Isolation of four novel tachykinins from frog (Rana catesbeiana) brain and intestine

In a survey for unknown bioactive peptides in frog (Rana catesbeiana) brain and intestine, we isolated four novel peptides that exhibit potent stimulant effects on smooth muscle preparation of guinea pig ileum. By microsequencing and synthesis, these peptides were identified as Lys- Pro- Ser- Pro- Asp- Arg- Phe- Tyr- Gly- Leu- Met- NH2 (ranatachykinin A), Tyr- Lys- Ser- Asp- Ser- Phe- Tyr- Gly- Leu- Met- NH2 (ranatachykinin B), His- Asn- Pro- Ala- Ser- Phe- Ile- Gly- Leu- Met- NH2 (ranatachykinin C) and Lys- Pro- Ans- Pro- Glu- Arg- Phe- Tyr- Ala- Pro- Met- NH2 (ranatachykinin D). Ranatachykinin (RTK) A, B and C conserve the C- terminal sequence, Phe- X- Gly- Leu- Met- NH2, which is common to known members of the tachykinin family. On the other hand, RTK-D has a striking feature in its C-terminal sequence, Phe- Tyr- Ala- Pro- Met- NH2, which has never been found in other known tachykinins, and may constitute a new subclass in the tachykinin family.     

Role of the active site residues arginine-216 and arginine-237 in the substrate specificity of mammalian <Emphasis Type="SmallCaps">d</Emphasis>-aspartate oxidase

d-Aspartate oxidase (DDO) and d-amino acid oxidase (DAO) are flavin adenine dinucleotide-containing flavoproteins that catalyze the oxidative deamination of d-amino acids. Unlike DAO, which acts on several neutral and basic d-amino acids, DDO is highly specific for acidic d-amino acids. Based on molecular modeling and simulated annealing docking analyses, a recombinant mouse DDO carrying two substitutions (Arg-216 to Leu and Arg-237 to Tyr) was generated (R216L-R237Y variant). This variant and two previously constructed single-point mutants of mouse DDO (R216L and R237Y variants) were characterized to investigate the role of Arg-216 and Arg-237 in the substrate specificity of mouse DDO. The R216L-R237Y and R216L variants acquired a broad specificity for several neutral and basic d-amino acids, and showed a considerable decrease in activity against acidic d-amino acids. The R237Y variant, however, did not show any additional specificity for neutral or basic d-amino acids and its activity against acidic d-amino acids was greatly reduced. The kinetic properties of these variants indicated that the Arg-216 residue is important for the catalytic activity and substrate specificity of mouse DDO. However, Arg-237 is, apparently, only marginally involved in substrate recognition, but is important for catalytic activity. Notably, the substrate specificity of the R216L-R237Y variant differed significantly from that of the R216L variant, suggesting that Arg-237 has subsidiary effects on substrate specificity. Additional experiments using several DDO and DAO inhibitors also suggested the involvement of Arg-216 in the substrate specificity and catalytic activity of mouse DDO and that Arg-237 is possibly involved in substrate recognition by this enzyme. Collectively, these results indicate that Arg-216 and Arg-237 play crucial and subsidiary role(s), respectively, in the substrate specificity of mouse DDO.     

Rhodopsin regeneration: role of interaction between the photoreceptors and pigment epithelium cells]

Regeneration of rhodopsin has been studied in the eyecup, isolated retina and retinal homogenate of frog Rana temporaia as well as in the eyecup and isolated retina of fish-flounder Limanda aspera (Pallas). Rhodopsin has been found to regenerate only in the eyecup of frog, while isorhodopsin appeared to be the final product in the frog retinal homogenate. Decrease in rhodopsin regeneration level has been resulted from addition of inhibitors--theophyllin (2.10-2 M), papaverine (10-4--10-3 M) and strophantin (2.10-4 M) To the eyecup preparations (60, 20, 23%, consequently). A conclusion is made that structural connection between pigment epithelium cells and photoreceptors is necessary to provide regeneration of native rhodopsin.     

2.0 Å resolution structure of a ternary complex of pig muscle phosphoglycerate kinase containing 3-phospho-D-glycerate and the nucleotide Mn adenylylimidodiphosphate

The crystal structure of a ternary complex of pig muscle phosphoglycerate kinase (PGK) containing 3-phosphoglycerate (3-PG) and manganese adenylylimidodiphosphate (Mn AMP-PNP) has been determined and refined at 2.0 A resolution. The complex differs from the true substrate ternary complex only in the presence of an imido- rather than an oxylink between β- and γ-phosphates of the bound nucleotide. The 3-PG is bound in a similar manner to that observed in binary complexes. The nucleotide is bound in a similar manner to Mg ADP except that the metal ion is coordinated by all three α-, β-, and γ-phosphates, but not by the protein. The γ-phosphate, which is transferred in the reaction, is not bound by the protein. One further characteristic of the ternary complex is that Arg-38 moves to a position where its guanidinium group makes a triple interaction with the N-terminal domain, the C-terminal domain, and the 1-carboxyl group of the bound 3-PG. Although a hinge-bending conformation change is seen in the ternary complex, it is no larger than that observed in the 3-PG binary complex. To reduce that distance between two bound substrates to a value consistent with the direct in-line transfer known to occur in PGK, we modeled the closure of a pronounced cleft in the protein structure situated between the bound substrates. This closure suggested a mechanism of catalysis that involves the “capture” of the γ-phosphate by Arg-38 and the N-terminus of helix-14, which has a conserved Gly-Gly-Gly phosphate binding motif. We propose that nucleophilic attack by the 1-carboxyl group of the 3-PG on the γ-phosphorus follows the capture of the γ-phosphate, leading to a pentacoordinate transition state that may be stabilized by hydrogen bonds donated by the NH groups in the N-terminus of helix 14 and the guanidinium group of Arg-38. During the course of the reaction the metal ion is proposed to migrate to a position coordinating the α- and β-phosphates and the carboxyl group of Asp-374. The mechanism is consistent with the structural information from binary and ternary substrate complexes and much solution data, and gives a major catalytic role to Arg-38, as indicated by site-directed mutagenesis.     

Structure of the 1-36 N-terminal fragment of human phospholamban phosphorylated at Ser-16 and Thr-17

The structure of a 36-amino-acid-long N-terminal fragment of human phospholamban phosphorylated at Ser-16 and Thr-17 and Cys-36-->Ser mutated was determined from nuclear magnetic resonance data in aqueous solution containing 30% trifluoroethanol. The peptide assumes a conformation characterized by two alpha-helices connected by an irregular strand, which comprises the amino acids from Arg-13 to Pro-21. The proline is in a trans conformation. The two phosphate groups on Ser-16 and Thr-17 are shown to interact preferably with the side chains of Arg-14 and Arg-13, respectively. The helix comprising amino acids 22 to 35 is well determined (the rmsd for the backbone atoms, calculated for a family of 24 nuclear magnetic resonance structures is 0.69 +/- 0.28 A). The structures of phosphorylated and unphosphorylated phospholamban are compared, and the effect of the two phosphate groups on the relative spatial position of the two helices is examined. The packing parameters Omega (interhelical angle) and d (minimal interhelical distance) are calculated: in the case of the phosphorylated phospholamban, Omega = 100 +/- 35 degrees and d = 7.9 +/- 4.6 A, whereas for the unphosphorylated peptide the values are Omega = 80 +/- 20 degrees and d = 7.0 +/- 4.0 A. We conclude that 1) the phosphorylation does not affect the structure of the C terminus between residues 21 and 36 and 2) the phosphorylated phospholamban has more loose helical packing than the nonphosphorylated.     

A C-helix residue, Arg-123, has important roles in both the active and inactive forms of the cAMP receptor protein

The cAMP receptor protein (CRP) of Escherichia coli exists in an equilibrium between active and inactive forms, and the effector, cAMP, shifts that equilibrium to the active form, thereby allowing DNA binding. For this equilibrium shift, a C-helix repositioning around the C-helix residues Thr-127 and Ser-128 has been reported as a critical local event along with proper beta4/beta5 positioning. Here we show that another C-helix residue, Arg-123, has a unique role in cAMP-dependent CRP activation in two different ways. First, Arg-123 is important for proper cAMP affinity, although it is not critical for the conformational change with saturating amounts of cAMP. Second, Arg-123 is optimal for stabilizing the inactive conformation of CRP when cAMP is absent, thereby allowing a maximal range of regulation by cAMP. However, Arg-123 does not appear to be critical for a functional response to cAMP, as has been proposed previously (Berman, H. M., Ten Eyck, L. F., Goodsell, D. S., Haste, N. M., Korney, A., and Taylor, S. S. (2005) Proc. Natl. Acad. Sci. U. S. A. 102, 45-50). Based on mutagenic evidence, we also propose the basis for the stabilization of the inactive form to be through a salt interaction between Asp-68 and Arg-123.     

Binding and toxicity of apamin. Characterization of the active site

The structural features of apamin, a natural octadecapeptide from bee venom, enabling binding to its receptor and the expression of toxicity in mice, have been delineated by studying the effects on binding and toxicity of chemical modifications and amino acid substitutions in synthetic analogues. The results obtained indicate that the only hydrophobic residue, leucine at position 10, can be changed to alanine without a significant decrease in the specific activity. The need for a correct conformation has been established and also the importance of Gln-17 and the side chains of Arg-13 and Arg-14 (besides the charge effects). The interaction of apamin with its receptor, a calcium-activated potassium channel, is thus mediated by a precise topology around these three residues. Due to the ability to detect very low specific activities for some of the analogues, it has been shown that, individually, none of these interactions constitute an essential criteria for binding per se, but that their presence is necessary for the high specific activity of the toxin.     

Steered molecular dynamics simulations on the "tail helix latch" hypothesis in the gelsolin activation process

The molecular basis of the "tail helix latch" hypothesis in the gelsolin activation process has been studied by using the steered molecular dynamics simulations. In the present nanosecond scale simulations, the tail helix of gelsolin was pulled away from the S2 binding surface, and the required forces were calculated, from which the properties of binding between the tail helix and S2 domain and their dynamic unbinding processes were obtained. The force profile provides a detailed rupture mechanism that includes six major unbinding steps. In particular, the hydrogen bonds formed between Arg-207 and Asp-744 and between Arg-221 and Leu-753 are of the most important interaction pairs. The two hydrogen bond "clamps" stabilize the complex. The subsequent simulation on Arg-207-Ala (R207A) mutation of gelsolin indicated that this mutation facilitates the unbinding of the tail helix and that the contribution of the hydrogen bond between Arg-207 and Asp-744 to the binding is more than 50%, which offers a new clue for further mutagenesis study on the activation mechanism of gelsolin. Surrounding water molecules enhance the stability of the tail helix and facilitate the rupture process. Additionally, temperature also has a significant effect on the conformation of the arginine and arginine-related interactions, which revealed the molecular basis of the temperature dependence in gelsolin activation.     

Trypanothione reductase of Trypanosoma congolense: gene isolation, primary sequence determination, and comparison to glutathione reductase

The gene encoding trypanothione reductase, the redox disulfide-containing flavoenzyme that is unique to the parasitic trypanosomatids (Shames et al., 1986), has been isolated from the cattle pathogen Trypanosoma congolense. Library screening was carried out with inosine-containing oligonucleotide probes encoding sequences determined from two active site peptides isolated from the purified Crithidia fasciculata enzyme. The nucleotide sequence of the gene was determined according to the dideoxy chain termination method of Sanger. The structural gene is 1476 nucleotides long and encodes 492 amino acids. We have identified the active site peptide containing the redox-active disulfide, a peptide corresponding to the histidine-467 region of human erythrocyte glutathione reductase, as well as the flavin binding domain that is highly conserved in all disulfide-containing flavoprotein reductase enzymes. Alignment of five tryptic peptides (80 residues) isolated from the C. fasciculata trypanothione reductase with the primary sequence of the T. congolense enzyme showed 88% homology with 76% identity. Additionally, a sequence comparison of the glutathione reductase from Escherichia coli or human erythrocytes to T. congolense trypanothione reductase reveals greater than 50% homology. A search for the amino acid residues in the primary sequence of trypanothione reductase functionally active in binding/catalysis in human erythrocyte glutathione reductase shows that only the two arginine residues (Arg-37 and Arg-347), shown by X-ray crystallographic data to hydrogen bond to the GS1 glutathione glycyl carboxylate, are absent.     

A loop involving catalytic chain residues 230-245 is essential for the stabilization of both allosteric forms of Escherichia coli aspartate transcarbamylase

The allosteric transition of Escherichia coli aspartate transcarbamylase involves significant alterations in structure at both the quaternary and tertiary levels. On the tertiary level, the 240s loop (residues 230-245 of the catalytic chain) repositions, influencing the conformation of Arg-229, a residue near the aspartate binding site. In the T state, Arg-229 is bent out of the active site and may be stabilized in this position by an interaction with Glu-272. In the R state, the conformation of Arg-229 changes, allowing it to interact with the beta-carboxylate of aspartate, and is stabilized in this position by a specific interaction with Glu-233. In order to ascertain the function of Arg-229, Glu-233, and Glu-272 in the catalytic and cooperative interactions of the enzyme, three mutant enzymes were created by site-specific mutagenesis. Arg-229 was replaced by Ala, while both Glu-233 and Glu-272 were replaced by Ser. The Arg-229----Ala and Glu-233----Ser enzymes exhibit 10,000-fold and 80-fold decreases in maximal activity, respectively, and they both exhibit a 2-fold increase in the aspartate concentration at half the maximal observed velocity, [S]0.5. The Arg-229----Ala enzyme still exhibits substantial homotropic cooperativity, but all cooperativity is lost in the Glu-233----Ser enzyme. The Glu-233----Ser enzyme also shows a 4-fold decrease in the carbamyl phosphate [S]0.5, while the Arg-229----Ala enzyme shows no change in the carbamyl phosphate [S]0.5 compared to the wild-type enzyme. The Glu-272 to Ser mutation results in a slight reduction in maximal activity, an increase in [S]0.5 for both aspartate and carbamyl phosphate, and reduced cooperativity. Analysis of the isolated catalytic subunits from these three mutant enzymes reveals that in each case the changes in the kinetic properties of the isolated catalytic subunit are similar to the changes caused by the mutation in the holoenzyme. PALA was able to activate the Glu-233----Ser enzyme, at low aspartate concentrations, even though the mutant holoenzyme did not exhibit any cooperativity, indicating that cooperative interactions still exist between the active sites in this enzyme. It is proposed that Glu-233 of the 240s loop helps create the high-activity-high-affinity R state by positioning the side chain of Arg-229 for aspartate binding while Glu-272 helps stabilize the low-activity-low-affinity T state by positioning the side chain of Arg-229 so that it cannot interact with aspartate.(ABSTRACT TRUNCATED AT 400 WORDS)     

Structure of two crystal forms of sheep β‐lactoglobulin with EF‐loop in closed conformation

Ovine β‐lactoglobulin has been isolated from whey fraction of sheep milk and crystallized. The high‐resolution structures of two crystal forms (triclinic and trigonal) obtained at pH 7.0 have been determined revealing that ovine protein, similarly to its bovine analog, is dimeric. Access to the binding site located in the eight‐stranded antiparallel β‐barrel in both structures is blocked by the EF loop that has been found in closed conformation. Similarly to bovine lactoglobulin (BLG), conformation of the EF loop is stabilized by hydrogen bond between Glu89 and Ser116 indicating that Tanford transition might occur with the same mechanism. The substitution at six positions in relation to the most abundant isoform B of BLG also affects the distribution of electrostatic potentials and the total charge. © 2014 Wiley Periodicals, Inc. Biopolymers 101: 886–894, 2014.     

Erythromelalgia Mutation Q875E Stabilizes the Activated State of Sodium Channel Nav1.7

The human voltage-gated sodium channel Nav1.7 plays a crucial role in transmission of noxious stimuli. The inherited pain disorder erythromelalgia (IEM) has been linked to Nav1.7 gain-of-function mutations. Here we show that the IEM-associated Q875E mutation located on the pore module of Nav1.7 produces a large hyperpolarizing shift (−18 mV) in the voltage dependence of activation. Three-dimensional homology modeling indicates that the side chains of Gln-875 and the gating charge Arg-214 of the domain I voltage sensor are spatially close in the activated conformation of the channel. We verified this proximity by using an engineered disulfide bridge approach. The Q875E mutation introduces a negative charge that may modify the local electrical field experienced by the voltage sensor and, upon activation, interact directly via a salt bridge with the Arg-214 gating charge residue. Together these processes could promote transition to, and stabilization of, the domain I voltage sensor in the activated conformation and thus produce the observed gain of function. In support of this hypothesis, an increase in the extracellular concentration of Ca²⁺ or Mg²⁺ reverted the voltage dependence of activation of the IEM mutant to near WT values, suggesting a cation-mediated electrostatic screening of the proposed interaction between Q875E and Arg-214.     

Mutation of a critical arginine in microsomal prostaglandin E synthase-1 shifts the isomerase activity to a reductase activity that converts prostaglandin H2 into prostaglandin F2alpha

Microsomal prostaglandin E synthase type 1 (mPGES-1) converts prostaglandin endoperoxides, generated from arachidonic acid by cyclooxygenases, into prostaglandin E2. This enzyme belongs to the membrane-associated proteins in eicosanoid and glutathione metabolism (MAPEG) family of integral membrane proteins, and because of its link to inflammatory conditions and preferential coupling to cyclooxygenase 2, it has received considerable attention as a drug target. Based on the high resolution crystal structure of human leukotriene C4 synthase, a model of mPGES-1 has been constructed in which the tripeptide co-substrate glutathione is bound in a horseshoe-shaped conformation with its thiol group positioned in close proximity to Arg-126. Mutation of Arg-126 into an Ala or Gln strongly reduces the enzyme's prostaglandin E synthase activity (85-95%), whereas mutation of a neighboring Arg-122 does not have any significant effect. Interestingly, R126A and R126Q mPGES-1 exhibit a novel, glutathione-dependent, reductase activity, which allows conversion of prostaglandin H2 into prostaglandin F2alpha. Our data show that Arg-126 is a catalytic residue in mPGES-1 and suggest that MAPEG enzymes share significant structural components of their active sites.     

Structure and Membrane Interactions of the Antibiotic Peptide Dermadistinctin K by Multidimensional Solution and Oriented N and P Solid-State NMR Spectroscopy

DD K, a peptide first isolated from the skin secretion of the Phyllomedusa distincta frog, has been prepared by solid-phase chemical peptide synthesis and its conformation was studied in trifluoroethanol/water as well as in the presence of sodium dodecyl sulfate and dodecylphosphocholine micelles or small unilamellar vesicles. Multidimensional solution NMR spectroscopy indicates an α-helical conformation in membrane environments starting at residue 7 and extending to the C-terminal carboxyamide. Furthermore, DD K has been labeled with ¹⁵N at a single alanine position that is located within the helical core region of the sequence. When reconstituted into oriented phosphatidylcholine membranes the resulting ¹⁵N solid-state NMR spectrum shows a well-defined helix alignment parallel to the membrane surface in excellent agreement with the amphipathic character of DD K. Proton-decoupled ³¹P solid-state NMR spectroscopy indicates that the peptide creates a high level of disorder at the level of the phospholipid headgroup suggesting that DD K partitions into the bilayer where it severely disrupts membrane packing.     

Crystal Structure of Prothrombin Reveals Conformational Flexibility and Mechanism of Activation

The zymogen prothrombin is composed of fragment 1 containing a Gla domain and kringle-1, fragment 2 containing kringle-2, and a protease domain containing A and B chains. The prothrombinase complex assembled on the surface of platelets converts prothrombin to thrombin by cleaving at Arg-271 and Arg-320. The three-dimensional architecture of prothrombin and the molecular basis of its activation remain elusive. Here we report the first x-ray crystal structure of prothrombin as a Gla-domainless construct carrying an Ala replacement of the catalytic Ser-525. Prothrombin features a conformation 80 Å long, with fragment 1 positioned at a 36° angle relative to the main axis of fragment 2 coaxial to the protease domain. High flexibility of the linker connecting the two kringles suggests multiple arrangements for kringle-1 relative to the rest of the prothrombin molecule. Luminescence resonance energy transfer measurements detect two distinct conformations of prothrombin in solution, in a 3:2 ratio, with the distance between the two kringles either fully extended (54 ± 2 Å) or partially collapsed (≤34 Å) as seen in the crystal structure. A molecular mechanism of prothrombin activation emerges from the structure. Of the two sites of cleavage, Arg-271 is located in a disordered region connecting kringle-2 to the A chain, but Arg-320 is well defined within the activation domain and is not accessible to proteolysis in solution. Burial of Arg-320 prevents prothrombin autoactivation and directs prothrombinase to cleave at Arg-271 first. Reversal of the local electrostatic potential then redirects prothrombinase toward Arg-320, leading to thrombin generation via the prethrombin-2 intermediate.     

Identification of tryptic cleavage sites for two conformational states of the Neurospora plasma membrane H+-ATPase

Previous work has shown that the tryptic degradation pattern of the Neurospora plasma membrane H+-ATPase varies with the presence and absence of ligands, thus providing information about conformational states of the enzyme (Addison, R., and Scarborough, G. A. (1982) J. Biol. Chem. 257, 10421-10426; Brooker, R. J., and Slayman, C. W. (1983) J. Biol. Chem. 258, 8827-8832). In the present study, sites of tryptic cleavage have been mapped by immunoblotting with N- and C-terminal specific antibodies and by direct sequencing of proteolytic products after electro-transfer to polyvinylidene difluoride filters. In the absence of ligands (likely to represent the E1 conformation), trypsin cleaved the 100-kDa ATPase polypeptide at three sites very near the N terminus: Lys-24, Lys-36, and Arg-73. Removal of the first 36 amino acid residues only slightly affected ATPase activity, but removal of the subsequent 37 residues inactivated the enzyme completely. In the presence of vanadate and Mg2+ (E2 conformation), the rate of trypsinolysis at Arg-73 was greatly reduced, and enzyme activity was protected. In addition, a new cleavage site near the C terminus (Arg-900) became accessible to trypsin. Both effects of vanadate occurred at micromolar concentrations, well within the range previously measured for vanadate inhibition of ATPase activity. Taken together, these results suggest that the Neurospora ATPase undergoes significant conformational changes at both termini of the polypeptide during its reaction cycle.     

The reactivity of arginine residues interacting with glucose 1-phosphate in glycogen phosphorylase. A comparison between pyridoxal-reconstituted phosphorylase and the native enzyme

Modification of pyridoxal-reconstituted phosphorylase b with two arginine-directed reagents, butanedione and [14C]phenylglyoxal, has been investigated and compared with the results obtained on the active and inactive conformations of the native enzyme; the reactivity of the various arginine residues has been directly described using autoradiography of chymotryptic maps derived from [14C]phenylglyoxal-labelled phosphorylase. In the native enzyme this method demonstrates that the same arginine residue (568) is reactive on both activated phosphorylase a and b, non-reactive on inactive forms of phosphorylase and protected by glucose 1-phosphate. Another residue is reactive, but its reactivity does not drastically depend upon phosphorylase conformation; it interacts with glucose 1-phosphate. In the pyridoxal-reconstituted phosphorylase, the residue Arg-568 is reactive. This reactivity does not correlated in a simple manner with the ionisation state of the coenzyme, since it is high when this group is either absent or in a dianionic form, and low when it is monoanionic. The reactivity of Arg-568 rather correlates with the quaternary structure of the enzyme. The protection offered by glucose 1-phosphate, pyrophosphate and phosphite on this pyridoxal-reconstituted phosphorylase also provides information about the relative disposition of the substrate, the coenzyme and this particular arginine residue.     

Structure of a fructose-1,6-bis(phosphate) aldolase liganded to its natural substrate in a cleavage-defective mutant at 2.3 A(,).

Class I fructose-1,6-bis(phosphate) aldolase is a glycolytic enzyme that catalyzes the cleavage of fructose 1,6-bis(phosphate) through a covalent Schiff base intermediate. Although the atomic structure of this enzyme is known, assigning catalytic roles to the various enzymic active-site residues has been hampered by the lack of a structure for the enzyme-substrate complex. A mutant aldolase, K146A, is unable to cleave the C3-C4 bond of the hexose while retaining the ability to form the covalent intermediate, although at a greatly diminished rate. The structure of rabbit muscle K146A-aldolase A, in complex with its native substrate, fructose 1,6-bis(phosphate), is determined to 2.3 A resolution by molecular replacement. The density at the hexose binding site differs between subunits of the tetramer, in that two sites show greater occupancy relative to the other two. The hexose is bound in its linear, open conformation, but not covalently linked to the Schiff base-forming Lys-229. Therefore, this structure most likely represents the bound complex of hexose just after hemiketal hydrolysis and prior to Schiff base formation. The C1-phosphate binding site involves the three backbone nitrogens of Ser-271, Gly-272, and Gly-302, and the epsilon-amino group of Lys-229. This is the same binding site previously found for the analogous phosphate of the product DHAP. The C6-phosphate binding site involves three basic side chains, Arg-303, Arg-42, and Lys-41. The residues closest to Lys-229 were relatively unchanged in position when compared to the unbound wild-type structure. The major differences between the bound and unbound enzyme structures were observed in the positions of Lys-107, Arg-303, and Arg-42, with the greatest difference in the change in conformation of Arg-303. Site-directed mutagenesis was performed on those residues with different conformations in bound versus unbound enzyme. The kinetic constants of these mutant enzymes with the substrates fructose 1, 6-bis(phosphate) and fructose 1-phosphate are consistent with their ligand interactions as revealed by the structure reported here, including differing effects on k(cat) and K(m) between the two substrates depending on whether the mutations affect C6-phosphate binding. In the unbound state, Arg-303 forms a salt bridge with Glu-34, and in the liganded structure it interacts closely with the substrate C6-phosphate. The position of the sugar in the binding site would require a large movement prior to achieving the proper position for covalent catalysis with the Schiff base-forming Lys-229. The movement most likely involves a change in the location of the more loosely bound C6-phosphate. This result suggests that the substrate has one position in the Michaelis complex and another in the covalent complex. Such movement could trigger conformational changes in the carboxyl-terminal region, which has been implicated in substrate specificity.     

Solution conformation of carboxy-terminal fragments of the third component of human complement C3: proton nuclear magnetic resonance study of C3a, des-Arg-C3a, and C3a Arg69

A proton nuclear magnetic resonance (NMR) study is reported of the solution conformation of human C3a, that is released on activation of C3, the third component of complement. The intact C3a was used along with des-Arg-C3a, which is formed on cleavage of Arg-77 at the C terminal of C3a, and C3a Arg69, which is a 69-residue fragment produced on tryptic digestion of C3. A method of carboxypeptidase digestion/difference spectroscopy (Endo & Arata (1985) Biochemistry 24, 1561-1568) was extensively used for the spectral assignments of Ile-43, Ile-60, Leu-63, Tyr-15, and Tyr-59. On the basis of the results of nuclear Overhauser effect (NOE) measurements, we discuss the solution conformation of the C3a molecule. It has been concluded that removal of Arg-77, which is essential for expression of the biological activity of C3a, does not induce any significant change in the solution conformation of the C3a molecule. The C3a molecule is known to consist of a core region that comprises segment Tyr-15-Tyr-59. We conclude that in solution the C terminal segment sticks out of the core and takes on a helix-like conformation. Possible roles of the core region and the N terminal segment in maintaining the conformation of the C terminal segment are briefly discussed.     

Micelle bound structure and DNA interaction of brevinin‐2‐related peptide,an antimicrobial peptide derived from frog skin

Brevinin‐2‐related peptide (BR‐II), a novel antimicrobial peptide isolated from the skin of frog, Rana septentrionalis, shows a broad spectrum of antimicrobial activity with low haemolytic activity. It has also been shown to have antiviral activity, specifically to protect cells from infection by HIV‐1. To understand the active conformation of the BR‐II peptide in membranes, we have investigated the interaction of BR‐II with the prokaryotic and eukaryotic membrane‐mimetic micelles such as sodium dodecylsulfate (SDS) and dodecylphosphocholine (DPC), respectively. The interactions were studied using fluorescence and circular dichroism (CD) spectroscopy. Fluorescence experiments revealed that the N‐terminus tryptophan residue of BR‐II interacts with the hydrophobic core of the membrane mimicking micelles. The CD results suggest that interactions with membrane‐mimetic micelles induce an α‐helix conformation in BR‐II. We have also determined the solution structures of BR‐II in DPC and SDS micelles using NMR spectroscopy. The structural comparison of BR‐II in the presence of SDS and DPC micelles showed significant conformational changes in the residues connecting the N‐terminus and C‐terminus helices. The ability of BR‐II to bind DNA was elucidated by agarose gel retardation and fluorescence experiments. The structural differences of BR‐II in zwitterionic versus anionic membrane mimics and the DNA binding ability of BR‐II collectively contribute to the general understanding of the pharmacological specificity of this peptide towards prokaryotic and eukaryotic membranes and provide insights into its overall antimicrobial mechanism. Copyright © 2014 European Peptide Society and John Wiley & Sons, Ltd.