Structure and chemical modifications of neurotoxin from Naja nigricollis studied by Raman spectroscopy

Raman spectroscopy was used to determine structural features of the native toxin alpha from Naja nigricollis, which contains only one Trp and one Tyr, and of chemically modified toxins having chromophores added to these two conserved aromatic amino acids. The percentages of secondary structure were determined by using amide I polypeptidic vibration analysis and are in agreement with X-ray structure [Low et al. (1976) Proc. Natl. Acad Sci. U.S.A. 73, 2991-2994] as well as with the geometry of the disulfide bridges estimated by using the v(S-S) vibrations. In the native toxin alpha, the single invariant tyrosine 25 appears to be buried in the structure and involved in a strong hydrogen bond. We have chemically modified these two invariant aromatic side chains by addition of chromophores. The presence of a (nitrophenyl)sulfenyl (NPS) chromophore bound to the Trp does not perturb the secondary structure of the toxin as shown by the analysis of the polypeptidic amide I vibrations; however, the environment of this Trp and the geometry of a disulfide bridge seem to be modified. The secondary structure is not affected by the presence of the NPS chromophore; therefore, the decrease in binding affinity observed after modification of Trp-29 by the reagent NPS-Cl [Faure et al. (1983) Biochemistry 22, 2068-2076] is due to an alteration of the environment of this aromatic amino acid and/or a steric hindrance and not to an overall modification of the toxin structure. The binding assays of [nitrotyrosyl]toxin show that after nitration the affinity toward the monoclonal antibody M alpha 1 is unchanged and that the affinity toward the cholinergic receptor (AcChR) from Torpedo marmorata remains high. We concluded that the structure of toxin alpha after adding the NO2 chromophore to Tyr-25 is the same as it is in native toxin.     

Structural implications on the interaction of scorpion alpha-like toxins with the sodium channel receptor site inferred from toxin iodination and pH-dependent binding

The alpha-like toxin from the venom of the scorpion Leiurus quinquestriatus hebraeus (Lqh III) binds with high affinity to receptor site 3 on insect sodium channels but does not bind to rat brain synaptosomes. The binding affinity of Lqh III to cockroach neuronal membranes was fivefold higher at pH 6.5 than at pH 7.5. This correlated with an increase in the electropositive charge on the toxin surface resulting from protonation of its four histidines. Radioiodination of Tyr(14) of Lqh III abolished its binding to locust but not cockroach sodium channels, whereas the noniodinated toxin bound equally well to both neuronal preparations. Radioiodination of Tyr(10) or Tyr(21) of the structurally similar alpha-toxin from L. quinquestriatus hebraeus (LqhalphaIT), as well as their substitution by phenylalanine, had only minor effects on binding to cockroach neuronal membranes. However, substitution of Tyr(21), but not Tyr(14), by leucine decreased the binding affinity of LqhalphaIT approximately 87-fold. Thus, Tyr(14) is involved in the bioactivity of Lqh III to locust receptor site 3 and is not crucial for the binding of LqhalphaIT to this site. In turn, the aromatic ring of Tyr(21) takes part in the bioactivity of LqhalphaIT to insects. These results highlight subtle architectural variations between locust and cockroach receptor site 3, in addition to previous results demonstrating the competence of Lqh III to differentiate between insect and mammalian sodium channel subtypes.     

Orientation of alpha-neurotoxin at the subunit interfaces of the nicotinic acetylcholine receptor

The alpha-neurotoxins are three-fingered peptide toxins that bind selectively at interfaces formed by the alpha subunit and its associating subunit partner, gamma, delta, or epsilon of the nicotinic acetylcholine receptor. Because the alpha-neurotoxin from Naja mossambica mossambica I shows an unusual selectivity for the alpha gamma and alpha delta over the alpha epsilon subunit interface, residue replacement and mutant cycle analysis of paired residues enabled us to identify the determinants in the gamma and delta sequences governing alpha-toxin recognition. To complement this approach, we have similarly analyzed residues on the alpha subunit face of the binding site dictating specificity for alpha-toxin. Analysis of the alpha gamma interface shows unique pairwise interactions between the charged residues on the alpha-toxin and three regions on the alpha subunit located around residue Asp(99), between residues Trp(149) and Val(153), and between residues Trp(187) and Asp(200). Substitutions of cationic residues at positions between Trp(149) and Val(153) markedly reduce the rate of alpha-toxin binding, and these cationic residues appear to be determinants in preventing alpha-toxin binding to alpha 2, alpha 3, and alpha 4 subunit containing receptors. Replacement of selected residues in the alpha-toxin shows that Ser(8) on loop I and Arg(33) and Arg(36) on the face of loop II, in apposition to loop I, are critical to the alpha-toxin for association with the alpha subunit. Pairwise mutant cycle analysis has enabled us to position residues on the concave face of the three alpha-toxin loops with respect to alpha and gamma subunit residues in the alpha-toxin binding site. Binding of NmmI alpha-toxin to the alpha gamma interface appears to have dominant electrostatic interactions not seen at the alpha delta interface.     

Requirement of N-glycan on GPI-anchored proteins for efficient binding of aerolysin but not Clostridium septicum alpha-toxin

Aerolysin of the Gram-negative bacterium Aeromonas hydrophila consists of small (SL) and large (LL) lobes. The alpha-toxin of Gram-positive Clostridium septicum has a single lobe homologous to LL. These toxins bind to glycosylphosphatidylinositol (GPI)-anchored proteins and generate pores in the cell's plasma membrane. We isolated CHO cells resistant to aerolysin, with the aim of obtaining GPI biosynthesis mutants. One mutant unexpectedly expressed GPI-anchored proteins, but nevertheless bound aerolysin poorly and was 10-fold less sensitive than wild-type cells. A cDNA of N-acetylglucosamine transferase I (GnTI) restored the binding of aerolysin to this mutant. Therefore, N-glycan is involved in the binding. Removal of mannoses by alpha-mannosidase II was important for the binding of aerolysin. In contrast, the alpha-toxin killed GnTI-deficient and wild-type CHO cells equally, indicating that its binding to GPI-anchored proteins is independent of N-glycan. Because SL bound to wild-type but not to GnTI-deficient cells, and because a hybrid toxin consisting of SL and the alpha-toxin killed wild-type cells 10-fold more efficiently than GnTI- deficient cells, SL with its binding site for N-glycan contributes to the high binding affinity of aerolysin.     

Role of tryptophan residues in toxicity of Cry1Ab toxin from Bacillus thuringiensis

Bacillus thuringiensis produces insecticidal proteins (Cry protoxins) during the sporulation phase as parasporal crystals. During intoxication, the Cry protoxins must change from insoluble crystals into membrane-inserted toxins which form ionic pores. The structural changes of Cry toxins during oligomerization and insertion into the membrane are still unknown. The Cry1Ab toxin has nine tryptophan residues; seven are located in domain I, the pore-forming domain, and two are located in domain II, which is involved in receptor recognition. Eight Trp residues are highly conserved within the whole family of three-domain Cry proteins, suggesting an essential role for these residues in the structural folding and function of the toxin. In this work, we analyzed the role of Trp residues in the structure and function of Cry1Ab toxin. We replaced the Trp residues with phenylalanine or cysteine using site-directed mutagenesis. Our results show that W65 and W316 are important for insecticidal activity of the toxin since their replacement by Phe reduced the toxicity against Manduca sexta. The presence of hydrophobic residue is important at positions 117, 219, 226, and 455 since replacement by Cys affected either the crystal formation or the insecticidal activity of the toxin in contrast to replacement by Phe in these positions. Additionally, some mutants in positions 219, 316, and 455 were also affected in binding to brush border membrane vesicles (BBMV). This is the first report that studies the role of Trp residues in the activity of Cry toxins.     

Importance of the conserved aromatic residues in the scorpion alpha-like toxin BmK M1: the hydrophobic surface region revisited

About one-third of the amino acid residues conserved in all scorpion long chain Na+ channel toxins are aromatic residues, some of which constitute the so-called "conserved hydrophobic surface." At present, in-depth structure-function studies of these aromatic residues using site-directed mutagenesis are still rare. In this study, an effective yeast expression system was used to study the role of seven conserved aromatic residues (Tyr5, Tyr14, Tyr21, Tyr35, Trp38, Tyr42, and Trp47) from the scorpion toxin BmK M1. Using site-directed mutagenesis, all of these aromatic residues were individually substituted with Gly in association with a more conservative substitution of Phe for Tyr5, Tyr14, Tyr35, or Trp47. The mutants, which were expressed in Saccharomyces cerevisiae S-78 cells, were then subjected to a bioassay in mice, electrophysiological characterization on cloned Na+ channels (Nav1.5), and CD analysis. Our results show an eye-catching correlation between the LD50 values in mice and the EC50 values on Nav1.5 channels in oocytes, indicating large mutant-dependent differences that emphasize important specific roles for the conserved aromatic residues in BmK M1. The aromatic side chains of the Tyr5, Tyr35, and Trp47 cluster protruding from the three-stranded beta-sheet seem to be essential for the structure and function of the toxin. Trp38 and Tyr42 (located in the beta2-sheet and in the loop between the beta2- and beta3-sheets, respectively) are most likely involved in the pharmacological function of the toxin.     

Study of the binding residues between ANEPII and insect sodium channel receptor

The present study aimed at determining the functional characteristics of anti-neuroexcitation peptide II (ANEPII). The depressant insect toxin ANEPII from the Chinese scorpion Buthus martensii Karsch had an effect on insect sodium channels. Previous studies showed that scorpion depressant toxins induce insect flaccid paralysis upon binding to receptor site-4, so we tried to predict the functional residues involved using computational techniques. In this study, three-dimensional structure modeling of ANEPII and site-4 of the insect sodium channel were carried out by homology modeling, and these models were used as the starting point for nanosecond-duration molecular dynamics simulations. Docking studies of ANEPII in the sodium channel homology model were conducted, and likely ANEPII binding loci were investigated. Based on these analyses, the residues Tyr34, Trp36, Gly39, Leu40, Trp53, Asn58, Gly61 and Gly62 were predicted to interact with sodium channel receptor and to act as functional residues.     

Multiple binding sites for phencyclidine on the nicotinic acetylcholine receptor from Torpedo ocellata electric organ

Binding of [3H]-phencyclidine ( [3H]-PCP) to acetylcholine-receptor enriched membrane from Torpedo ocellata electric organ was studied over a ligand concentration range of 1 to 200 microM. The results indicate that [3H]-PCP is bound to two classes of sites: high affinity (Kd = 6-9 microM) and low affinity (Kd = 85 microM) binding sites. In the absence of cholinergic drugs the ratio of high affinity [3H]-PCP binding sites to 125I-alpha-bungarotoxin (alpha-Bgt) binding sites is 0.37, and that of low affinity [3H]-PCP binding sites to 125I-alpha-Bgt is 1.06. Low affinity [3H]-PCP binding can be completely inhibited by alpha-bungarotoxin (alpha-Bgt), carbamylcholine and d-tubocurarine. This inhibition, together with the one to one stoichiometry with 125I-alpha-Bgt, suggests that the sites to which [3H]-PCP binds with low affinity are the acetylcholine (AcCho) binding sites. In the presence of 1 microM alpha-Bgt which blocks binding of [3H]-PCP to the AcCho binding sites, the ratio of high affinity [3H]-PCP sites to 125I-alpha-Bgt sites is 0.5, indicating the existence of one high affinity PCP site per receptor molecule, The toxin, however, decreases the apparent affinity of [3H]-PCP towards the AcCho receptor as well as the potency of tetracaine or dibucaine in inhibiting [3H]-PCP binding to that receptor. In the latter case the effect involves changes from a biphasic to a simple inhibition curve. The results suggest that non-competitive blockers to the AcCho receptors may affect their own sites as well, and that they do this also by binding to the AcCho binding sites. This is also inferred from the accelerated dissociation of [3H]-PCP from its high affinity binding sites by unlabeled PCP in the concentration range of 10(-3) to 10(-4) M, at which the drug occupies AcCho binding sites as well.     

Role of Tryptophan Residues in Toxicity of Cry1Ab Toxin from Bacillus thuringiensis

Bacillus thuringiensis produces insecticidal proteins (Cry protoxins) during the sporulation phase as parasporal crystals. During intoxication, the Cry protoxins must change from insoluble crystals into membrane-inserted toxins which form ionic pores. The structural changes of Cry toxins during oligomerization and insertion into the membrane are still unknown. The Cry1Ab toxin has nine tryptophan residues; seven are located in domain I, the pore-forming domain, and two are located in domain II, which is involved in receptor recognition. Eight Trp residues are highly conserved within the whole family of three-domain Cry proteins, suggesting an essential role for these residues in the structural folding and function of the toxin. In this work, we analyzed the role of Trp residues in the structure and function of Cry1Ab toxin. We replaced the Trp residues with phenylalanine or cysteine using site-directed mutagenesis. Our results show that W65 and W316 are important for insecticidal activity of the toxin since their replacement by Phe reduced the toxicity against Manduca sexta. The presence of hydrophobic residue is important at positions 117, 219, 226, and 455 since replacement by Cys affected either the crystal formation or the insecticidal activity of the toxin in contrast to replacement by Phe in these positions. Additionally, some mutants in positions 219, 316, and 455 were also affected in binding to brush border membrane vesicles (BBMV). This is the first report that studies the role of Trp residues in the activity of Cry toxins.     

Site-directed mutagenesis of histidine residues in Clostridium perfringens alpha-toxin.

Mutagenesis of H-68 or -148 in Clostridium perfringens alpha-toxin resulted in complete loss of hemolytic, phospholipase C, sphingomyelinase, and lethal activities of the toxin. These activities of the variant toxin at H-126 or -136 decreased by approximately 100-fold of the activities of the wild-type toxin. Mutation at H-46, -207, -212, or -241 showed no effect on the biological activities, indicating that these residues are not essential for these activities. The variant toxin at H-11 was not detected in culture supernatant and in cells of the transformant carrying the variant toxin gene. Wild-type toxin and the variant toxin at H-148 bound to erythrocytes in the presence of Ca2+; however, the variant toxins at H-68, -126, and -136 did not. Co2+ and Mn2+ ions stimulated binding of the variant toxin at H-68, -126, and -136 to membranes in the presence of Ca2+ and caused an increase in hemolytic activity. Wild-type toxin and the variant toxins at H-68, -126, and -136 contained two zinc atoms in the molecule. Wild-type toxin inactivated by EDTA contained two zinc atoms. These results suggest that wild-type toxin contains two tightly bound zinc atoms which are not coordinated to H-68, -126, and -136. The variant toxin at H-148 possessed only one zinc atom. Wild-type toxin and the variant toxin at H-148 showed [65Zn]2+ binding, but the variant toxins at H-68, -126, and -136 did not. Furthermore, [65Zn]2+ binding to wild-type toxin was competitively inhibited by unlabeled Zn2+, Co2+, and Mn2+. These results suggest that H-68, -126, and -136 residues bind an exchangeable and labile metal which is important for binding to membranes and that H-148 tightly binds one zinc atom which is essential for the active site of alpha-toxin.     

Chemical modification of tryptophan residues in α-neurotoxins fromOphiophagus hannah (king cobra) venom

Twoα-neurotoxins, Oh-4 and Oh-7, from the king cobra (Ophiophagus hannah) venom were subjected to Trp modification with 2-nitrophenylsulfenyl chloride (NPS-Cl). One major NPS derivative was isolated from the modified mixtures of Oh-4 and two from Oh-7 by HPLC. Amino acid analysis and sequence determination revealed that Trp-27 in Oh-4, and Trp-30 and Trp-26 and 30 in the two Oh-7 derivatives, were modified, respectively. Sulfenylation of Trp-27 in Oh-4 caused about 70% drop in lethal toxicity and nicotinic acetylcholine receptor-binding activity. Modification of Trp-30 in Oh-7 resulted in the decrease of lethal toxicity by 36% and binding activity by 61%. The activities were further lost when the conserved Trp-26 in Oh-7 was modified. Sulfenylation of the Trp residues did not significantly affect the secondary structure of the toxins as revealed by the CD spectra. These results indicate that the Trp residues in these two longα-neurotoxins may be involved in the receptor binding.     

Functional and structural consequences of aromatic residue substitutions within the kringle-2 domain of tissue-type plasminogen activator.

Aromatic amino acid residues within kringle domains play important roles in the structural stability and ligand-binding properties of these protein modules. In previous investigations, it has been demonstrated that the rigidly conserved Trp25 is primarily involved in stabilizing the conformation of the kringle-2 domain of tissue-type plasminogen activator (K2tpA), whereas Trp63, Trp74, and Tyr76 function in omega-amino acid ligand binding, and, to varying extents, in stabilizing the native folding of this kringle module. In the current study, the remaining aromatic residues of K2tPA, viz., Tyr2, Phe3, Tyr9, Tyr35, Tyr52, have been subjected to structure-function analysis via site-directed mutagenesis studies. Ligand binding was not significantly influenced by conservative amino acid mutations at these residues, but a radical mutation at Tyr35 destabilized the interaction of the ligand with the variant kringle. In addition, as reflected in the values of the melting temperatures, changes at Tyr9 and Tyr52 generally destabilized the native structure of K2tPA to a greater extent than changes at Tyr2, Phe3, and Tyr35. Taken together, results to date show that, in concert with predictions from the crystal structure of K2tpA, ligand binding appears to rely most on the integrity of Trp63 and Trp74, and aromaticity at Tyr76. With regard to aromatic amino acids, kringle folding is most dependent on Tyr9, Trp25, Tyr52, Trp63, and Tyr76. As yet, no obvious major roles have been uncovered for Tyr2, Phe3, or Tyr35 in K2tpA.     

Analysis of the substrate binding sites of human galactosyltransferase by protein engineering.

An expression vector, pIN-GT, encoding the soluble form of beta 1,4-galactosyltransferase (GT) has been constructed from human GT cDNAs and the pIN-III-ompA2 expression vector. Escherichia coli strain SB221 harboring the pIN-GT plasmid produces and secretes a fusion protein consisting of the ompA signal and GT. The expression of GT was detected by assaying enzymatic activity as well as by Western blotting using anti-GT antibodies. The recombinant GT was purified to homogeneity by N-acetylglucosamine-Sepharose affinity chromatography. The NH2-terminal peptide sequence of purified GT confirmed the cleavage site of the fusion protein by bacterial signal peptidase. This expression system was utilized to produce mutant forms of GT in order to identify specific amino acids involved in substrate binding sites. Photoaffinity labeling of GT with UDP-galactose analog, 4-azido-2-nitrophenyluridylylpyrophosphate (ANUP), followed by cyanogen bromide (CNBr) cleavage revealed that ANUP bound to a fragment of GT composed of amino acid residues from Asp276 to Met328. Within this peptide segment, Tyr284, Tyr287, Tyr309, Trp310 and Trp312 were separately substituted into Gly and Tyr287 into Phe by site-directed mutagenesis. Enzymatic activity assay showed drastic reduction of the activity in all of the mutants except that Tyr287----Phe remained as active as wild-type GT. Kinetic studies of the mutated GT showed that Tyr284, Tyr309 and Trp310 are critically involved in the N-acetyglucosamine binding and Tyr309 is involved in UDP-galactose binding as well.(ABSTRACT TRUNCATED AT 250 WORDS)     

Evidence that clustered phosphocholine head groups serve as sites for binding and assembly of an oligomeric protein pore

High susceptibility of rabbit erythrocytes toward the pore-forming action of staphylococcal alpha-toxin correlates with the presence of saturable, high affinity binding sites. All efforts to identify a protein or glycolipid receptor have failed, and the fact that liposomes composed solely of phosphatidylcholine are efficiently permeabilized adds to the enigma. A novel concept is advanced here to explain the puzzle. We propose that low affinity binding moieties can assume the role of high affinity binding sites due to their spatial arrangement in the membrane. Evidence is presented that phosphocholine head groups of sphingomyelin, clustered in sphingomyelin-cholesterol microdomains, serve this function for alpha-toxin. Clustering is required so that oligomerization, which is prerequisite for stable attachment of the toxin to the membrane, can efficiently occur. Outside these clusters, binding to phosphocholine is too transient for toxin monomers to find each other. The principle of membrane targeting in the absence of any genuine, high affinity receptor may also underlie the assembly of other lipid-inserted oligomers including cytotoxic peptides, protein toxins, and immune effector molecules.     

Toxins from the venom of the green mamba Dendroaspis angusticeps that inhibit the binding of quinuclidinyl benzilate to muscarinic acetylcholine receptors

Two protein toxins that displace the muscarinic antagonist quinuclidinyl benzilate from rat cortex synaptosomal membranes have been isolated from the green mamba (Dendroaspis angusticeps) venom by gel filtration on sephadex G-50, chromatography on the ion-exchangers Bio-Rex 70 and Sulphopropyl-Sephadex C-25 and reversed-phase HPLC. Toxin 1 has 64 amino acids and four disulfides and a formula weight of 7200 and the corresponding values for toxin 2 are 63, 4 and 6840, respectively. Ultracentrifugation gave a molecular weight of 6900 for toxin 1 and 6700 for toxin 2, Quinuclidinyl benzilate that binds to all types of muscarinic cholinergic receptor was displaced to about 50% by both toxins. This partial displacement indicates that the toxins might be specific for one subtype of receptor.     

X-ray structure and mutagenesis of the scorpion depressant toxin LqhIT2 reveals key determinants crucial for activity and anti-insect selectivity

Scorpion depressant beta-toxins show high preference for insect voltage-gated sodium channels (Na(v)s) and modulate their activation. Although their pharmacological and physiological effects were described, their three-dimensional structure and bioactive surface have never been determined. We utilized an efficient system for expression of the depressant toxin LqhIT2 (from Leiurus quinquestriatushebraeus), mutagenized its entire exterior, and determined its X-ray structure at 1.2 A resolution. The toxin molecule is composed of a conserved cysteine-stabilized alpha/beta-core (core-globule), and perpendicular to it an entity constituted from the N and C-terminal regions (NC-globule). The surface topology and overall hydrophobicity of the groove between the core and NC-globules (N-groove) is important for toxin activity and plays a role in selectivity to insect Na(v)s. The N-groove is flanked by Glu24 and Tyr28, which belong to the "pharmacophore" of scorpion beta-toxins, and by the side-chains of Trp53 and Asn58 that are important for receptor site recognition. Substitution of Ala13 by Trp in the N-groove uncoupled activity from binding, suggesting that this region of the molecule is also involved in "voltage-sensor trapping", the mode of action that typifies scorpion beta-toxins. The involvement of the N-groove in recognition of the receptor site, which seems to require a defined topology, as well as in sensor trapping, which involves interaction with a moving channel region, is puzzling. On the basis of the mutagenesis studies we hypothesize that following binding to the receptor site, the toxin undergoes a conformational change at the N-groove region that facilitates the trapping of the voltage-sensor in its activated position.     

A system for the directed evolution of the insecticidal protein from Bacillus thuringiensis

Theoretically, the activity of AB-type toxin molecules such as the insecticidal toxin (Cry toxin) from B. thuringiensis, which have one active site and two binding site, is improved in parallel with the binding affinity to its receptor. In this experiment, we tried to devise a method for the directed evolution of Cry toxins to increase the binding affinity to the insect receptor. Using a commercial T7 phage-display system, we expressed Cry1Aa toxin on the phage surface as fusions with the capsid protein 10B. These recombinant phages bound to a cadherin-like protein that is one of the Cry1Aa toxin receptors in the model target insect Bombyx mori. The apparent affinity of Cry1Aa-expressing phage for the receptor was higher than that of Cry1Ab-expressing phage. Phages expressing Cry1Aa were isolated from a mixed suspension of phages expressing Cry1Ab and concentrated by up to 130,000-fold. Finally, random mutations were made in amino acid residues 369–375 in domain 2 of Cry1Aa toxin, the mutant toxins were expressed on phages, and the resulting phage library was screened with cadherin-like protein-coated beads. As a result, phages expressing abnormal or low-affinity mutant toxins were excluded, and phages with high-affinity mutant toxins were selected. These results indicate that a method combining T7 phage display with selection using cadherin-like protein-coated magnetic beads can be used to increase the activity of easily obtained, low-activity Cry toxins from bacteria.     

Role of tryptophan-1 in hemolytic and phospholipase C activities of Clostridium perfringens alpha-toxin

Replacement of the Trp-1 in Clostridium perfringens alpha-toxin with tyrosine caused no effect on hemolytic and phospholipase C (PLC) activities or on binding to the zinc ion, but that of the residue with alanine, glycine and histidine led to drastic decreases in these activities and a significant reduction in binding to the zinc ion. The hemolytic and PLC activities of W1H and W1A were significantly increased by the preincubation of these variant toxins with zinc ions, but the preincubation of W1G with the metal ion caused little effect on these activities. Gly-Ile-alpha-toxin, which contained an additional Gly-Ile linked to the N-terminal amino acid of alpha-toxin, did not show hemolytic activity, but showed about 6% PLC activity of the wild-type toxin. A mutant toxin, which contained an additional Gly-Ile linked to the N-terminus of a protein lacking 4 N-terminal residues of alpha-toxin, showed about 1 and 6% hemolytic and PLC activities of the wild-type toxin, respectively. Incubation of the mutant toxin with zinc ions caused a significant increase in PLC activity. These observations suggested that Trp-1 is not essential for toxin activity, but plays a role in binding to zinc ions.     

Threonine-74 Is a Key Site for the Activity of Clostridium perfringens Alpha-Toxin

A mutant toxin (MT) that abolished almost 99% of the hemolytic activity of alpha-toxin was isolated by random polymerase chain reaction (PCR) mutagenesis of the gene for Clostridium perfringens alpha-toxin. In the mutant toxin, the amino acids at Tyr (Y)-62, Thr (T)-74 and Ile (I)-345 were substituted with His, Ile and Met, respectively. Replacement of T-74 with Ile by site-directed mutagenesis resulted in the loss of hemolytic, phospholipase C and sphingomyelinase activities by 1/250-fold of that of the wild-type. The replacement of Y-62 with Ile or I-345 with Met alone did not affect the activities of the toxin. T74I mutant bound to sheep erythrocyte membranes and specifically bound [⁶⁵Zn]²⁺ in Tris-buffered saline, in the same manner as the wild-type, and contained 2 mol of zinc ions per mol of protein. These results suggest that the T-74 residue plays a key role in these biological activities of C. perfringens alpha-toxin.     

Delineation of the peptide binding site of the human galanin receptor.

Galanin, a neuroendocrine peptide of 29 amino acids, binds to Gi/Go-coupled receptors to trigger cellular responses. To determine which amino acids of the recently cloned seven-transmembrane domain-type human galanin receptor are involved in the high-affinity binding of the endogenous peptide ligand, we performed a mutagenesis study. Mutation of the His264 or His267 of transmembrane domain VI to alanine, or of Phe282 of transmembrane domain VII to glycine, results in an apparent loss of galanin binding. The substitution of Glu271 to serine in the extracellular loop III of the receptor causes a 12-fold loss in affinity for galanin. We combined the mutagenesis results with data on the pharmacophores (Trp2, Tyr9) of galanin and with molecular modelling of the receptor using bacteriorhodopsin as a model. Based on these studies, we propose a binding site model for the endogenous peptide ligand in the galanin receptor where the N-terminus of galanin hydrogen bonds with Glu271 of the receptor, Trp2 of galanin interacts with the Zn2+ sensitive pair of His264 and His267 of transmembrane domain VI, and Tyr9 of galanin interacts with Phe282 of transmembrane domain VII, while the C-terminus of galanin is pointing towards the N-terminus of th