.     

Elimination of P1 arginine 393 interaction with underlying glutamic acid 255 partially activates antithrombin III for thrombin inhibition but not factor Xa inhibition

The mechanism for heparin activation of antithrombin III has been postulated to involve disruption of interactions between its reactive loop P1 residue and Glu(255) on the underlying protein surface. To test this hypothesis, the potential P1-constraining Arg(393)-Glu(255) hydrogen bond and ionic interactions were eliminated by converting Glu(255) to alanine. E255A and wild-type ATIIIs have identical reactive loop sequences (including the P1 and P14 residues), but differ in that Glu(255)-mediated, P1-constraining interactions with the underlying surface cannot form in the mutant. Relative to its wild-type parent, E255A had a 5-fold higher affinity for heparin and pentasaccharide. In the absence of cofactor, E255A exhibited a 5-fold activation of thrombin inhibition but no activation of factor Xa inhibition. Pentasaccharide addition elicited no further activation of thrombin inhibition but increased the factor Xa inhibition rate 100-fold. E255A heparin-dependent thrombin and factor Xa inhibition rates were 1000- and 2-fold faster, respectively, than pentasaccharide-catalyzed rates. Although "approximation" is the predominant factor in heparin activation of ATIII thrombin inhibition, and removal of the P1 constraint plays a distinct but minor role, the primary determinant for activation of factor Xa inhibition is the pentasaccharide-induced conformational change, with approximation making a further minor contribution, and removal of the P1 constraint playing no role at all.     

Mutagen–nucleic acid complexes at the polynucleotide duplex level in solution: Intercalation of proflavine into poly(dA-dT) and the melting transition of the complex

The nmr chemical shifts and line widths of the nucleic acid base and sugar proton resonances and the proflavine ring protons can be monitored through the melting transition of the proflavine + poly(dA-dT) complex, phosphate/dye (P/D) ratio = 24 and 8 in 1M salt solution. The nucleic acid and mutagen protons in the complex are in fast exchange between duplex and strand states with the midpoint of the melting transition monitored at the nucleic acid resonances increasing from 72.6°C for poly(dA-dT) to 78.1°C for the P/D = 24 complex and 83.4°C for the P/D = 8 complex in 1M salt solution. The melting transition monitored by the proflavine resonances were 80.0°C for the P/D = 24 complex and 84.3°C for the P/D = 8 complex in 1M salt solution. Since the nucleic acid is in excess at high P/D ratios, the nucleic acid transitions are an average for the opening of mutagen-free and mutagen-bound base-pair regions, while the proflavine transitions monitor the melting of mutagen-bound base-pair regions. The observed 0.75 to 0.95 ppm unfield shift at all four proflavine protons on formation of the complex with poly(dA-dT) provides direct evidence for intercalation of the mutagen between base pairs of the nucleic acid duplex. We have deduced the approximate overlap geometry between the proflavine ring and nearest-neighbor base pairs at the intercalation site from a comparison between experimental proflavine complexation shifts and those calculated for various stacking orientations. The experimental chemical shift of the poly(dA-dT) adenine H-2 resonance in the duplex state in the absence and presence of proflavine suggests that intercalation occurs preferentially at dT-dA sites. The selective chemical shift changes at the sugar H-2′,2″ and H-3′ resonances of the poly(dA-dT) duplex on complex formation demonstrates changes in the sugar pucker and/or torsion angles of the sugar phosphate backbone at the intercalation site.     

Purification and properties of a citrate synthase from Nitrosomonas sp. TK794 and a comparison with the enzymes of another nitrifying bacteria

Citrate(si)-synthase (citrate oxaloacetate-lyasem EC 4.1.3.7) was purified as an electrophoretically homogeneous protein from an ammonia-oxidizing chemoautotrophic bacterium, Nitrosomonas sp. TK794. The molecular mass of the native enzyme was estimated to be about 287 kDa by gel filtration, whereas SDS-PAGE produced one band with M_r values of 44.7 kDa, suggesting that the enzyme is a hexamer consisting of identical subunits. The isoelectric point of the enzyme was 5.0. The pH and temperature optima for citrate synthase (CS) activity was about 7.5–8.0 and 40°C, respectively. The citrate synthase was stable over a pH range of 6.0–8.5 and up to 40°C. The apparent K_m values for oxaloacetate and acetyl-CoA were about 11 μM and 247 μM, respectively. The activity of the citrate synthase was not inhibited by ATP, NADH or 2-oxoglutarate at 5mM, and was activated by potassium chloride at 0.1–100 mM. The N-terminal amino acid sequence of the enzyme protein was PPQDVATLSPGENKKTIELPILG.