In vivo characterization of the bacterial intramembrane-cleaving protease RseP using the heme binding tag-based assay iCliPSpy

Regulated intramembrane proteolysis (RIP) describes the protease-dependent cleavage of transmembrane proteins within the hydrophobic core of cellular membranes. Intramembrane-cleaving proteases (I-CliPs) that catalyze these reactions are found in all kingdoms of life and are involved in a wide range of cellular processes, including signaling and protein homeostasis. I-CLiPs are multispanning membrane proteins and represent challenging targets in structural and enzyme biology. Here we introduce iCLiPSpy, a simple assay to study I-CLiPs in vivo. To allow easy detection of enzyme activity, we developed a heme-binding reporter based on TNFα that changes color after I-CLiP-mediated proteolysis. Co-expression of the protease and reporter in Escherichia coli (E. coli) results in white or green colonies, depending on the activity of the protease. As a proof of concept, we use this assay to study the bacterial intramembrane-cleaving zinc metalloprotease RseP in vivo. iCLiPSpy expands the methodological repertoire for identifying residues important for substrate binding or activity of I-CLiPs and can in principle be adapted to a screening assay for the identification of inhibitors or activators of I-CLiPs, which is of great interest for proteases being explored as biomedical targets.

Heme binding of transmembrane signaling proteins undergoing regulated intramembrane proteolysis

Transmembrane signaling proteins play a crucial role in the transduction of information across cell membranes. One function of regulated intramembrane proteolysis (RIP) is the release of signaling factors from transmembrane proteins. To study the role of transmembrane domains (TMDs) in modulating structure and activity of released signaling factors, we purified heterologously expressed human transmembrane proteins and their proteolytic processing products from Escherichia coli. Here we show that CD74 and TNFα are heme binding proteins. Heme coordination depends on both a cysteine residue proximal to the membrane and on the oligomerization of the TMD. Furthermore, we show that the various processing products have different modes of heme coordination. We suggest that RIP changes the mode of heme binding of these proteins and generates heme binding peptides with yet unexplored functions. The identification of a RIP modulated cofactor binding of transmembrane signaling proteins sheds new light on the regulation of cell signaling pathways.

Kupke et al. study regulated intramembrane proteolysis (RIP) using recombinant transmembrane proteins CD74 and TNFα and find they are heme binding proteins that change their mode of heme binding after proteolytic processing. These data suggest that RIP of type II transmembrane proteins can generate intracellular heme sensor peptides.

A ternary membrane protein complex anchors the spindle pole body in the nuclear envelope in budding yeast

In budding yeast (Saccharomyces cerevisiae) the multilayered spindle pole body (SPB) is embedded in the nuclear envelope (NE) at fusion sites of the inner and outer nuclear membrane. The SPB is built from 18 different proteins, including the three integral membrane proteins Mps3, Ndc1, and Mps2. These membrane proteins play an essential role in the insertion of the new SPB into the NE. How the huge core structure of the SPB is anchored in the NE has not been investigated thoroughly until now. The present model suggests that the NE protein Mps2 interacts via Bbp1 with Spc29, one of the coiled-coil proteins forming the central plaque of the SPB. To test this model, we purified and reconstituted the Mps2-Bbp1 complex from yeast and incorporated the complex into liposomes. We also demonstrated that Mps2-Bbp1 directly interacts with Mps3 and Ndc1. We then purified Spc29 and reconstituted the ternary Mps2-Bbp1-Spc29 complex, proving that Bbp1 can simultaneously interact with Mps2 and Spc29 and in this way link the central plaque of the SPB to the nuclear envelope. Interestingly, Bbp1 induced oligomerization of Spc29, which may represent an early step in SPB duplication. Together, this analysis provides important insights into the interaction network that inserts the new SPB into the NE and indicates that the Mps2-Bbp1 complex is the central unit of the SPB membrane anchor.

Targeting of Nbp1 to the inner nuclear membrane is essential for spindle pole body duplication

Spindle pole bodies (SPBs), like nuclear pore complexes, are embedded in the nuclear envelope (NE) at sites of fusion of the inner and outer nuclear membranes. A network of interacting proteins is required to insert a cytoplasmic SPB precursor into the NE. A central player of this network is Nbp1 that interacts with the conserved integral membrane protein Ndc1. Here, we establish that Nbp1 is a monotopic membrane protein that is essential for SPB insertion at the inner face of the NE. In vitro and in vivo studies identified an N-terminal amphipathic α-helix of Nbp1 as a membrane-binding element, with crucial functions in SPB duplication. The karyopherin Kap123 binds to a nuclear localization sequence next to this amphipathic α-helix and prevents unspecific tethering of Nbp1 to membranes. After transport into the nucleus, Nbp1 binds to the inner nuclear membrane. These data define the targeting pathway of a SPB component and suggest that the amphipathic α-helix of Nbp1 is important for SPB insertion into the NE from within the nucleus.

Biochemical and physiological characterization of Arabidopsis thaliana AtCoAse: a Nudix CoA hydrolyzing protein that improves plant development

CoA is required for many synthetic and degradative reactions in intermediary metabolism and is the principal acyl carrier in prokaryotic and eukaryotic cells. CoA is synthesized in five steps from pantothenate, and recently, the CoA biosynthetic genes of Arabidopsis have all been identified and characterized. Here, we demonstrate the biochemical and physiological characterization of a pyrophosphatase from Arabidopsis thaliana, called AtCoAse (locus tag At5g45940), cleaving CoA to 4'-phosphopantetheine and 3',5'-adenosine-diphosphate in the presence of Mg2+/Mn2+ ions. The CoA cleaving enzyme isa member of the Nudix hydrolases, pyrophosphatases that hydrolyze nucleoside diphosphates, already described as CoAse and now further characterized in detail by us. Mutagenesis of residues of the so-called Nudix and NuCoA motifs drastically reduced the hydrolase activity. AtCoAse is not absolute specific for CoA, and in the presence of Mn2+ ions, a minor hydrolyzing activity was observed with NADH as substrate. The AtCoAse expression is ubiquitous, strongly in flower and unaffected by abiotic stress. The immunohistochemical localization indicates that the AtCoAse protein is observed in the cytoplasm of distinct cells types from different heterotrophic Arabidopsis tissues, mainly restricted to the vascular elements of the root and shoot and in flower and developing embryo. Transgenic Arabidopsis plants, with increased AtCoAse expression, show altered growth rates and development, expanding their live cycle far away from the wild-type.

4'-phosphopantetheine biosynthesis in Archaea

Coenzyme A as the principal acyl carrier is required for many synthetic and degradative reactions in intermediary metabolism. It is synthesized in five steps from pantothenate, and recently the CoaA biosynthetic genes of eubacteria, plants, and human were all identified and cloned. In most bacteria, the so-called Dfp proteins catalyze the synthesis of the coenzyme A precursor 4'-phosphopantetheine. Dfp proteins are bifunctional enzymes catalyzing the synthesis of 4'-phosphopantothenoylcysteine (CoaB activity) and its decarboxylation to 4'-phosphopantetheine (CoaC activity). Here, we demonstrate the functional characterization of the CoaB and CoaC domains of an archaebacterial Dfp protein. Both domains of the Methanocaldococcus jannaschii Dfp protein were purified as His tag proteins, and their enzymatic activities were then identified and characterized by site-directed mutagenesis. Although the nucleotide binding motif II of the CoaB domain resembles that of eukaryotic enzymes, Methanocaldococcus CoaB is a CTP- and not an ATP-dependent enzyme, as shown by detection of the 4'-phosphopantothenoyl-CMP intermediate. The proposed 4'-phosphopantothenoylcysteine binding clamp of the Methanocaldococcus CoaC activity differs significantly from those of other characterized CoaC proteins. In particular, the active site cysteine residue, which otherwise is involved in the reduction of an aminoenethiol reaction intermediate, is not present. Moreover, the conserved Asn residue of the PXMNXXMW motif, which contacts the carboxyl group of 4'-phosphopantothenoylcysteine, is exchanged for His.

Structural basis of CTP-dependent peptide bond formation in coenzyme A biosynthesis catalyzed by Escherichia coli PPC synthetase

Phosphopantothenoylcysteine (PPC) synthetase forms a peptide bond between 4'-phosphopantothenate and cysteine in coenzyme A biosynthesis. PPC synthetases fall into two classes: eukaryotic, ATP-dependent and eubacterial, CTP-dependent enzymes. We describe the first crystal structure of E. coli PPC synthetase as a prototype of bacterial, CTP-dependent PPC synthetases. Structures of the apo-form and the synthetase complexed with CTP, the activated acyl-intermediate, 4'-phosphopantothenoyl-CMP, and with the reaction product CMP provide snapshots along the reaction pathway and detailed insight into substrate binding and the reaction mechanism of peptide bond formation. Binding of the phosphopantothenate moiety of the acyl-intermediate in a cleft at the C-terminal end of the central beta sheet of the dinucleotide binding fold is accomplished by an otherwise flexible flap. A second disordered loop may control access of cysteine to the active site. The conservation of functionalities involved in substrate binding and catalysis provides insight into similarities and differences of prokaryotic and eukaryotic PPC synthetases.

Active-site residues and amino acid specificity of the bacterial 4'-phosphopantothenoylcysteine synthetase CoaB

In bacteria, coenzyme A is synthesized in five steps from d-pantothenate. The Dfp flavoprotein catalyzes the synthesis of the coenzyme A precursor 4'-phosphopantetheine from 4'-phosphopantothenate and cysteine using the cofactors CTP and flavine mononucleotide via the phosphopeptide-like compound 4'-phosphopantothenoylcysteine. The synthesis of 4'-phosphopantothenoylcysteine is catalyzed by the C-terminal CoaB domain of Dfp and occurs via the acyl-cytidylate intermediate 4'-phosphopantothenoyl-CMP in two half reactions. In this new study, the molecular characterization of the CoaB domain is continued. In addition to the recently described residue Asn210, two more active-site residues, Arg206 and Ala276, were identified and shown to be involved in the second half reaction of the (R)-4'-phospho-N-pantothenoylcysteine synthetase. The proposed intermediate of the (R)-4'-phospho-N-pantothenoylcysteine synthetase reaction, 4'-phosphopantothenoyl-CMP, was characterized by MALDI-TOF MS and it was shown that the intermediate is copurified with the mutant His-CoaB N210H/K proteins. Therefore, His-CoaB N210H and His-CoaB N210K will be of interest to elucidate the crystal structure of CoaB complexed with the reaction intermediate. Wild-type His-CoaB is not absolutely specific for cysteine and can couple derivatives of cysteine to 4'-phosphopantothenate. However, no phosphopeptide-like structure is formed with serine. Molecular characterization of the temperature-sensitive Escherichia coli dfp-1 mutant revealed that the residue adjacent to Ala276, Ala275 of the strictly conserved AAVAD(275-279) motif, is exchanged for Thr.

4'-phosphopantetheine and coenzyme A biosynthesis in plants

Coenzyme A is required for many synthetic and degradative reactions in intermediary metabolism and is the principal acyl carrier in prokaryotic and eukaryotic cells. Coenzyme A is synthesized in five steps from pantothenate, and recently the CoaA biosynthetic genes in bacteria and human have all been identified and characterized. Coenzyme A biosynthesis in plants is not fully understood, and to date only the AtHAL3a (AtCoaC) gene of Arabidopsis thaliana has been cloned and identified as 4'-phosphopantothenoylcysteine (PPC) decarboxylase (Kupke, T., Hernández-Acosta, P., Steinbacher, S., and Culiáñez-Macià, F. A. (2001) J. Biol. Chem. 276, 19190-19196). Here, we demonstrate the cloning of the four missing genes, purification of the enzymes, and identification of their functions. In contrast to bacterial PPC synthetases, the plant synthetase is not CTP-but ATP-dependent. The complete biosynthetic pathway from pantothenate to coenzyme A was reconstituted in vitro by adding the enzymes pantothenate kinase (AtCoaA), 4'-phosphopantothenoylcysteine synthetase (AtCoaB), 4'-phosphopantothenoylcysteine decarboxylase (AtCoaC), 4'-phosphopantetheine adenylyltransferase (AtCoaD), and dephospho-coenzyme A kinase (AtCoaE) to a mixture containing pantothenate, cysteine, ATP, dithiothreitol, and Mg2+.

The influence of His94 and Pro149 in modulating the activity of V. cholerae DsbA

DsbA is the primary catalyst of disulfide bond formation in the periplasm of gram-negative bacteria. Numerous theoretical and experimental studies have been undertaken to determine the molecular mechanisms by which DsbA acts as a potent oxidant, whereas the homologous cytoplasmic protein, thioredoxin, acts as a reductant. Many of these studies have focused on the nature of the two residues that lie between the active-site cysteines. Although these are clearly important, they are not solely responsible for the differences in activity between these thiol-disulfide oxidoreductases. Q97 in the helical domain of E. coli DsbA has been implicated in influencing the redox potential of E. coli DsbA. In V. cholerae DsbA, the analogous residue is H94. In this study, the effect of H94 on the oxidase activity of DsbA is examined, along with the role of the conserved cis-proline residue P149. The DsbA mutant H94L shows a nearly fourfold increase in activity over the wild-type enzyme. To our knowledge, this is the first time an increase in the normal activity of a thiol-disulfide oxidoreductase has been reported. Potential reasons for this increase in activity are discussed.

Structure of MrsD, an FAD-binding protein of the HFCD family

MrsD from Bacillus sp. HIL-Y85/54728 is a member of the HFCD (homo-oligomeric flavin-containing Cys decarboxylases) family of flavoproteins and is involved in the biosynthesis of the lantibiotic mersacidin. It catalyses the oxidative decarboxylation of the C-terminal cysteine residue of the MrsA precursor peptide of mersacidin, yielding a (Z)-enethiol intermediate as the first step in the formation of the unusual amino acid S-[(Z)-2-aminovinyl]-methyl-D-cysteine. Surprisingly, MrsD was found to bind FAD, in contrast to the three other characterized members of the HFCD family, which bind FMN. To determine the molecular discriminators of FAD binding within the HFCD family, the crystal structure of MrsD was analyzed at a resolution of 2.54 A. Crystals of space group F432 contain one MrsD monomer in the asymmetric unit. However, a Patterson search with EpiD-derived models failed. Based on the consideration that the dodecameric MrsD particle of tetrahedral symmetry resembles the quaternary structure of EpiD, rotational and translational parameters were derived from the geometric consideration that the MrsD dodecamer is generated from a monomer by crystallographic symmetry around the position (1/4, 1/4, 1/4) of the unit cell. A structural comparison with the FMN-binding members of the HFCD family EpiD and AtHAL3a shows conserved sequence motifs in contact with the flavin's pyrimidine ring but divergent environments for the dimethylbenzene ring of the isoalloxazine moiety. The position of the ribityl chain differs in MrsD from that found in EpiD and AtHAL3a. However, the FMN-phosphate binding sites are also highly conserved in their exact positions. In all three cases, the flavin cofactor is bound to a structurally conserved region of the Rossmann-fold monomer, exposing its Re side for catalysis. The adenosyl phosphate of FAD is anchored in a well defined binding site and the adenosine moieties are oriented towards the interior of the hollow particle, where three of them pack against each other around the threefold axis of a trimeric facet.

Crystal structure of the plant PPC decarboxylase AtHAL3a complexed with an ene-thiol reaction intermediate

The Arabidopsis thaliana protein AtHAL3a decarboxylates 4'-phosphopantothenoylcysteine to 4'-phosphopantetheine, a step in coenzyme A biosynthesis. Surprisingly, this decarboxylation reaction is carried out as an FMN-dependent redox reaction. In the first half-reaction, the side-chain of the cysteine residue of 4'-phosphopantothenoylcysteine is oxidised and the thioaldehyde intermediate decarboxylates spontaneously to the 4'-phosphopantothenoyl-aminoethenethiol intermediate. In the second half-reaction this compound is reduced to 4'-phosphopantetheine and the FMNH(2) cofactor is re-oxidised. The active site mutant C175S is unable to perform this reductive half-reaction. Here, we present the crystal structure of the AtHAL3a mutant C175S in complex with the reaction intermediate pantothenoyl-aminoethenethiol and FMNH(2). The geometry of binding suggests that reduction of the C(alpha)=C(beta) double bond of the intermediate can be performed by direct hydride-transfer from N5 of FMNH(2) to C(beta) of the aminoethenethiol-moiety supported by a protonation of C(alpha) by Cys175. The binding mode of the substrate is very similar to that previously observed for a pentapeptide to the homologous enzyme EpiD that introduces the aminoethenethiol-moiety as final reaction product at the C terminus of peptidyl-cysteine residues. This finding further supports our view that these homologous enzymes form a protein family of homo-oligomeric flavin-containing cysteine decarboxylases, which we have termed HFCD family.

Molecular characterization of the 4'-phosphopantothenoylcysteine synthetase domain of bacterial dfp flavoproteins

In bacteria, coenzyme A is synthesized in five steps from pantothenate. The flavoprotein Dfp catalyzes the synthesis of the coenzyme A precursor 4'-phosphopantetheine in the presence of 4'-phosphopantothenate, cysteine, CTP, and Mg(2+) (Strauss, E., Kinsland, C., Ge, Y., McLafferty, F. W., and Begley, T. P. (2001) J. Biol. Chem. 276, 13513-13516). It has been shown that the NH(2)-terminal domain of Dfp has 4'-phosphopantothenoylcysteine decarboxylase activity (Kupke, T., Uebele, M., Schmid, D., Jung, G., Blaesse, M., and Steinbacher, S. (2000) J. Biol. Chem. 275, 31838-31846). Here I demonstrate that the COOH-terminal CoaB domain of Dfp catalyzes the synthesis of 4'-phosphopantothenoylcysteine. The exchange of conserved amino acid residues within the CoaB domain revealed that the synthesis of 4'-phosphopantothenoylcysteine occurs in two half-reactions. Using the mutant protein His-CoaB N210D the putative acyl-cytidylate intermediate of 4'-phosphopantothenate was detectable. The same intermediate was detectable for the wild-type CoaB enzyme if cysteine was omitted in the reaction mixture. Exchange of the conserved Lys(289) residue, which is part of the strictly conserved (289)KXKK(292) motif of the CoaB domain, resulted in complete loss of activity with neither the acyl-cytidylate intermediate nor 4'-phosphopantothenoylcysteine being detectable. Gel filtration experiments indicated that CoaB forms dimers. Residues that are important for dimerization are conserved in CoaB proteins from eubacteria, Archaea, and eukaryotes.

Molecular characterization of the Arabidopsis thaliana flavoprotein AtHAL3a reveals the general reaction mechanism of 4'-phosphopantothenoylcysteine decarboxylases

The Arabidopsis thaliana flavoprotein AtHAL3a, which is linked to plant growth and salt and osmotic tolerance, catalyzes the decarboxylation of 4'-phosphopantothenoylcysteine to 4'-phosphopantetheine, a key step in coenzyme A biosynthesis. AtHAL3a is similar in sequence and structure to the LanD enzymes EpiD and MrsD, which catalyze the oxidative decarboxylation of peptidylcysteines. Therefore, we hypothesized that the decarboxylation of 4'-phosphopantothenoylcysteine also occurs via an oxidatively decarboxylated intermediate containing an aminoenethiol group. A set of AtHAL3a mutants were analyzed to detect such an intermediate. By exchanging Lys(34), we found that AtHAL3a is not only able to decarboxylate 4'-phosphopantothenoylcysteine but also pantothenoylcysteine to pantothenoylcysteamine. Exchanging residues within the substrate binding clamp of AtHAL3a (for example of Gly(179)) enabled the detection of the proposed aminoenethiol intermediate when pantothenoylcysteine was used as substrate. This intermediate was characterized by its high absorbance at 260 and 280 nm, and the removal of two hydrogen atoms and one molecule of CO(2) was confirmed by ultrahigh resolution mass spectrometry. Using the mutant AtHAL3a C175S enzyme, the product pantothenoylcysteamine was not detectable; however, oxidatively decarboxylated pantothenoylcysteine could be identified. This result indicates that reduction of the aminoenethiol intermediate depends on a redox-active cysteine residue in AtHAL3a.

The flavoprotein MrsD catalyzes the oxidative decarboxylation reaction involved in formation of the peptidoglycan biosynthesis inhibitor mersacidin

The lantibiotic mersacidin inhibits peptidoglycan biosynthesis by binding to the peptidoglycan precursor lipid II. Mersacidin contains an unsaturated thioether bridge, which is proposed to be synthesized by posttranslational modifications of threonine residue +15 and the COOH-terminal cysteine residue of the mersacidin precursor peptide MrsA. We show that the flavoprotein MrsD catalyzes the oxidative decarboxylation of the COOH-terminal cysteine residue of MrsA to an aminoenethiol residue. MrsD belongs to the recently described family of homo-oligomeric flavin-containing Cys decarboxylases (i.e., the HFCD protein family). Members of this protein family include the bacterial Dfp proteins (which are involved in coenzyme A biosynthesis), eukaryotic salt tolerance proteins, and further oxidative decarboxylases such as EpiD. In contrast to EpiD and Dfp, MrsD is a FAD and not an FMN-dependent flavoprotein. HFCD enzymes are characterized by a conserved His residue which is part of the active site. Exchange of this His residue for Asn led to inactivation of MrsD. The lantibiotic-synthesizing enzymes EpiD and MrsD have different substrate specificities.

Electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry to reveal the substrate specificity of the peptidyl-cysteine decarboxylase EpiD

The microbial flavoenzyme EpiD catalyzes the oxidative decarboxylation of peptidyl-cysteines to peptidyl-aminoenethiols. These unusual C-terminally modified peptides are intermediates in the biosynthesis of the tetracyclic peptide antibiotic epidermin, which belongs to the lantibiotics family. The peptide SFNSYCC represents the C-terminal partial sequence of the natural precursor peptide EpiA. EpiA is posttranslationally modified to form finally the lantibiotic epidermin. The substrate specificity of EpiD was investigated using high-resolution mass spectrometry and the heptapeptide library SFNSXCC. The enzymatic conversion of particular peptides can be observed by a mass loss of m/z 46. In contrast to the previously used triple quadrupole instrument, electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry (ESI-FTICR-MS) was able to resolve and detect all precursor and converted peptides with identical nominal masses in a single measurement, avoiding the necessity to investigate single peptides. Furthermore, a new substrate SFNSCCC of the enzyme EpiD was detected within the reaction mixture.

Arabidopsis thaliana flavoprotein AtHAL3a catalyzes the decarboxylation of 4'-Phosphopantothenoylcysteine to 4'-phosphopantetheine, a key step in coenzyme A biosynthesis

The Arabidopsis thaliana flavoprotein AtHAL3a is related to plant growth and salt and osmotic tolerance. AtHAL3a shows sequence homology to the bacterial flavoproteins EpiD and Dfp. EpiD, Dfp, and AtHAL3a are members of the homo-oligomeric flavin-containing Cys decarboxylase (HFCD) protein family. We demonstrate that AtHAL3a catalyzes the decarboxylation of (R)-4'-phospho-N-pantothenoylcysteine to 4'-phosphopantetheine. This key step in coenzyme A biosynthesis is catalyzed in bacteria by the Dfp proteins. Exchange of His-90 of AtHAL3a for Asn led to complete inactivation of the enzyme. Dfp and AtHAL3a are characterized by a shortened substrate binding clamp compared with EpiD. Exchange of the cysteine residue of the conserved ACGD motif of this binding clamp resulted in loss of (R)-4'-phospho-N-pantothenoylcysteine decarboxylase activity. Based on the crystal structures of EpiD H67N with bound substrate peptide and of AtHAL3a, we present a model for the binding of (R)-4'-phospho-N-pantothenoylcysteine to AtHAL3a.

Molecular characterization of the 4'-phosphopantothenoylcysteine decarboxylase domain of bacterial Dfp flavoproteins

The NH(2)-terminal domain of the bacterial flavoprotein Dfp catalyzes the decarboxylation of (R)-4'-phospho-N-pantothenoylcysteine to 4'-phosphopantetheine, a key step in coenzyme A biosynthesis. Dfp proteins, LanD proteins (for example EpiD, which is involved in epidermin biosynthesis), and the salt tolerance protein AtHAL3a from Arabidopsis thaliana are homooligomeric flavin-containing Cys decarboxylases (HFCD protein family). The crystal structure of the peptidyl-cysteine decarboxylase EpiD complexed with a pentapeptide substrate has recently been determined. The peptide is bound by an NH(2)-terminal substrate binding helix, residue Asn(117), which contacts the cysteine residue of the substrate, and a COOH-terminal substrate recognition clamp. The conserved motif G-G/S-I-A-X-Y-K of the Dfp proteins aligns partly with the substrate binding helix of EpiD. Point mutations within this motif resulted in loss of coenzyme binding (G14S) or in significant decrease of Dfp activity (G15A, I16L, A17D, K20N, K20Q). Exchange of Asn(125) of Dfp, which corresponds to Asn(117) of EpiD, and exchange of Cys(158), which is within the proposed substrate recognition clamp of Dfp, led to inactivity of the enzyme. Molecular analysis of the conditional lethality of the Escherichia coli dfp-707 mutant revealed that the single point mutation G11D of Dfp is related to decreased amounts of soluble Dfp protein at 37 degrees C.

Crystal structure of the peptidyl-cysteine decarboxylase EpiD complexed with a pentapeptide substrate

Epidermin from Staphylococcus epidermidis Tü3298 is an antimicrobial peptide of the lantibiotic family that contains, amongst other unusual amino acids, S:-[(Z:)- 2-aminovinyl]-D-cysteine. This residue is introduced by post-translational modification of the ribosomally synthesized precursor EpiA. Modification starts with the oxidative decarboxylation of its C-terminal cysteine by the flavoprotein EpiD generating a reactive (Z:)-enethiol intermediate. We have determined the crystal structures of EpiD and EpiD H67N in complex with the substrate pentapeptide DSYTC at 2.5 A resolution. Rossmann-type monomers build up a dodecamer of 23 point symmetry with trimers disposed at the vertices of a tetrahedron. Oligomer formation is essential for binding of flavin mononucleotide and substrate, which is buried by an otherwise disordered substrate recognition clamp. A pocket for the tyrosine residue of the substrate peptide is formed by an induced fit mechanism. The substrate contacts flavin mononucleotide only via Cys-Sgamma, suggesting its oxidation as the initial step. A thioaldehyde intermediate could undergo spontaneous decarboxylation. The unusual substrate recognition mode and the type of chemical reaction performed provide insight into a novel family of flavoproteins.

Molecular characterization of lantibiotic-synthesizing enzyme EpiD reveals a function for bacterial Dfp proteins in coenzyme A biosynthesis

The lantibiotic-synthesizing flavoprotein EpiD catalyzes the oxidative decarboxylation of peptidylcysteines to peptidyl-aminoenethiols. The sequence motif responsible for flavin coenzyme binding and enzyme activity is conserved in different proteins from all kingdoms of life. Dfp proteins of eubacteria and archaebacteria and salt tolerance proteins of yeasts and plants belong to this new family of flavoproteins. The enzymatic function of all these proteins was not known, but our experiments suggested that they catalyze a similar reaction like EpiD and/or may have similar substrates and are homododecameric flavoproteins. We demonstrate that the N-terminal domain of the Escherichia coli Dfp protein catalyzes the decarboxylation of (R)-4'-phospho-N-pantothenoylcysteine to 4'-phosphopantetheine. This reaction is essential for coenzyme A biosynthesis.

In vivo reaction of affinity-tag-labelled epidermin precursor peptide with flavoenzyme EpiD

The Staphylococcus epidermidis genes encoding the His-tag-labelled epidermin precursor peptide EpiA and the flavoenzyme EpiD or the mutant protein EpiD-G93D, which lacks the coenzyme, were co-expressed and the proteins were synthesized in vivo in Escherichia coli. Only in the presence of EpiD was the precursor peptide converted to a reaction product with a decrease in mass of 44-46 Da. This result confirms the in vitro experiments carried out with purified EpiA and purified EpiD from Staphylococcus epidermidis [Kupke et al. (1994) J. Biol. Chem. 269, 5653-5659]. EpiD catalyzes the oxidative decarboxylation of the C-terminal cysteine residue of EpiA to a [Z]-enethiol structure. In the presence of EpiD, the amount of purified (modified) peptide EpiA was several-fold higher than in the presence of EpiD-G93D, indicating that the stabilization of EpiA against proteolysis is due to an interaction with EpiD or to the presence of the C-terminal modification. The presented experimental approach will be valuable for the analysis of enzymes that catalyze posttranslational modification reaction of peptides and proteins.

The enethiolate anion reaction products of EpiD. Pka value of the enethiol side chain is lower than that of the thiol side chain of peptides

One of the steps involved in the biosynthesis of the lantibiotic epidermin is the oxidative decarboxylation reaction of peptides catalyzed by the flavoenzyme EpiD. EpiD catalyzes the formation of a (Z)-enethiol derivative from the C-terminal cysteine residue of the precursor peptide of epidermin and related peptides. The UV-visible spectra of the reaction products of EpiD are pH-dependent, indicating that the enethiol side chain is converted to an enethiolate anion. The pKa value of the enethiol group was determined to be 6.0 and is substantially lower than the pKa value of the thiol side chain of cysteine residues. The increased acid strength of the enethiol side chain compared with that of the thiol group is attributed to the resonance stabilization of the negative charge of the anion.

Expression, purification, and characterization of EpiC, an enzyme involved in the biosynthesis of the lantibiotic epidermin, and sequence analysis of Staphylococcus epidermidis epiC mutants

The plasmid-encoded epidermin biosynthetic gene epiC of Staphylococcus epidermidis Tü3298 was expressed in Escherichia coli by using the T7 RNA polymerase-promoter system, and the gene product EpiC was identified by Western blotting (immunoblotting) with an anti-EpiC-peptide antiserum. EpiC was a hydrophobic but soluble protein. EpiC was purified by hydrophobic-interaction chromatography. The determined amino-terminal amino acid sequence was M I N I N N I .... The electrophoretic migration behavior of EpiC depended on the oxidation state of the enzyme, indicating the formation of an intramolecular disulfide bridge between C-274 and C-321. The cysteine residues in the motifs WC-274YG and C-321HG of EpiC are conserved in all lantibiotic enzymes of the C type (so-called LanC proteins) and in the CylM protein. Mutated epiC genes from S. epidermidis epiC mutants were cloned and expressed in E. coli. Sequence analysis revealed that the mutations occurred in the two motifs -S-X-X-X-G-X-X-G- and -N-X-G-X-A-H-G-X-X-G-, which are conserved in all LanC proteins. For the investigation of EpiC-EpiA interactions, precursor peptide EpiA was coupled to N-hydroxysuccinimide-activated Sepharose High Performance Material (HiTrap). Under reducing conditions, EpiC was retarded on the EpiA-HiTrap column. In the incubation experiments, EpiC did not react with EpiA, with proepidermin, or with oxidative decarboxylated peptides.

Post-translational modifications of lantibiotics

Several newly reported post-translational modification reactions are involved in lantibiotic biosynthesis. A short overview of the present knowledge on the post-translational modifications and on the enzymes involved in lantibiotic biosynthesis is given. The oxidative decarboxylation of the epidermin precursor peptide EpiA is described in detail. The FMN-containing oxidoreductase EpiD is involved in the formation of the C-terminal S-[(Z)-2-aminovinyl]-D-cysteine residue of epidermin: under reducing conditions the side chain of the C-terminal cysteine residue of EpiA is converted to an enethiol. EpiD has no absolute substrate specificity and can be used for modification of peptides having the C-terminal consensus motif [V/I/L/(M)/F/Y/W]-[A/S/V/T/C/(I/L)]-C.

Protein engineering of lantibiotics

Whereas protein engineering of enzymes and structural proteins nowadays is an established research tool for studying structure-function relationships of polypeptides and for improving their properties, the engineering of posttranslationally modified peptides, such as the lantibiotics, is just coming of age. The engineering of lantibiotics is less straightforward than that of unmodified proteins, since expression systems should be developed not only for the structural genes but also for the genes encoding the biosynthetic enzymes, immunity protein and regulatory proteins. Moreover, correct posttranslational modification of specific residues could in many cases be a prerequisite for production and secretion of the active lantibiotic, which limits the number of successful mutations one can apply. This paper describes the development of expression systems for the structural lantibiotic genes for nisin A, nisin Z, gallidermin, epidermin and Pep5, and gives examples of recently produced site-directed mutants of these lantibiotics. Characterization of the mutants yielded valuable information on biosynthetic requirements for production. Moreover, regions in the lantibiotics were identified that are of crucial importance for antimicrobial activity. Eventually, this knowledge will lead to the rational design of lantibiotics optimally suited for fighting specific undesirable microorganisms. The mutants are of additional value for studies directed towards the elucidation of the mode of action of lantibiotics.

The biosynthesis of the lantibiotics epidermin, gallidermin, Pep5 and epilancin K7

Lantibiotics are antibiotic peptides that contain the rare thioether amino acids lanthionine and/or methyllanthionine. Epidermin, Pep5 and epilancin K7 are produced by Staphylococcus epidermidis whereas gallidermin (6L-epidermin) was isolated from the closely related species Staphylococcus gallinarum. The biosynthesis of all four lantibiotics proceeds from structural genes which code for prepeptides that are enzymatically modified to give the mature peptides. The genes involved in biosynthesis, processing, export etc. are found in gene clusters adjacent to the structural genes and code for transporters, immunity functions, regulatory proteins and the modification enzymes LanB, LanC and LanD, which catalyze the biosynthesis of the rare amino acids. LanB and LanC are responsible for the dehydration of the serine and threonine residues to give dehydroalanine and dehydrobutyrine and subsequent addition of cysteine SH-groups to the dehydro amino acids which results in the thioether rings. EpiD, the only LanD enzyme known so far, catalyzes the oxidative decarboxylation of the C-terminal cysteine of epidermin which gives the C-terminal S-aminovinylcysteine after addition of a dehydroalanine residue.

Serine protease EpiP from Staphylococcus epidermidis catalyzes the processing of the epidermin precursor peptide

The function of serine protease EpiP in epidermin biosynthesis was investigated. Epidermin is synthesized as a 52-amino-acid precursor peptide, EpiA, which is posttranslationally modified and processed to the mature 22-amino-acid peptide antibiotic. epiP was expressed in Staphylococcus carnosus with xylose-regulated expression vector pCX15. The cleavage of the unmodified EpiA precursor peptide to leader peptide and proepidermin by EpiP-containing culture filtrates of S. carnosus (pCX15epiP) was followed by reversed-phase chromatography and subsequent electrospray mass spectrometry.

Isolation and characterization of genetically engineered gallidermin and epidermin analogs

Gallidermin (Gdm) and epidermin (Epi) are highly homologous tetracyclic polypeptide antibiotics that are ribosomally synthesized by a Staphylococcus gallinarum strain and a Staphylococcus epidermidis strain, respectively. These antibiotics are secreted into media and are distinguished by the presence of the unusual amino acids lanthionine, 3-methyllanthionine, didehydrobutyrine, and S-(2-aminovinyl)-D-cysteine, which are formed by posttranslational modification. To study the substrate specificities of the modifying enzymes and to obtain variants that exhibit altered or new biological activities, we changed certain amino acids by performing site-specific mutagenesis with the Gdm and Epi structural genes (gdmA and epiA, respectively). S. epidermidis Tü3298/EMS6, an epiA mutant of the Epi-producing strain, was used as the expression host. This mutant synthesized Epi, Gdm, or analogs of these antibiotics when the appropriate genes were introduced on a plasmid. No Epi or Gdm analogs were isolated from the supernatant when (i) hydroxyamino acids involved in thioether amino acid formation were replaced by nonhydroxyamino acids (S3N and S19A); (ii) C residues involved in thioether bridging were deleted (delta C21, C22 and delta C22); or (iii) a ring amino acid was replaced by an amino acid having a completely different character (G10E and Y20G). A strong decrease in production was observed when S residues involved in thioether amino acid formation were replaced by T residues (S16T and S19T). A number of conservative changes at positions 6, 12, and 14 on the Gdm backbone were tolerated and led to analogs that had altered biological properties, such as enhanced antimicrobial activity (L6V) or a remarkable resistance to proteolytic degradation (A12L and Dhb14P). The T14S substitution led to simultaneous production of two Gdm species formed by incomplete posttranslational modification (dehydration) of the S-14 residue. The fully modified Dhb14Dha analog exhibited antimicrobial activity similar to that of Gdm, whereas the Dhb14S analog was less active. Both peptides were more sensitive to tryptic cleavage than Gdm was.

Oxidative decarboxylation of peptides catalyzed by flavoprotein EpiD. Determination of substrate specificity using peptide libraries and neutral loss mass spectrometry

The flavoprotein EpiD catalyzes the COOH-terminal oxidative decarboxylation of the lantibiotic precursor peptide EpiA. Variations of the COOH-terminal heptapeptide S1FNSYCC7 of EpiA were used for determining the substrate specificity of EpiD. When Cys7 was replaced by serine, cysteine-amide, homocysteine, or a thioether amino acid residue, no reaction with EpiD was observed. Heptapeptide libraries with one variable amino acid residue at positions 1-7 of the peptide substrate S1FNSYCC7 were incubated with EpiD, and the reaction products were identified by neutral loss mass spectrometry. When the penultimate cysteine residue Cys6 of the substrate peptide was replaced with Ser, Thr, Ala, or Val, the reaction still occurred. Tyr5 could be replaced with other hydrophobic amino acid residues. Mass spectrometry was used to compare the kinetics of the reaction of EpiD with various peptides. Peptide sequencing of the reaction products was performed by tandem mass spectrometry, confirming that the last cysteine residue was modified. The removal of the acid COOH-terminal carboxyl group was confirmed by determination of the isoelectric points of the reaction products. To study the interaction between EpiA and EpiD, EpiA was coupled to N-hydroxysuccinimide-activated Sepharose HiTrap material; EpiD was only retarded under reducing conditions.

On being informed you are HIV positive: experiences of Navy service members

This study addressed the experience of being told that one has become infected with the human immunodeficiency virus (HIV) while serving in the United States Navy. Responses to a questionnaire, administered to 150 HIV-positive service members, indicated that feelings of fear, shock, disbelief, and embarrassment were experienced by study participants upon learning of their HIV-positive status. The manner in which their HIV diagnosis was disclosed was generally viewed in favorable terms and more so in recent years relative to the earliest days of the Navy's HIV program. Having a medical officer as a disclosing official was associated with more negative experiences than was the case for other categories of disclosing officials. Lastly, post-disclosure events were often excessively stressful, and no improvement in this regard over 6 years of the Navy's HIV program was evident.

Producer immunity towards the lantibiotic Pep5: identification of the immunity gene pepI and localization and functional analysis of its gene product

The lantibiotic Pep5 is produced by Staphylococcus epidermidis 5. Pep5 production and producer immunity are associated with the 20-kb plasmid pED503. A 1.3-kb KpnI fragment of pED503, containing the Pep5 structural gene pepA, was subcloned into the Escherichia coli-Staphylococcus shuttle vector pCU1, and the recombinant plasmid pMR2 was transferred to the Pep5- and immunity-negative mutant S. epidermidis 5 Pep5- (devoid of pED503). This clone did not produce active Pep5 but showed the same degree of insensitivity towards Pep5 as did the wild-type strain. Sequencing of the 1.3-kb KpnI-fragment and analysis of mutants demonstrated the involvement of two genes in Pep5 immunity, the structural gene pepA itself and pepI, a short open reading frame upstream of pepA. To identify the 69-amino-acid pepI gene product, we constructed an E. coli maltose-binding protein-PepI fusion clone. The immunity peptide PepI was detected in the soluble and membrane fractions of the wild-type strain and the immune mutants (harboring the plasmids pMR2 and pMR11) by immunoblotting with anti-maltose-binding protein-PepI antiserum. Strains harboring either pepI without pepA or pepI with incomplete pepA were not immune and did not produce PepI. Washing the membrane with salts and EDTA reduced the amount of PepI in this fraction, and treatment with Triton X-100 almost completely removed the peptide. Furthermore, PepI was hydrolyzed by proteases added to osmotically stabilized protoplasts. This suggests that PepI is loosely attached to the outside of the cytoplasmic membrane. Proline uptake and efflux experiments with immune and nonimmune strains also indicated that PepI may act at the membrane site.

Mass spectroscopic analysis of a novel enzymatic reaction. Oxidative decarboxylation of the lantibiotic precursor peptide EpiA catalyzed by the flavoprotein EpiD

The epidermin biosynthetic reaction between the flavoprotein EpiD and the precursor peptide EpiA was investigated by reversed-phase chromatography and ion spray mass spectrometry. Several products with molecular masses 46 and 104 Da less than that of EpiA were observed; these results were confirmed by using an MBP-EpiD fusion protein as enzyme and the mutant peptides EpiAR-1Q and K-EpiA as substrates. The reaction was inhibited by Zn2+ ions. Modifications were localized in the C-terminal fragment of EpiA as shown by factor Xa cleavage of the products followed by mass spectrometry analysis. In addition, EpiD reacted with the precursor peptides and with proepidermin, indicating that the leader peptide is not necessary for the recognition of EpiA by EpiD. Sequence analysis of modified proepidermin revealed that at least the amino acids Ile(+1)-Tyr+20 are unmodified. The observed decrease in mass of 46 Da and the modification at the C terminus of EpiA is in agreement with the proposed enzymatic function of EpiD, the oxidative decarboxylation of the precursor peptide. In addition, the increased absorbance at 260 nm of the modified peptides indicates the presence of a thioenol group in the C-terminal proepidermin.

Purification and characterization of EpiA, the peptide substrate for post-translational modifications involved in epidermin biosynthesis

For the investigation of enzymes involved in epidermin biosynthesis it is necessary to produce sufficient amounts of preepidermin (EpiA) as a substrate and to design EpiA detection systems. Therefore, EpiA was expressed in Escherichia coli using a malE-epiA fusion. The identity of purified EpiA was confirmed by ion spray mass spectrometry and amino acid sequencing. For EpiA detection, anti-EpiA antisera were raised. Upon prolonged incubation, factor Xa not only cleaved EpiA from the fusion protein, but also less efficiently cleaved EpiA internally between R-1 and I+1. The internal factor Xa cleavage site of EpiA was masked by altering the sequence -A(-4)-E-P-R(-1)- to -A(-4)-E-P-Q(-1)- by site-directed mutagenesis.

Regulation of epidermin biosynthetic genes by EpiQ

We investigated the role of epiQ in the biosynthesis of the lantibiotic epidermin. epiQ was essential for epidermin production. It was shown that EpiQ controls epidermin production by transcriptionally activating the epiA promoter, used for transcription of most of the epidermin biosynthetic genes. Additional copies of epiQ increased epidermin production in the epidermin-producing wild-type strain Staphylococcus epidermidis Tü3298. The epiA promoter region was characterized by primer extension analysis. Two inverted repeats, putative operator sites for EpiQ binding, are located upstream of the -35 region and one is localized downstream of the -10 region. Crude protein extracts from S. epidermidis Tü3298 and epiQ expressing Escherichia coli cells led to gel mobility shifts of a DNA fragment bearing the inverted repeat which is located immediately upstream of the -35 region. DNA fragments bearing the other two inverted repeats were not shifted. The epiQ gene product could be detected by overexpression in the E. coli T7 system using antiserum raised against synthetic peptides of EpiQ. Furthermore, EpiQ, like other DNA-binding proteins, was shown to bind strongly to heparin sepharose.

Purification and characterization of EpiD, a flavoprotein involved in the biosynthesis of the lantibiotic epidermin

The plasmid-encoded epidermin biosynthesis gene, epiD, of Staphylococcus epidermidis Tü3298 was expressed in Escherichia coli by using both the malE fusion system and the T7 RNA polymerase-promoter system. EpiD was identified by Western blotting (immunoblotting) with anti-maltose-binding protein (MBP)-EpiD antiserum. EpiD and the MBP-EpiD fusion protein, which were mainly present in the soluble protein fraction, were purified from the respective E. coli clones. Purified EpiD showed the typical absorption spectrum of an oxidized flavoprotein with maxima at 274, 382, and 453 nm. The coenzyme released from EpiD by heat treatment was identified as flavin mononucleotide. S. epidermidis Tü3298/EMS11, containing a mutation within epiD, was unable to synthesize active epidermin. This mutated gene, epiD*, was cloned in E. coli and expressed as an MBP-EpiD* fusion protein. DNA sequencing of epiD* identified a point mutation that led to replacement of Gly-93 with Asp. Unlike MBP-EpiD, the fusion protein MBP-EpiD* could not bind flavin mononucleotide. We propose that EpiD catalyzes the removal of two reducing equivalents from the cysteine residue of the C-terminal meso-lanthionine to form a --C==C-- double bond and is therefore involved in formation of the unusual S-[(Z)-2-aminovinyl[-D-cysteine structure in epidermin.

Improved purification and biochemical properties of phosphatidylinositol-specific phospholipase C from Bacillus thuringiensis

Monophosphatidylinositol inositol phosphohydrolase (phosphatidylinositol-specific phospholipase C. PtdIns-PLC. EC 3.1.4.10) has been purified from a Bacillus thuringiensis culture supernatant and from the cellular fraction of a recombinant Escherichia coli clone containing the PtdIns-PLC gene from B. thuringiensis. The two-step purification procedure involved ion-exchange chromatography on DEAE-Sepharose followed by separation on a Mono-Q/FPLC-column with yields of 32% and 50%, respectively. The molecular mass was determined to be 34 kDa by SDS/PAGE. The isoelectric point of the enzyme was 5.15. The amino-terminal sequences were shown to be identical for the enzymes purified from both organisms. PtdIns-PLC was inhibited by divalent cations using mixed micelles of Triton X-100 and pure phosphatidylinositol. PtdIns-PLC activity was detectable on polyacrylamide gels by activity staining on phosphatidylinostiol-containing agarose.

Molecular characterization and sequence of phosphatidylinositol-specific phospholipase C of Bacillus thuringiensis

The gene encoding monophosphatidylinositol inositol phosphohydrolase (PI-specific phospholipase C, PI-PLC) of Bacillus thuringiensis was cloned in Staphylococcus carnosus TM300. The complete coding region comprises 987 base pairs corresponding to a precursor protein of 329 amino acids (molecular weight, 38,095). The NH2-terminal sequence of the purified enzyme from Escherichia coli indicated that the mature PI-PLC consists of 299 amino acid residues with a molecular weight of 34,586. Polyacrylamide gel electrophoresis revealed the same molecular weight for the purified enzyme isolated from the DNA-donor strain of B. thuringiensis and from the E. coli clone. By computer analysis, the secondary structure was predicted. The enzyme from the E. coli recombinant shows no activity on other phospholipids and sphingomyelin. The cleaving specificity of PI-PLC was examined by thin layer chromatography.

Hisactophilin, a histidine-rich actin-binding protein from Dictyostelium discoideum

The purification, cloning, and complete cDNA-derived sequence of a 17-kDa protein of Dictyostelium discoideum are described. This protein binds to F-actin in a pH-dependent and saturable manner. It induces actin polymerization in the absence of Mg2+ or K+, and is enriched in the submembranous region of the amoeboid cells as indicated by immunofluorescence labeling of cryosections. The mRNA as well as the protein are present throughout growth and all stages of development. The protein is detected in both soluble and particulate fractions of the cells. From a plasma membrane-enriched fraction, minor amounts of the protein are stepwise solubilized with 1.5 M KCl, 0.1 M NaOH, and Triton X-100, but most of the protein is only solubilized with 1% sodium dodecyl sulfate. As judged by the apparent molecular mass in sodium dodecyl sulfate-polyacrylamide gels, immunological cross-reactivity, and two-dimensional electrophoresis, the 17-kDa proteins from the soluble and particulate fraction resemble each other. The cDNA sequence does not reveal any signal peptide, trans-membrane region, or N-glycosylation site. Southern blots hybridized with a cDNA probe that spans the entire coding region show that the 17-kDa protein is encoded by a single gene. The most characteristic feature of the protein is its high content of 31 histidine residues out of 118 amino acids. We designate this protein as hisactophilin and suggest that this histidine-rich protein responds in its actin-binding activity to changes in cellular pH upon chemotactic signal reception.

Relative influence of subject variables and neurological parameters on neuropsychological performance of adult seizure patients

We present the results of a study examining relationships between subject characteristics (age, education, sex, race) and neurological factors on neuropsychological test performance of adult seizure patients. Test scores from a modified and expanded Halstead-Reitan test battery for 250 epileptics served as criterion variables for sets of multiple regression analyses using subject characteristics and neurological parameters as predictors. Initially, subjects were divided into two subsamples and separate analyses for subject and neurological variables were pursued. Double cross-validated results indicated that test performance was significantly related to both sets of predictor variables, yet the magnitudes of relationship were rather consistently highest for demographic attributes. The relative contribution of individual predictor variables subsequently was explored in a second set of multiple regression analyses examining both subject and neurological variables within the combined patient sample. Results indicated that one or more subject characteristic plus one or more neurological variable accounted for a significant amount of test variance for almost all of the measures under consideration. A subject variable was entered first in step-wise regression analyses for 78 % of the measures, with education proving to be the most potent predictor of test status. In general, these data support the need for test norms which make adjustments for nonneurological subject attributes.