Identification of the amino acid residues involved in the hemolytic activity of the Cucumaria echinata lectin CEL-III

Background

CEL-III is a hemolytic lectin isolated from the sea cucumber Cucumaria echinata that shows Ca^2 +-dependent Gal/GalNAc-binding specificity. This lectin is composed of two carbohydrate-recognition domains (domains 1 and 2) and an oligomerization domain (domain 3) that facilitates CEL-III assembly in the target cell membrane to form ion-permeable pores.

Methods

Several amino acid residues in domain 3 were replaced by alanine, and hemolytic activity of the mutants was examined.

Results

K344A, K351A, K405A, K420A and K425A showed marked increases in activity. In particular, K405A had activity that was 360-fold higher than the wild-type recombinant CEL-III and 3.6-fold higher than the native protein purified from sea cucumber. Since these residues appear to play roles in the stabilization of domain 3 through ionic and hydrogen bonding interactions with other residues, the mutations of these residues presumably lead to destabilization of domain 3, which consequently induces the oligomerization of the protein through association of domain 3 in the membrane. In contrast, K338A, R378A and R408A mutants exhibited a marked decrease in hemolytic activity. Since these residues are located on the surface of domain 3 without significant interactions with other residue, they may be involved in the interaction with components of the target cell membrane.

Conclusions

Several amino acid residues, especially basic residues, are found to be involved in the hemolytic activity as well as the oligomerization ability of CEL-III.

General significance

The results provide important clues to the membrane pore-forming mechanism of CEL-III, which is also related to that of bacterial pore-forming toxins.     

Primary structure of hemolytic lectin CEL-III from marine invertebrate Cucumaria echinata and its cDNA: structural similarity to the B-chain from plant lectin, ricin

CEL-III, a galactose/N-acetylgalactosamine (Gal/GalNAc) specific lectin purified from a marine invertebrate Cucumaria echinata has a strong hemolytic activity especially toward human and rabbit erythrocytes. We determined the primary structure of the CEL-III by examining the amino acid sequences of the protein and the nucleotide sequence of the cDNA. The cDNA encoding CEL-III has 1823 nucleotides and an open reading frame of 1296 nucleotides. CEL-III is composed of 432 amino acid residues with a M(r) of 47? omitted?457 and has six internal tandem repeats, each with of 40-50 amino acids, comprising the N-terminal two-thirds of the molecule. Similar repeats are found in the B-chains of cytotoxic plant lectins, such as ricin and abrin, where six repetitive sequences extend throughout the molecules. A hydropathy plot predicts hydrophobic segments in the C-terminal region of CEL-III. These findings suggest that the N-terminal region of CEL-III plays an important role in binding to carbohydrate receptors on the target cell membranes, an event which triggers an intermolecular hydrophobic interaction of the C-terminal region, the result being oligomerization of CEL-III to lead to pore-formation in erythrocyte membrane.     

C-type lectin-like carbohydrate recognition of the hemolytic lectin CEL-III containing ricin-type -trefoil folds

CEL-III is a Ca(2+)-dependent hemolytic lectin, isolated from the marine invertebrate Cucumaria echinata. The three-dimensional structure of CEL-III/GalNAc and CEL-III/methyl alpha-galactoside complexes was solved by x-ray crystallographic analysis. In these complexes, five carbohydrate molecules were found to be bound to two carbohydrate-binding domains (domains 1 and 2) located in the N-terminal 2/3 portion of the polypeptide and that contained beta-trefoil folds similar to ricin B-chain. The 3-OH and 4-OH of bound carbohydrate molecules were coordinated with Ca(2+) located at the subdomains 1alpha, 1gamma, 2alpha, 2beta, and 2gamma, simultaneously forming hydrogen bond networks with nearby amino acid side chains, which is similar to carbohydrate binding in C-type lectins. The binding of carbohydrates was further stabilized by aromatic amino acid residues, such as tyrosine and tryptophan, through a stacking interaction with the hydrophobic face of carbohydrates. The importance of amino acid residues in the carbohydrate-binding sites was confirmed by the mutational analyses. The orientation of bound GalNAc and methyl alpha-galactoside was similar to the galactose moiety of lactose bound to the carbohydrate-binding site of the ricin B-chain, although the ricin B-chain does not require Ca(2+) ions for carbohydrate binding. The binding of the carbohydrates induced local structural changes in carbohydrate-binding sites in subdomains 2alpha and 2beta. Binding of GalNAc also induced a slight change in the main chain structure of domain 3, which could be related to the conformational change upon binding of specific carbohydrates to induce oligomerization of the protein.     

Effects of amino acid mutations in the pore-forming domain of the hemolytic lectin CEL-III

The hemolytic lectin CEL-III forms transmembrane pores in the membranes of target cells. A study on the effect of site-directed mutation at Lys405 in domain 3 of CEL-III indicated that replacements of this residue by relatively smaller residues lead to a marked increase in hemolytic activity, suggesting that moderately destabilizing domain 3 facilitates formation of transmembrane pores through conformational changes.     

Characterization of functional domains of the hemolytic lectin CEL-III from the marine invertebrate Cucumaria echinata

CEL-III is a Ca(2+)-dependent, galactose/N-acetylgalactosamine (GalNAc)-specific lectin isolated from the marine invertebrate Cucumaria echinata. This lectin exhibits strong hemolytic activity and cytotoxicity through pore formation in target cell membranes. The amino acid sequence of CEL-III revealed the N-terminal two-thirds to have homology to the B-chains of ricin and abrin, which are galactose-specific plant toxic lectins; the C-terminal one-third shows no homology to any known proteins. To examine the carbohydrate-binding ability of the N-terminal region of CEL-III, the protein comprising Pyr1-Phe283 was expressed in Escherichia coli cells. The expressed protein showed both the ability to bind to a GalNAc-immobilized column as well as hemagglutinating activity for rabbit erythrocytes, confirming that the N-terminal region has binding activity for specific carbohydrates. Since the C-terminal region could not be expressed in E. coli cells, a fragment containing this region was produced by limited proteolysis of the native protein by trypsin. The resulting C-terminal 15 kDa fragment of CEL-III exhibited a tendency to self-associate, forming an oligomer. When mixed with erythrocytes, the oligomer of the C-terminal fragment caused hemagglutination, probably due to hydrophobic interaction with cell membranes, while the monomeric fragment did not. Chymotryptic digestion of the preformed CEL-III oligomer induced upon lactose binding also yielded an oligomer of the C-terminal fragment comprising six molecules of the 16 kDa fragment. These results suggest that after binding to cell surface carbohydrate chains, CEL-III oligomerizes through C-terminal domains, leading to the formation of ion-permeable pores by hydrophobic interaction with the cell membrane.     

Calcium ions stabilize a protein structure of hemolytic lectin CEL-III from marine invertebrate Cucumaria echinata

CEL-III, a galactose/N-acetylgalactosamine (Gal/GalNAc)-specific lectin purified from a marine invertebrate, Cucumaria echinata, has a strong hemolytic activity, especially toward human and rabbit erythrocytes in the presence of Ca2+. We evaluated the role of Ca2+ in hemagglutinating and hemolytic activities of CEL-III. We found that Ca2+ is closely associated with both activities of CEL-III. The fluorescence spectra of CEL-III upon binding to Ca2+ were measured. The result showed a structural change of CEL-III in the presence of Ca2+. The structural change of CEL-III upon Ca2+ binding was further demonstrated by stabilization against urea denaturation and by insusceptibility to protease digestions. CEL-III was completely unfolded at a low concentration of 2 M urea, while CEL-III complexed with Ca2+ was stable in 6 M urea. As for protease digestions, CEL-III monomer and oligomer were readily digested by trypsin, chymotrypsin, and papain in the absence of Ca2+, while they were insusceptible to the three proteases in the presence of Ca2+. The papain digestion of the decalcified oligomer produced a large C-terminal peptide, suggestting that the C-terminal region of CEL-III may participate in oligomerization of CEL-III as a core domain.     

Effects of chemical modification of carboxyl groups in the hemolytic lectin CEL-III on its hemolytic and carbohydrate-binding activities

Effects of chemical modification of carboxyl groups in the hemolytic lectin CEL-III on its activities were investigated. When carboxyl groups were modified with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) and glycine methyl ester, hemolytic activity of CEL-III decreased as the EDC concentration increased, accompanied by reduction of oligomerization ability and hemagglutinating activity. However, binding ability of CEL-III for immobilized lactose was retained fairly well after modification, suggesting that one of two carbohydrate-binding sites might be responsible for such inactivation of CEL-III.     

Effects of Chemical Modification of Carboxyl Groups in the Hemolytic Lectin CEL-III on Its Hemolytic and Carbohydrate-Binding Activities

Effects of chemical modification of carboxyl groups in the hemolytic lectin CEL-III on its activities were investigated. When carboxyl groups were modified with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) and glycine methyl ester, hemolytic activity of CEL-III decreased as the EDC concentration increased, accompanied by reduction of oligomerization ability and hemagglutinating activity. However, binding ability of CEL-III for immobilized lactose was retained fairly well after modification, suggesting that one of two carbohydrate-binding sites might be responsible for such inactivation of CEL-III.     

Antibacterial activity of peptides derived from the C-terminal region of a hemolytic lectin, CEL-III, from the marine invertebrate Cucumaria echinata

Several synthetic peptides derived from the C-terminal domain sequence of a hemolytic lectin, CEL-III, were examined as to their action on bacteria and artificial lipid membranes. Peptide P332 (KGVIFAKASVSVKVTASLSK-NH(2)), corresponding to the sequence from residue 332, exhibited strong antibacterial activity toward Gram-positive bacteria. Replacement of each Lys in P332 by Ala markedly decreased the activity. However, when all Lys were replaced by Arg, the antibacterial activity increased, indicating the importance of positively charged residues at these positions. Replacement of Val by Leu also led to higher antibacterial activity, especially toward Gram-negative bacteria. The antibacterial activity of these peptides was correlated with their membrane-permeabilizing activity toward the bacterial inner membrane and artificial lipid vesicles, indicating that the antibacterial action is due to perturbation of bacterial cell membranes, leading to enhancement of their permeability. These results also suggest that the hydrophobic region of CEL-III, from which P332 and its analogs were derived, may play some role in the interaction with target cell membranes to trigger hemolysis.     

Oligomerization process of the hemolytic lectin CEL-III purified from a sea cucumber, Cucumaria echinata

CEL-III is a Ca(2+)-dependent lectin purified from a sea cucumber, Cucumaria echinata. This protein exhibits strong hemolytic activity as well as cytotoxicity toward some cultured cell lines. Hemolysis is caused by CEL-III oligomers formed in the cell membrane after binding to specific carbohydrate chains on the cell surface. We have found that the oligomerization of CEL-III is also induced by the binding of simple carbohydrates, such as lactose, in aqueous solution under high pH and high ionic strength conditions. From gel filtration analysis of the oligomerization of CEL-III, it was found that the formation of the CEL-III oligomer is effectively induced by the binding of lactose and lactulose, disaccharides containing a beta-galactoside structure. Electron micrographs of the resulting oligomers revealed them to exist as particles with a size of approximately 20-30 nm. The oligomerization process required more than 1 h, which is consistent with the increase in surface hydrophobicity as measured using a fluorescent probe, 8-anilinonaphthalene-1-sulfonate. However, a change in the far-UV CD spectra as well as small-angle X-ray scattering occurred within a few minutes, suggesting that a structural change in the protein takes place rapidly, but the following growth of the oligomer is a much slower process.     

Sequence determination of lychnin, a type 1 ribosome-inactivating protein from Lychnis chalcedonica seeds

The complete amino acid sequence of lychnin, a type 1 ribosome-inactivating protein (RIP) isolated from Lychnis chalcedonica seeds, has been determined by automated Edman degradation and ESI-QTOF mass spectrometry. Lychnin consists of 234 amino acid residues with a molecular mass of 26 131.14 Da. All amino acid residues involved in the formation of the RIP active site (Tyr69, Tyr119, Glu170, Arg173 and Trp203) are fully conserved. Furthermore, a fast MALDI-TOF experiment showed that two out of three cysteinyl residues (Cys32 and Cys115) form a disulfide bridge, while Cys214 is in the thiol form, which makes it suitable for linking carrier molecules to generate immunotoxins and other conjugates.     

Multiple functional domains of Tat, the trans-activator of HIV-1, defined by mutational analysis.

The tat gene of HIV-1 is a potent trans-activator of gene expression from the HIV long terminal repeat (LTR). To define the functionally important regions of the product of the tat gene (Tat) of HIV-1, deletion, linker insertion and single amino acid substitution mutants within the Tat coding region of strain SF2 were constructed. The effect of these mutations on trans-activation was assessed by measuring the expression of the bacterial chloramphenicol acetyltransferase (CAT) reporter gene linked to the HIV-LTR. These studies have revealed that four different domains of the protein that map within the N-terminal 56 amino acid region are essential for Tat function. In addition to the essential domains, an auxiliary domain that enhances the activity of the essential region has also been mapped between amino acid residues 58 and 66. One of the essential domains maps in the N-terminal 20 amino acid region. The other three essential domains are highly conserved among the various strains of HIV-1 and HIV-2 as well as simian immunodeficiency virus (SIV). Of the conserved domains, one contains seven Cys residues and single amino acid substitutions for several Cys residues indicate that they are essential for Tat function. The second conserved domain contains a Lys X Leu Gly Ile X Tyr motif in which the Lys residue is essential for trans-activation and the other residues are partially essential. The third conserved domain is strongly basic and appears to play a dual role. Mutants lacking this domain are deficient in trans-activation and in efficient targeting of Tat to the nucleus and nucleolus. The combination of the four essential domains and the auxiliary domain contribute to the near full activity observed with the 101 amino acid Tat protein.     

景东湍蛙抗菌肽jindongenin-1d的分析和活性测定

新型抗菌肽研究有助于解决细菌对抗生素的耐药性问题。本研究用SMART技术构建了景东湍蛙Amolops jingdongensis皮肤的全长cDNA文库。通过单克隆和测序获得一个抗菌肽cDNA序列,序列比对结果表明其属于jindongenin-1家族,命名为jindongenin-1d。其cDNA序列全长321bp,编码含66个氨基酸残基的多肽。该多肽包括1个信号肽和1个前肽序列。成熟jindongenin-1d多肽包含24个氨基酸残基,理论分子量为2 709.38,等电点为9.24。对人工合成的jindongenin-1d蛋白进行了抗菌和溶血活性分析,结果表明jindongenin-1d对所选的革兰氏阴性菌、革兰氏阳性菌和真菌均有显著抑制作用,同时有弱溶血活性。本研究结果有助于进一步了解两栖动物皮肤分泌物活性物质的多态性和新型抗感染药物的设计。     

Comparison of the refined crystal structures of two wheat germ isolectins

The crystal structures of two closely related members of the multigene family of wheat lectins (isolectins 1 and 2) have been compared. These isolectins differ at five sequence positions, one being located in the saccharide binding site modulating ligand affinity. Crystals of the two isolectins are closely isomorphous (space group C2). The atomic models are based on structure refinement at 1.8 A resolution in the case of isolectin 2 (WGA2) and 2.0 A resolution in the case of isolectin 1 (WGA1). Refinement results for WGA1, recently completed with a crystallographic R-factor of 16.5% (Fo greater than 3 sigma (Fo)), are presented. Examination of a difference Fourier map, [FWGA2-FWGA1], at 2.0 A resolution and direct superposition of the two models indicated an overall close match of the two structures. Local differences are observed in the region of residues 44 to 69, where three sequence differences occur, and at highly mobile external residues on the surface. The average positional discrepancy (root-mean-square delta r) for corresponding protein atoms in the two crystal structures is 0.64 A for independent protomer I and 0.61 A for protomer II (0.29 A and 0.30 A for main-chain atoms). The mean atomic temperature factors are very similar 20.9 versus 22.0 A2). Regions of high flexibility coincide in the two isolectin structures. Of the 210 water sites identified in WGA1, 144 have corresponding positions in WGA2. A set of 51 well-ordered sites was found to be identical in the two independent environments in both structures, and was considered to be important for structure stabilization. Both of the unique sugar binding sites superimpose very closely, exhibiting root-mean-square positional differences ranging from 0.29 A to 0.42 A. The side-chains of the critical tyrosine residues, Tyr73 (P-site) and Tyr159 (S-site), superimpose best, while other highly flexible aromatic groups (Tyr64 and Trp150) and several water sites display large differences in position (0.5 to 1.0 A) and high temperature factors. The aromatic side-chains of Tyr66 in WGA1 and His66 in WGA2 are oriented similarly.     

Three aromatic amino acid residues critical for galactose transport in yeast Gal2 transporter

Tyr(446) in putative transmembrane segment 10 (TM10) of the yeast galactose transporter Gal2 has previously been identified as essential for galactose recognition. In the present study, alignment of the amino acid sequences of 63 sugar transporters or related proteins revealed 14 aromatic sites, including Tyr(446) of Gal2, that are conserved in >75% of these proteins. The importance of the remaining 13 conserved aromatic amino acids was examined individually by random mutagenesis using degenerate primers. Galactose transport-positive clones were identified by plate selection and subjected to DNA sequencing. For those transport-positive clones corresponding to Tyr(352), and Phe(504) mutants, all the amino acid substitutions comprised aromatic residues. The importance of the aromatic residues at these sites was further investigated by replacing them individually with each of the other 19 amino acids and measuring the galactose transport activity of the resulting mutants. Among both Tyr(352) and Phe(504) mutants, the other aromatic amino acids supported galactose transport; no other amino acids conferred high affinity transport activity. Thus, at least three aromatic sites are critical for galactose transport: one at the extracellular boundary of putative TM7 (Tyr(352)), one in the middle of putative TM10 (Tyr(446)), and one in the middle of putative TM12 (Phe(504)).     

Molecular cloning, sequencing, and expression of a fibrinolytic serine-protease gene from the earthworm Lumbricus rubellus

The full-length cDNA of the lumbrokinase fraction 6 (F6) protease gene of Lumbricus rubellus was amplified using an mRNA template, sequenced and expressed in E. coli cells. The F6 protease gene consisted of pro- and mature sequences by gene sequence analysis, and the protease was translated and modified into active mature polypeptide by N-terminal amino acid sequence analysis of the F6 protease. The pro-region of F6 protease consisted of the 44 residues from methionine-1 to lysine-44, and the mature polypeptide sequence (239 amino acid residues and one stop codon; 720 bp) started from isoleucine-45 and continued to the terminal residue. F6 protease gene clones having pro-mature sequence and mature sequence produced inclusion bodies in E. coli cells. When inclusion bodies were orally administrated rats, generated thrombus weight in the rat's venous was reduced by approximately 60 % versus controls. When the inclusion bodies were solubilized in pepsin and/or trypsin solutions, the solubilized enzymes showed hemolytic activity in vitro. It was concluded the F6 protease has hemolytic activity, and that it is composed of pro- and mature regions.     

Mutational and comparative analysis of streptolysin O, an oxygen-labile streptococcal hemolysin

The structural gene of streptolysin O was cloned from Streptococcus pyogenes strain Sa and S. equisimilis H46A, and the nucleotide sequences were compared with those of strain Richards. To obtain the minimal active fragment of the toxin and to elucidate structure-function relationships in hemolytic function, streptolysin O mutants deleted in N- and C-terminal regions were constructed. Internal amino acid residues were also replaced by introduction of point mutations. Analyses of these mutants showed that considerable activity was retained even after deletion of the N-terminal 107 residues, but genetic removal of the ultimate C-terminal residue resulted in a marked decrease in hemolytic function. By removal in succession, hemolytic activity declined exponentially, and only 0.002% of the activity remained after deletion of the C-terminal four residues. Nucleotide replacement experiments indicated pivotal roles of I202, V217, D324-L325, V339, and H469 residues in hemolysis.     

Chemical modification of a catalytic antibody that accelerates the hydrolysis of carbonate esters

Catalytic antibody, 4A1, catalyzes the hydrolysis of p-nitrophenyl alkyl carbonate. To determine the amino acid residues related to the catalytic activity of the antibody, we studied the effect of Tyr-, Trp-, and Lys-selective reagents on the catalytic activity and determined the amino acid sequences around the modified amino acid residues. We found that the Tyr-selective reagent is the most effective one and the modification of one Tyr residue results in the complete loss of the catalytic activity. The modified Tyr residue is identified to be Tyr-32 in the CDR-1 of the L chain.     

Sequence variability in three wheat germ agglutinin isolectins: Products of multiple genes in polyploid wheat

Summary Three highly homologous wheat germ isolectins (95–97%) are distinct gene products in hexaploid wheat. The amino acid sequences of two of these [wheat germ agglutinin 1 (WGA1) and 2 (WGA2)] are compared with sequence date derived from a complementary DNA (cDNA) clone for the third isolection (WGA3). This comparison includes three corrections to earlier amino acid sequences data of both WGA1 and WGA2 at positions 109 (from Ser to Phe), 134 (from Gly to Lys), and 150 (from Gly to Trp). These reassignments are based on new results from crystal structure refinement and amino acid sequence data of WGA1, as well as the recently determined nucleotide sequence of WGA3. In addition, the C-terminal residue of WGA1 has been revised to Gly 171 and now differs from WGA2 (Ala 171). Four other positions, Asn9, Ala53, Gly119, and Ser 123, at which WGA1 and WGA2 are identical but differ from the DNA sequence of WGA3, were also reinvestigated by amino acid sequencing techniques and confirmed.Variability among the three isolectins is observed at a total of 10 sequence positions: 9, 53, 56, 59, 66, 93, 109, 119, 123, and 171. Pairwise comparisons indicate that WGA3 deviates to a much larger extent from WGA1 (at eight positions) and from WGA2 (at seven positions) than the latter from one another (at five positions). Eight of the 10 mutations are equally distributed between domians B and C, the two intrior and more highly conserved of the four WGA domains (A, B, C, D). Correlation of the variable residues with the three-dimensional structure indicates that all except the two previously described B-domain residues, 56 and 59 (Wright and Olafsdottir 1986), are easily accommodated at the dimer surface.WGA3 displays a higher degree of inter-domain similarity than found in WGA1 and WGA2. Of the seven variable positions that are located in the domain core (residues 3–31), five are in perfect agreement with our earlier predicted domain ancestor sequence. This suggests that of the three isolectins WGA3 is most closely related to the common ancestral molecule.     

Design of potent, non-toxic antimicrobial agents based upon the structure of the frog skin peptide, pseudin-2

Pseudin-2, a naturally occurring 24 amino-acid-residue antimicrobial peptide first isolated from the skin of the South American paradoxical frog Pseudis paradoxa, has weak hemolytic and cytolytic activity but also relatively low potency against microorganisms. In a membrane-mimetic environment, the peptide exists in an amphipathic alpha-helical conformation. Analogs of the peptide with increased cationicity and alpha-helicity were chemically synthesized by progressively substituting neutral and acidic amino acid residues on the hydrophilic face of the alpha-helix by lysine. Analogs with up to three L-lysine substitutions showed increased potency against a range of gram-negative and gram-positive bacteria (up to 16-fold) whilst retaining low hemolytic activity. The analog [D-Lys3, D-Lys10, D-Lys14]pseudin-2 showed potent activity against gram-negative bacteria (minimum inhibitory concentration, MIC=5 microM against several antibiotic-resistant strains of Escherichia coli) but very low hemolytic activity (HC50>500 microM) and cytolytic activity against L929 fibroblasts (LC50=215 microM). Increasing the number of l-lysines to four and five did not enhance antimicrobial potency further but increased hemolytic activity towards human erythrocytes. Time-kill studies demonstrated that the analog [Lys3, Lys10, Lys14, Lys21]pseudin-2 at a concentration of 1 x MIC was bacteriocidal against E. coli (99.9% cell death after 96 min) but was bacteriostatic against S. aureus. Increasing the hydrophobicity of pseudin-2, while maintaining the amphipathic character of the molecule, by substitution of neutral amino acids on the hydrophobic face of the alpha-helix by L-phenylalanine, had only minor effects on antimicrobial and hemolytic activities.