Tryparedoxin Peroxidase of Leishmania donovani: Molecular Cloning, Heterologous Expression, Specificity, and Catalytic Mechanism

Tryparedoxin peroxidase (TXNPx) of Trypanosomatidae is the terminal peroxidase of a complex redox cascade that detoxifies hydroperoxides by NADPH (Nogoceke et al., Biol. Chem. 378, 827-836, 1997). A gene putatively coding for a peroxiredoxin-type TXNPx was identified in L. donovani and expressed in Escherichia coli to yield an N-terminally His-tagged protein (LdH6TXNPx). LdH6TXNPx proved to be an active peroxidase with tryparedoxin (TXN) 1 and 2 of Crithidia fasciculata as cosubstrates. LdH6TXNPx efficiently reduces H₂O₂, is moderately active with t-butyl and cumene hydroperoxide, but only marginally with linoleic acid hydroperoxide and phosphatidyl choline hydroperoxide. The enzyme displays ping-pong kinetics with a k_cat of 11.2 s⁻¹ and limiting K_m values for t-butyl hydroperoxide and CfTXN1 of 50 and 3.6 μM, respectively. Site-directed mutagenesis confirmed that C52 and C173, as in related peroxiredoxins, are involved in catalysis. Exchanges of R128 against D and T49 against S and V, supported by molecular modelling, further disclose that the SH group of C52 builds the center of a novel catalytic triad. By hydrogen bonding with the OH of T49 and by the positive charge of R128 the solvent-exposed thiol of C52 becomes deprotonated to react with ROOH. Molecular models of oxidized TXNPx show C52 disulfide-bridged with C173′ that can be attacked by C41 of TXN2. By homology, the deduced mechanism may apply to most peroxiredoxins and complements current views of peroxiredoxin catalysis.     

Verification of the interaction of a tryparedoxin peroxidase with tryparedoxin by ESI-MS/MS

Tryparedoxin peroxidases (TXNPx) catalyze hydroperoxide reduction by tryparedoxin (TXN) by an enzyme substitution mechanism presumed to involve three catalytic intermediates: (i) a transient oxidation state having C52 oxidized to a sulfenic acid, (ii) the stable oxidized form with C52 disulfide-bound to C173', and (iii) a semi-reduced intermediate with C40 of TXN disulfide-linked to C173' from which the ground state enzyme is regenerated by thiol/disulfide reshuffling. This kinetically unstable form was mimmicked by a dead-end intermediate generated by cooxidation of TXNPx of Trypanosoma brucei brucei with an inhibitory mutein of TXN in which C43 was replaced by serine (TbTXNC43S). Cleavage of the isolated dead-end intermediate by trypsin plus chymotrypsin yielded a fragment that complied in size with the TbTXNC43S sequence 36 to 44 disulfide-linked to the TbTXNPx sequence 169 to 177. The presumed nature of the proteolytic fragment was confirmed by MS/MS sequencing. The results provide direct chemical evidence for the assumption that the reductive part of the catalysis is initiated by an attack of the substrate's solvent-exposed C40 on C173' of the oxidized peroxidase and, thus, confirm the hypothesis on the interaction of 2-Cys-peroxiredoxins with their proteinaceous substrates.     

Reversible oxidation of the active site cysteine of peroxiredoxins to cysteine sulfinic acid. Immunoblot detection with antibodies specific for the hyperoxidized cysteine-containing sequence

We previously suggested that oxidation of the active site cysteine of peroxiredoxin (Prx) I or Prx II to cysteine sulfinic acid in H2O2-treated cells is reversible (Woo, H. A., Chae, H. Z., Hwang, S. C., Yang, K.-S., Kang, S. W., Kim, K., and Rhee, S. G. (2003) Science 300, 653-656). In contrast, it was recently proposed that sulfinylation of Prx II, but not that of Prx I or Prx III, is reversible (Chevallet, M., Wagner, E., Luche, S., van Dorssealaer, A., Leize-Wagner, E., and Rabilloud, T. (2003) J. Biol. Chem. 278, 37146-37153). The detection of sulfinylated proteins in both of these previous studies relied on complex proteomics analysis. We now describe a simple immunoblot assay for the detection of sulfinylated Prx enzymes that is based on antibodies produced in response to a sulfonylated peptide modeled on the conserved active site sequence. These antibodies recognized both sulfinic and sulfonic forms of Prx equally well and allowed the detection of sulfinylated Prx enzymes in H2O2-treated cells with high sensitivity and specificity. With the use of these antibodies, we demonstrated that not only the cytosolic enzymes Prx I and Prx II but also the mitochondrial enzyme Prx III undergo reversible sulfinylation. The generation of antibodies specific for sulfonylated peptides should provide insight into protein function similar to that achieved with antibodies to peptides containing phosphoserine or phosphothreonine.     

Dimer-oligomer interconversion of wild-type and mutant rat 2-Cys peroxiredoxin: disulfide formation at dimer-dimer interfaces is not essential for decamerization

Rat heme-binding protein 23 (HBP23)/peroxiredoxin (Prx I) belongs to the 2-Cys peroxiredoxin type I family and exhibits peroxidase activity coupled with reduced thioredoxin (Trx) as an electron donor. We analyzed the dimer-oligomer interconversion of wild-type and mutant HBP23/Prx I by gel filtration and found that the C52S and C173S mutants existed mostly as decamers, whereas the wild type was a mixture of various forms, favoring the decamer at higher protein concentration and lower ionic salt concentration and in the presence of dithiothreitol. The C83S mutant was predominantly dimeric, in agreement with a previous crystallographic analysis (Hirotsu, S., Abe, Y., Okada, K., Nagahara, N., Hori, H., Nishino, T., and Hakoshima, T. (1999) Proc. Natl. Acad. Sci. U. S. A. 96, 12333-12338). X-ray diffraction analysis of the decameric C52S mutant revealed a toroidal structure (diameter, approximately 130A; inside diameter, approximately 55A; thickness, approximately 45A). In contrast to human Prx I, which was recently reported to exist predominantly as the decamer with Cys(83)-Cys(83) disulfide bonds at all dimer-dimer interfaces, rat HBP23/Prx I has a Cys(83)-Cys(83) disulfide bond at only one dimer-dimer interface (S-S separation of approximately 2.1A), whereas the interactions at the other interfaces (mean S-S separation of 3.6A) appear to involve hydrophobic and van der Waals forces. This finding is consistent with gel filtration analyses showing that the protein readily interconverts between dimer and oligomeric forms. The C83S mutant exhibited similar peroxidase activity to the wild type, which is exclusively dimeric, in the Trx/Trx reductase system. At higher concentrations, where the protein was mostly decameric, less efficient attack of reduced Trx was observed in a [(14)C]iodoacetamide incorporation experiment. We suggest that the dimerdecamer interconversion may have a regulatory role.     

Disulfide pairing of the recombinant kringle-2 domain of tissue plasminogen activator produced in Escherichia coli.

The kringle-2 domain of tissue plasminogen activator, cloned and expressed in Escherichia coli (Wilhelm, O.G., Jaskunas, S.R., Vlahos, C.J., and Bang, N.U. (1990) J. Biol. Chem. 265, 14606-14611), was internally radiolabeled using [35S]methionine-cysteine. Following refolding and isolation, the labeled polypeptide was further purified by reverse-phase high performance liquid chromatography. The purified kringle-2 domain was digested with thermolysin, and the resulting peptides were purified by high performance liquid chromatography. Five major peptides containing 35S were obtained. Amino acid sequence analysis showed that these peptides represented various cleavage products containing one or more of the following disulfides: Cys180-Cys261, Cys201-Cys243, Cys232-Cys256 (sequence numbering based on Pennica et al. (Pennica, D., Holmes, W.E., Kohr, W.J., Hakins, R.N., Vehar, G. A., Ward, C.A., Bennett, W.F., Yelverton E., Seeburg, P.H., Heynecker, H.L., Goeddel, E.V., and Collen, D. (1983) Nature 301, 214-221)). These results confirm that the refolding methodology used produced kringle-2 with the predicted disulfide linkage and, thus, yielded material suitable for structural and functional studies.     

Structure of a thermostable disulfide-bridge mutant of phage T4 lysozyme shows that an engineered cross-link in a flexible region does not increase the rigidity of the folded protein

A disulfide bond introduced between amino acid positions 9 and 164 in phage T4 lysozyme has been shown to significantly increase the stability of the enzyme toward thermal denaturation [Matsumura, M., Becktel, W.J., Levitt, M., & Matthews, B. W. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 6562-6566]. To elucidate the structural features of the engineered disulfide, the crystal structure of the disulfide mutant has been determined at 1.8-A resolution. Residue 9 lies in the N-terminal alpha-helix, while residue 164 is located at the extreme C terminus of T4 lysozyme, which is the most mobile part of the molecule. The refined structure shows that the formation of the disulfide bond is accompanied by relatively large (approximately 2.5 A) localized shifts in C-terminal main-chain atoms. Comparison of the geometry of the engineered disulfide with those of naturally observed disulfides in proteins shows that the engineered bridge adopts a left-handed spiral conformation with a typical set of dihedral angles and C alpha-C alpha distance. The geometry of the engineered disulfide suggests that it is slightly more strained than the disulfide of oxidized dithiothreitol but that the strain is within the range observed in naturally occurring disulfides. The wild-type and cross-linked lysozymes have very similar overall crystallographic temperature factors, indicating that the introduction of the disulfide bond does not impose rigidity on the folded protein structure. In particular, residues 162-164 retain high mobility in the mutant structure, consistent with the idea that stabilization of the protein is due to the effect of the disulfide cross-link on the unfolded rather than the folded state.(ABSTRACT TRUNCATED AT 250 WORDS)     

Why yeast cells can undergo apoptosis: death in times of peace, love, and war

The purpose of apoptosis in multicellular organisms is obvious: single cells die for the benefit of the whole organism (for example, during tissue development or embryogenesis). Although apoptosis has also been shown in various microorganisms, the reason for this cell death program has remained unexplained. Recently published studies have now described yeast apoptosis during aging, mating, or exposure to killer toxins (Fabrizio, P., L. Battistella, R. Vardavas, C. Gattazzo, L.L. Liou, A. Diaspro, J.W. Dossen, E.B. Gralla, and V.D. Longo. 2004. J. Cell Biol. 166:1055-1067; Herker, E., H. Jungwirth, K.A. Lehmann, C. Maldener, K.U. Frohlich, S. Wissing, S. Buttner, M. Fehr, S. Sigrist, and F. Madeo. 2004. J. Cell Biol. 164:501-507, underscoring the evolutionary benefit of a cell suicide program in yeast and, thus, giving a unicellular organism causes to die for.     

Secondary structure extensions in Pyrococcus furiosus ferredoxin destabilize the disulfide bond relative to that in other hyperthermostable ferredoxins. Global consequences for the disulfide orientational heterogeneity.

The single cubane cluster ferredoxin (Fd) from the hyperthermophilic archaeon Pyrococcus furiosus (Pf) possesses several unique properties when compared even to Fds from other hyperthermophilic archaea or bacteria. These include an equilibrium molecular heterogeneity, a six- to seven-residue increase in size, an Asp rather than the Cys as one cluster ligand, and a readily reducible disulfide bond. NMR assignments and determination of both secondary structure and tertiary contacts remote from the paramagnetic oxidized cluster of Pf 3Fe Fd with an intact disulfide bond reported previously (Teng Q., Zhou, Z. H., Smith, E. T., Busse, S. C., Howard, J. B. Adams, M. W. W., and La Mar, G. (1994) Biochemistry 33, 6316-6328) are extended here to the 4Fe oxidized cluster WT (1H and 15N) and D14C (1H only) Fds with an intact disulfide bond and to the 4Fe oxidized WT Fd (1H and 15N) with a cleaved disulfide bond. All forms are shown to possess a long (13-member) alpha-helix, two beta-sheets (one double-, one triple-stranded), and three turns outside the cluster vicinity, each with tertiary contacts among themselves as found in other Fds. While the same secondary structural elements, with similar tertiary contacts, are found in other hyperthermostable Fds, Pf Fd has two elements, the long helix and the triple-stranded beta-sheet, that exhibit extensions and form multiple tertiary contacts. All Pf Fd forms with an intact disulfide bond exhibit a dynamic equilibrium heterogeneity which is shown to modulate a hydrogen-bonding network in the hydrophobic core that radiates from the Cys21-Cys48 disulfide bond and encompasses residues Lys36, Val24, Cys21, and Cys17 and the majority of the long helix. The heterogeneity is attributed to population of the alternate S and R chiralities of the disulfide bond, each destabilized by steric interactions with the extended alpha-helix. Comparison of the chemical shifts and their temperature gradients reveals that the molecular structure of the protein with the less stable R disulfide resembles that of the Fd with a cleaved disulfide bond. Both cluster architecture (3Fe vs 4Fe) and ligand mutation (Cys for Asp14) leave the disulfide orientational heterogeneity largely unperturbed. It is concluded that the six- to seven-residue extension that results in a longer helix and larger beta-sheet in Pf Fd, relative to other hyperthermostable Fds, more likely serves to destabilize the disulfide bond, and hence make it more readily reducible, than to significantly increase protein thermostability.     

Amplified expression of streptomyces endo-beta-N-acetylglucosaminidase H in Escherichia coli and characterization of the enzyme product

The endo-beta-N-acetylglucosaminidase H (Endo H) gene from Streptomyces plicatus has been cloned into the Escherichia coli plasmid pKC30 (Shimatake, H., and Rosenberg, M. (1981) Nature 272, 128-132), thus placing expression of this gene under control of the strong lambda promoter pL. The construction, pKCE3, which includes a properly positioned E. coli ribosome binding site from the lac operon (Robbins, P.W., Trimble, R. B., Wirth, D.F., Hering, C., Maley, F. Maley, G. F., Das, R., Gibson, B.W., and Biemann, K. (1984) J. Biol. Chem. 259, 7577-7583), was used to transform an E. coli strain lysogenic for a lambda prophage containing a temperature-sensitive repressor. By shifting cultures of pKCE3 lysogens to 42 degrees C, the production of Endo H commenced and was linear for about 1 h. Enzyme yields were amplified 150-fold above those obtained from comparable cultures of S. plicatus and represented 3 to 4% of total cellular protein, which enabled purification of Endo H to homogeneity by a rapid fourstep procedure. Although most of the cloned Endo H was secreted into the periplasmic space by E. coli, its 4 kDa leader sequence peptide (Robbins et al. (1984] was only partially removed during processing. As a result the purified pKCE3 Endo H was a heterogeneous population of molecules with an average molecular mass of 31 kDa compared to the 28.9 kDa fully processed product normally secreted by S. plicatus. Despite the residual approximately 2 kDa of leader sequence on the cloned pKCE3 product, there were no detectable differences in either the substrate specificity or the stability characteristics of the enzyme purified from E. coli or from S. plicatus. Of particular value for studies on glycoproteins was the finding that the genetically engineered Endo H was completely free of proteolytic contaminants.     

The crystal structures of the tryparedoxin-tryparedoxin peroxidase couple unveil the structural determinants of leishmania detoxification pathway

Leishmaniasis is a neglected disease caused by Leishmania, an intracellular protozoan parasite which possesses a unique thiol metabolism based on trypanothione. Trypanothione is used as a source of electrons by the tryparedoxin/tryparedoxin peroxidase system (TXN/TXNPx) to reduce the hydroperoxides produced by macrophages during infection. This detoxification pathway is not only unique to the parasite but is also essential for its survival; therefore, it constitutes a most attractive drug target. Several forms of TXNPx, with very high sequence identity to one another, have been found in Leishmania strains, one of which has been used as a component of a potential anti-leishmanial polyprotein vaccine. The structures of cytosolic TXN and TXNPx from L. major (LmTXN and LmTXNPx) offer a unique opportunity to study peroxide reduction in Leishmania parasites at a molecular level, and may provide new tools for multienzyme inhibition-based drug discovery. Structural analyses bring out key structural features to elucidate LmTXN and LmTXNPx function. LmTXN displays an unusual N-terminal α-helix which allows the formation of a stable domain-swapped dimer. In LmTXNPx, crystallized in reducing condition, both the locally unfolded (LU) and fully folded (FF) conformations, typical of the oxidized and reduced protein respectively, are populated. The structural analysis presented here points to a high flexibility of the loop that includes the peroxidatic cysteine which facilitates Cys52 to form an inter-chain disulfide bond with the resolving cysteine (Cys173), thereby preventing over-oxidation which would inactivate the enzyme. Analysis of the electrostatic surface potentials of both LmTXN and LmTXNPx unveils the structural elements at the basis of functionally relevant interaction between the two proteins. Finally, the structural analysis of TXNPx allows us to identify the position of the epitopes that make the protein antigenic and therefore potentially suitable to be used in an anti-leishmanial polyprotein vaccine.     

Structure of a stabilizing disulfide bridge mutant that closes the active-site cleft of T4 lysozyme.

The engineered disulfide bridge between residues 21 and 142 of phage T4 lysozyme spans the active-site cleft and can be used as a switch to control the activity of the enzyme (Matsumura, M. & Matthews, B.W., 1989, Science 243, 792-794). In the oxidized form the disulfide increases the melting temperature of the protein by 11 degrees C at pH 2. The crystal structure of this mutant lysozyme has been determined in both the reduced and oxidized forms. In the reduced form, the crystal structure of the mutant is shown to be extremely similar to that of wild type. In the oxidized form, however, the formation of the disulfide bridge causes the alpha-carbons of Cys 21 and Cys 142, on opposite sides of the active-site cleft, to move toward each other by 2.5 A. In association with this movement, the amino-terminal domain of the protein undergoes a rigid-body rotation of 5.1 degrees relative to the carboxy-terminal domain. This rotation occurs about an axis passing through the junction of the amino-terminal and carboxy-terminal domains and is also close to the axis that best fits the apparent thermal motion of the amino-terminal domain seen previously in crystals of wild-type lysozyme. Even though the engineered Cys 21-Cys 142 disulfide links together the amino-terminal and carboxy-terminal domains of T4 lysozyme, it does not reduce the apparent mobility of the one domain relative to the other. The pronounced "hinge-bending" mobility of the amino-terminal domain that is suggested by the crystallographic thermal parameters of wild-type lysozyme persists in the oxidized (and reduced) mutant structures. In the immediate vicinity of the introduced disulfide bridge the mutant structure is more mobile (or disordered) than wild type, so much so that the exact conformation of Cys 21 remains obscure. As with the previously described disulfide bridge between residues 9 and 164 of T4 lysozyme (Pjura, P.E., Matsumura, M., Wozniak, J.A., & Matthews, B.W., 1990, Biochemistry 29, 2592-2598), the engineered cross-link substantially enhances the stability of the protein without making the folded structure more rigid.     

NMR structure of a variant human prion protein with two disulfide bridges

The nuclear magnetic resonance structure of the globular domain with residues 121-230 of a variant human prion protein with two disulfide bonds, hPrP(M166C/E221C), shows the same global fold as wild-type hPrP(121-230). It contains three alpha-helices of residues 144-154, 173-194 and 200-228, an anti-parallel beta-sheet of residues 128-131 and 161-164, and the disulfides Cys166-Cys221 and Cys179-Cys214. The engineered extra disulfide bond in the presumed "protein X"-binding site is accommodated with slight, strictly localized conformational changes. High compatibility of hPrP with insertion of a second disulfide bridge in the protein X epitope was further substantiated by model calculations with additional variant structures. The ease with which the hPrP structure can accommodate a variety of locations for a second disulfide bond within the presumed protein X-binding epitope suggests a functional role for the extensive perturbation by a natural second disulfide bond of the corresponding region in the human doppel protein.     

The arrangement of disulfide loops in human alpha 2-HS glycoprotein. Similarity to the disulfide bridge structures of cystatins and kininogens

The complete disulfide loop structure of human alpha 2-HS glycoprotein has been elucidated. alpha 2-HS glycoprotein isolated from human plasma was found to be a two-chain protein composed of a heavy and a light chain. The heavy chain comprises the A-chain of alpha 2-HS glycoprotein (Yoshioka, Y., Gejyo, F., Marti, T., Rickli, E. E., Bürgi, W., Offner, G. D., Troxler, R. F., and Schmid, K. (1986) J. Biol. Chem. 261, 1665-1676) and part of the connecting peptide which has been predicted from the corresponding cDNA sequence (Lee, C. C., Bowman, B. H., and Yang, F. (1987) Proc. Natl. Acad. Sci. U.S.A. 84, 4403-4407), whereas the light chain corresponds to the beta-chain of alpha 2-HS glycoprotein (Gejyo, F., Chang, J. L., Bürgi, W., Schmid, K., Offner, G. D., Troxler, R. F., Van Halbeek, H., Dorland, L., Gerwig, G. J., Vliegenthart, J. F. G. (1983) J. Biol. Chem. 258, 4966-4971). Twelve half-cystine residues are present in the alpha 2-HS glycoprotein molecule, and 11 of them are positioned in the heavy chain and a single one in the light chain of the molecule; they form six disulfide bridges. The first and the last half-cystine residues of the amino acid sequence of alpha 2-HS glycoprotein are engaged in the formation of a loop spanning the extreme NH2- and COOH-terminal portions of the molecule, thereby connecting the heavy and light chains. The other 10 half-cystines residues are linked consecutively in the heavy chain and form five loops which span 4-19 amino acid residues. Among them are two pairs of loops which are characterized by mutual sequence homology. The particular arrangement of disulfide loops in alpha 2-HS glycoprotein is similar to the patterns of linearly arranged and tandemly repeated disulfide loops of cysteine proteinase inhibitors, i.e. the cystatins and the kininogens. It is concluded that alpha 2-HS glycoprotein represents a structural prototype of a novel family among the cystatin superfamily, characterized by the presence of two cystatin-like building blocks. Extensive similarity among the NH2-terminal sequences of alpha 2-HS glycoprotein and human histidine-rich glycoprotein suggest that the latter protein is another candidate protein of this new family.     

Regulation of macrophage migration inhibitory factor and thiol-specific antioxidant protein PAG by direct interaction

Macrophage migration inhibitory factor (MIF) is an important mediator that plays a central role in the control of the host immune and inflammatory response. To investigate the molecular mechanism of MIF action, we have used the yeast two-hybrid system and identified PAG, a thiol-specific antioxidant protein, as an interacting partner of MIF. Association of MIF with PAG was found in 293T cells transiently expressing MIF and PAG. The use of PAG mutants (C52S, C71S, and C173S) revealed that this association was significantly affected by C173S, but not C52S and C71S, indicating that a disulfide involving Cys(173) of PAG is responsible for the formation of MIF-PAG complex. In addition, the interaction was highly dependent on the reducing conditions such as dithiothreitol or beta-mercaptoethanol but not in the presence of H2O2. Analysis of the activities of the interacting proteins showed that the D-dopachrome tautomerase activity of MIF was decreased in a dose-dependent manner by coexpression of wild-type PAG, C52S, and C71S, whereas C173S was almost ineffective, suggesting that the direct interaction may be involved in the control of D-dopachrome tautomerase activity of MIF. Moreover, MIF has been shown to bind to PAG and it also inhibits the antioxidant activity of PAG.     

Amino acid sequence and post-translational modification of stem cell factor isolated from buffalo rat liver cell-conditioned medium.

Stem cell factor (SCF) isolated from culture medium conditioned by Buffalo rat liver cells was subjected to detailed structural analysis. Attempts at direct N-terminal sequencing of the factor indicated that its N terminus is blocked as pyroglutamic acid (Zsebo, K. M., Wypych, J., McNiece, I. K., Lu, H. S., Smith, K. A., Karkare, S. B., Sachdev, R. K., Yuschenkoff, V. N., Birkett, N. C., Williams, L. R., Satyagal, V. N., Bosselman, R. A., Mendiaz, E. A., and Langley, K. E. (1990) Cell 63, 195-201). The removal of the blocking pyroglutamate by pyroglutamate aminopeptidase allowed sequencing of the polypeptide chain to position 47. Stem cell factor was also digested with CNBr, trypsin, Staphylococcus aureus protease (strain V8), and AspN peptidase to generate different sets of peptides that were then separated by reverse-phase high-performance liquid chromatography and sequenced. Sequence of an internal peptide fragment obtained by cleavage of stem cell factor at a single tryptophanyl peptide bond was also obtained. From these analyses, the complete amino acid sequence could be constructed. The factor as isolated is a single polypeptide of 164 or 165 amino acids. The sequence is confirmatory to a sequence deduced from a cDNA sequence and provides important evidence for C-terminal processing of the polypeptide encoded by cDNA. There are four potential N-linked glycosylation sites. Asn65, Asn72, Asn109, and Asn120. Sequence determination of isolated peptides suggested that Asn120 is glycosylated, Asn65 and Asn109 glycosylated in some molecules but not in others, and Asn72 not glycosylated. Amino acids at three positions, i.e. 142, 143, and 155, could not be detected during sequence analysis. Since the gene sequence codes for Ser, Thr, and Thr at these positions (Martin, F. H., Suggs, S. V., Langley, K. E., Lu, H. S., Ting, J., Okino, K. H., Morris, C. F., McNiece, I. K., Jacobsen, F. W., Mendiaz, E. A., Birkett, N. C., Smith, K. C., Johnson, M. J., Parker, V. P., Flores, J. C., Patel, A. C., Fisher, E. F., Erjavec, H. O., Herrera, C. J., Wypych, J., Sachdev, R. K., Pope, J. A., Leslie, I., Wen, D., Lin, C. W., Cupples, R. L., and Zsebo, K. M. (1990) Cell 63, 203-211), they could be sites of O-linked carbohydrate attachment. The four cysteines form two intramolecular disulfide bonds, Cys4-Cys89 and Cys43-Cys138.     

Cell surface sulfhydryls are required for the cytotoxicity of diphtheria toxin but not of ricin in Chinese hamster ovary cells.

A previous study on cleavage of disulfide bonds in endocytosed model compounds had shown that an initial phase of cleavage was totally inhibited by membrane-impermeant sulfhydryl inhibitors and thus was mediated by cell surface sulfhydryls (Feener, E. P., Shen, W.-C., and Ryser, H. J.-P. (1990) J. Biol. Chem. 265, 18780-18785). This paper uses the same inhibitors (5,5'-dithiobis(2-nitrobenzoic acid) and p-chloromercuriphenylsulfonic acid) to examine the role of surface sulfhydryls in the cytotoxicity of diphtheria toxin (DT). Since the interchain disulfide of endocytosed DT must be cleaved prior to translocation of chain A from endosomes to cytoplasm, it was postulated that surface sulfhydryls might mediate the cleavage of that disulfide bond as well. Both sulfhydryl blockers did indeed markedly inhibit DT cytotoxicity. This effect was not due to inactivation of unbound DT, inhibition of receptor-mediated endocytosis, or impairment of acidification of endosomes. We conclude that cell surface sulfhydryls susceptible to blockage by 5,5'-dithiobis(2-nitro-benzoic acid) and p-chloromercuriphenylsulfonic acid are required for the cytotoxicity of DT and, most likely, for the reductive cleavage of DT's interchain disulfides. Ricin cytotoxicity was not decreased; this is consistent with the view that ricin reaches the cytoplasm from a late endocytic structure and with the finding that endocytosed disulfides are also cleaved in a cell fraction containing elements of the Golgi apparatus (Feener, E. P., Shen, W.-C., and Ryser, H. J.-P. (1990) J. Biol. Chem. 265, 18780-18785).     

The complete amino-acid sequence of the alpha and beta subunits of B-phycoerythrin from the rhodophytan alga Porphyridium cruentum

Determination of the complete amino-acid sequence of the subunits of B-phycoerythrin from Porphyridium cruentum has shown that the alpha subunit contains 164 amino-acid residues and the beta subunit contains 177 residues. When the sequences of B- and C-phycoerythrins are aligned with those of other phycobiliproteins, it is obvious that B-phycoerythrin lacks a deletion at beta-21-22 present in C-phycoerythrin. However, relative to C-phycoerythrin from Fremyella diplosiphon (Calothrix) (Sidler, W., Kumpf, B., Rüdiger, W. and Zuber, H. (1986) Biol. Chem. Hoppe-Seyler 367, 627-642), B-phycoerythrin has deletions at beta-141k-o, beta-142, beta-143, beta-147 and beta-148. The four singly-linked phycoerythrobilins at positions alpha-84, alpha-143a, beta-84 and beta-155, and the doubly-linked phycoerythrobilin at position beta-50/61 are at sites homologous to the attachment sites in C-phycoerythrin. The aspartyl residues (alpha-87, beta-87, and beta-39), that interact with the bilins at alpha-84, beta-84, and beta-155 in C-phycocyanin, are found in the homologous positions in B-phycoerythrin. B-Phycoerythrin, in common with other phycobiliproteins, contains a N gamma-methylasparagine residue at position beta-72.     

Functional effects of periodic tryptophan substitutions in the alpha M4 transmembrane domain of the Torpedo californica nicotinic acetylcholine receptor

Previous amino acid substitutions at the M4 domain of the Torpedo californica and mouse acetylcholine receptor suggested that the location of the substitution relative to the membrane-lipid interface and perhaps to the ion pore can be critical to the channel gating mechanism [Lasalde, J. A., Tamamizu, S., Butler, D. H., Vibat, C. R. T., Hung, B., and McNamee, M. G. (1996) Biochemistry 35, 14139-14148; Ortiz-Miranda, S. I., Lasalde, J. A., Pappone, P. A., and McNamee, M. G. (1997) J. Membr. Biol. 158, 17-30; Tamamizu, S., Lee, Y. H., Hung, B., McNamee, M. G., and Lasalde-Dominicci, J. A. (1999) J. Membr. Biol. 170, 157-164]. In this study, we introduce tryptophan substitutions at 12 positions (C412W, M415W, L416W, I417W, C418W, I419W, I420W, G421W, T422W, V423W, S424W, and V425W) along this postulated lipid-exposed segment M4 so that we can examine functional consequences on channel gating. The expression levels of mutants C412W, G421W, S424W, and V425W were almost the same as that of the wild type, whereas other mutants (M415W, L416W, C418W, I419W, I420W, T422W, and V423W) had relatively lower expression levels compared to that of the wild type as measured by iodinated alpha-bungarotoxin binding ([(125)I]-alpha-BgTx). Two positions (L416W and I419W) had less than 20% of the wild type expression level. I417W gave no detectable [(125)I]BgTx binding on the surface of oocyte, suggesting that this position might be involved in the AChR assembly, oligomerization, or transport to the cell membrane. The alphaV425W mutant exhibited a significant increase in the open channel probability with a moderate increase in the macroscopic response at higher ACh concentrations very likely due to channel block. The periodicity for the alteration of receptor assembly and ion channel function seems to favor a potential alpha-helical structure. Mutants that have lower levels of expression are clustered on one side of the postulated alpha-helical structure. Mutations that display normal expression and functional activity have been shown previously to face the membrane lipids by independent labeling studies. The functional analysis of these mutations will be presented and discussed in terms of possible structural models.     

Complete Genome Sequence of T4-Like Escherichia coli Bacteriophage HX01

Phage T4 is among the best-characterized biological systems (S. Kanamaru and F. Arisaka, Seikagaku 74:131-135, 2002; E. S. Miller et al., Microbiol. Mol. Biol. Rev. 67:86-156, 2003; W. B. Wood and H. R. Revel, Bacteriol. Rev. 40:847-868, 1976). To date, several genomes of T4-like bacteriophages are available in public databases but without any APEC bacteriophages (H. Jiang et al., Arch. Virol. 156:1489-1492, 2011; L. Kaliniene, V. Klausa, A. Zajanckauskaite, R. Nivinskas, and L. Truncaite, Arch. Virol. 156:1913-1916, 2011; J. H. Kim et al., Vet. Microbiol. 157:164-171, 2012; W. C. Liao et al., J. Virol. 85:6567-6578, 2011). We isolated a bacteriophage from a duck factory, named HX01, that infects avian pathogenic Escherichia coli (APEC). Sequence and morphological analyses revealed that phage HX01 is a T4-like bacteriophage and belongs to the family Myoviridae. Here, we announce the complete genome sequence of phage HX01 and report the results of our analysis.     

Proximity of cytoplasmic and periplasmic loops in NhaA Na+/H+ antiporter of Escherichia coli as determined by site-directed thiol cross-linking

The unique trypsin cleavable site of NhaA, the Na(+)/H(+) antiporter of Escherichia coli, was exploited to detect a change in mobility of cross-linked products of NhaA by polyacrylamide gel electrophoresis. Double-Cys replacements were introduced into loops, one on each side of the trypsin cleavage site (Lys 249). The proximity of paired Cys residues was assessed by disulfide cross-linking of the two tryptic fragments, using three homobifunctional cross-linking agents: 1,6-bis(maleimido)hexane (BMH), N,N'-o-phenylenedimaleimide (o-PDM), and N,N'-p-phenylenedimaleimide (p-PDM). The interloop cross-linking was found to be very specific, indicating that the loops are not merely random coils that interact randomly. In the periplasmic side of NhaA, two patterns of cross-linking are observed: (a) all three cross-linking reagents cross-link very efficiently between the double-Cys replacements A118C/S286C, N177C/S352C, and H225C/S352C; (b) only BMH cross-links the double-Cys replacements A118C/S352C, N177C/S286C, and H225C/S286C. In the cytoplasmic side of NhaA, three patterns of cross-linking are observed: (a) all three cross-linking reagents cross-link very efficiently the pairs of Cys replacements L4C/E252C, S146C/L316C, S146C/R383C, and E241C/E252C; (b) BMH and p-PDM cross-link efficiently the pairs of Cys replacements S87C/E252C, S87C/L316C, and S146C/E252C; (c) none of the reagents cross-links the double-Cys replacements L4C/L316C, L4C/R383C, S87C/R383C, A202C/E252C, A202C/L316C, A202C/R383C, E241C/L316C, and E241C/R383C. The data reveal that the N-terminus and loop VIII-IX that have previously been shown to change conformation with pH are in close proximity within the NhaA protein. The data also suggest close proximity between N-terminal and C-terminal helices at both the cytoplasmic and the periplasmic face of NhaA.