Characterization of a Metal-independent CAZy Family 6 Glycosyltransferase from Bacteroides ovatus

The myriad functions of complex carbohydrates include modulating interactions between bacteria and their eukaryotic hosts. In humans and other vertebrates, variations in the activity of glycosyltransferases of CAZy family 6 generate antigenic variation between individuals and species that facilitates resistance to pathogens. The well characterized vertebrate glycosyltransferases of this family are multidomain membrane proteins with C-terminal catalytic domains. Genes for proteins homologous with their catalytic domains are found in at least nine species of anaerobic commensal bacteria and a cyanophage. Although the bacterial proteins are strikingly similar in sequence to the catalytic domains of their eukaryotic relatives, a metal-binding Asp-X-Asp sequence, present in a wide array of metal ion-dependent glycosyltransferases, is replaced by Asn-X-Asn. We have cloned and expressed one of these proteins from Bacteroides ovatus, a bacterium that is linked to inflammatory bowel disease. Functional characterization shows it to be a metal-independent glycosyltransferase with a 200-fold preference for UDP-GalNAc as substrate relative to UDP-Gal. It efficiently catalyzes the synthesis of oligosaccharides similar to human blood group A and may participate in the synthesis of the bacterial O-antigen. The kinetics for GalNAc transfer to 2′-fucosyl lactose are characteristic of a sequential mechanism, as observed previously for this family. Mutational studies indicate that despite the lack of a metal cofactor, there are pronounced similarities in structure-function relationships between the bacterial and vertebrate family 6 glycosyltransferases. These two groups appear to provide an example of horizontal gene transfer involving vertebrates and prokaryotes.The structures of complex glycans are determined by the specificities of the glycosyltransferases (GTs)² that catalyze their biosynthesis. GTs fall into two groups that differ in mechanism, based on whether the anomeric configuration of the donor substrate (α for most UDP-sugars) is retained or inverted in the product (1–3). They are classified into 90 different families in the CAZy data base based on sequence similarities (4, 5), but the majority of those that have been structurally characterized fall into one of two fold types, designated GT-A and GT-B (2). The retaining GTs of CAZy family 6 (GT6) have a GT-A fold and catalyze the transfer of either galactose or GalNAc into an α-linkage with the 3-OH group of β-linked galactose or GalNAc. GT6 includes the histo-blood group A and B GTs (GTA and GTB), the α-galactosyltransferase (α3GT) that catalyzes the synthesis of the xenoantigen or α-gal epitope, Forssman glycolipid synthase, isogloboside 3 synthase, and their homologues from other vertebrates (6). GT6 enzymes from vertebrates are type-2 membrane proteins with N-terminal cytosolic domains, a transmembrane helix, a spacer, and a C-terminal catalytic domain (6). Crystallographic studies of recombinant catalytic domains of GTA, GTB, and α3GT have provided detailed information about their interactions with substrates, metal cofactor, and inhibitors (7–9). Most GT-A fold GTs, including those in the GT6 family, require divalent metal ions, such as Mn²⁺, for catalytic activity; their metal dependence is linked to a shared DXD sequence motif. Residues of this motif interact with the metal ion and both the ribose and phosphates of the donor substrate to produce an appropriate substrate orientation and conformation for catalysis and to stabilize the UDP leaving group (3, 7–10).Mammalian members of GT6 are responsible for variations in glycan structures between different species and individuals as the result of selective enzyme inactivation in certain species (α3GT, Forssman glycolipid synthase, and isogloboside 3 synthase) or the inheritance of multiple alleles at one locus that encode enzymes with different substrate specificity (GTA and GTB) or are inactive (11–14). The presence of circulating antibodies against glycan structures that are subject to interspecies and individual variability has been linked to resistance to pathogens that also carry the glycans; these antibodies are thought to arise from exposure to potential pathogens, including enveloped viruses and bacteria that carry structurally similar glycans (11).In addition to the well characterized enzymes discussed previously, atypical members of the GT6 family have been identified in mammals that have sequence changes in highly conserved regions of the active site, including the DXD motif (6). However, no glycosyltransferase activity was detected in recombinant forms of two of these, and their functions are unclear (6). Although GT6 members are widely distributed among vertebrates, no homologues have been found in other eukaryotes (6). However, GT6 members have been identified in several bacterial species (15–17). GT6 enzymes from Escherichia coli O86, and Helicobacter mustelae that appear to function in the biosynthesis of the lipopolysaccharide O-antigen have been cloned and expressed by Wang and co-workers (16, 17) and found to have specificities similar to those of human GTB and GTA, respectively. These enzymes have been applied in the enzymatic synthesis of oligosaccharides. Other homologues are encoded by Hemophilus somnus, Psychroacter sp., PRwf-1 (15), Francisella philomiragia, and three Bacteroides species, Bacteroides ovatus, Bacteroides caccae, and Bacteroides stercoris, as well as a cyanophage, PSSM-2 (15). Genes for other homologues from unidentified species are present in the marine metagenome (18, 19) and human gut metagenome (20, 21). The phage and bacterial enzymes are substantially truncated at the N terminus relative to the catalytic domains of vertebrate GT6 representatives and are smaller than the reported minimal functional unit of a primate α3GT (22). When bacterial and vertebrate GT6 amino acid sequences are aligned (Fig. 1 and supplemental Figs. S1 and S2), it can be seen that the metal-binding DXD of the eukaryotic GTs is replaced by NXN (where X is Ala, Gly, or Ser) in the bacterial homologues. The cyanophage GT6 member and related proteins in the marine metagenome, however, retain the DXD motif. This conspicuous difference in the bacterial proteins is particularly interesting, since, in the mammalian enzymes, the aspartates of the DXD and adjacent residues are crucial for catalytic activity (10, 23).Open in a separate windowFIGURE 1.An alignment of selected bacterial, cyanophage and mammalian GT6 amino acid sequences. Abbreviations and Interpro sequence IDs (in parentheses) are as follows. HuA, human histo-blood group A synthase (A1EAJ6); Bova, bovine α1,3-galactosyltransferase ({"type":"entrez-protein","attrs":{"text":"P14769","term_id":"120970","term_text":"P14769"}}P14769); PSSM2, cyanophage PSSM-2 ({"type":"entrez-protein","attrs":{"text":"Q58M87","term_id":"75096044","term_text":"Q58M87"}}Q58M87); Bs, B. stercoris (B0NSM3); Bo1, B. ovatus GT1 (A7LVT2); Bo2, B. ovatus GT2 (A7M0P3); Bc, B. caccae (A5ZC71). The boxed regions in the alignment identify regions that have been shown to be involved in interactions with substrates and cofactor and in catalysis in bovine α1,3-galactosyltransferase and histo-blood group A and B enzymes. These are labeled (below) as follows. A, interactions with uracil; B, interactions with the galactose moiety of UDP-Gal; C, interactions with Mn²⁺, phosphates, and galactose; D, interactions with acceptor substrate; E, interactions with Gal or GalNAc of donor substrate; F, interactions with monosaccharide of donor substrate and acceptor and catalysis; The arrow (above) denotes the intron/exon boundary in vertebrate GT6s, and the asterisks indicate the residues in BoGT6a that were subjected to mutagenesis.B. ovatus is a Gram-negative commensal bacterium that inhabits the distal mammalian gut and has been implicated in the pathology of inflammatory bowel disease in humans (24). The B. ovatus genome contains two genes that encode GT6 representatives (Fig. 1). We selected one of these for initial investigation, and designate it BoGT6a (family 6 glycosyltransferase 1 of Bacteroides). The gene for this protein was amplified by PCR and cloned and expressed in His-tagged form in E. coli BL21(DE3). Assays with a variety of substrates show that its substrate specificity is similar to that of human GTA. Previous studies of the activities of bacterial enzymes were conducted in the presence of Mn²⁺ (16, 17), but we find that the B. ovatus enzyme does not require divalent metal ions for activity and is fully active in EDTA. Despite this striking difference, BoGT6a is similar to its metal-dependent relatives in catalytic properties; also, the effects of amino acid substitutions for residues corresponding to several that act in substrate binding and catalysis in vertebrate GT6 glycosyltransferases suggest that they have similar structure-function relationships. These results indicate that the metal cofactor is not a conserved feature in the GT6 family. They also raise questions about the catalytic mechanism of prokaryotic GT6 members and the evolutionary relationship between bacterial, phage, and vertebrate enzymes.     

A New Class of Endoplasmic Reticulum Export Signal ΦXΦXΦ for Transmembrane Proteins and Its Selective Interaction with Sec24C

Protein export from the endoplasmic reticulum (ER) depends on the interaction between a signal motif on the cargo and a cargo recognition site on the coatomer protein complex II. A hydrophobic sequence in the N terminus of the bovine anion exchanger 1 (AE1) anion exchanger facilitated the ER export of human AE1Δ11, an ER-retained AE1 mutant, through interaction with a specific Sec24 isoform. The cell surface expression and N-glycan processing of various substitution mutants or chimeras of human and bovine AE1 proteins and their Δ11 mutants in HEK293 cells were examined. The N-terminal sequence (V/L/F)X(I/L)X(M/L), ²⁶VSIPM³⁰ in bovine AE1, which is comparable with ΦXΦXΦ, acted as the ER export signal for AE1 and AE1Δ11 (Φ is a hydrophobic amino acid, and X is any amino acid). The AE1-Ly49E chimeric protein possessing the ΦXΦXΦ motif exhibited effective cell surface expression and N-glycan maturation via the coatomer protein complex II pathway, whereas a chimera lacking this motif was retained in the ER. A synthetic polypeptide containing the N terminus of bovine AE1 bound the Sec23A-Sec24C complex through a selective interaction with Sec24C. Co-transfection of Sec24C-AAA, in which the residues ⁸⁹⁵LIL⁸⁹⁷ (the binding site for another ER export signal motif IXM on Sec24C and Sec24D) were mutated to ⁸⁹⁵AAA⁸⁹⁷, specifically increased ER retention of the AE1-Ly49E chimera. These findings demonstrate that the ΦXΦXΦ sequence functions as a novel signal motif for the ER export of cargo proteins through an exclusive interaction with Sec24C.     

Structural and functional insights into the molecular mechanism of rRNA m6A methyltransferase RlmJ

RlmJ catalyzes the m⁶A2030 methylation of 23S rRNA during ribosome biogenesis in Escherichia coli. Here, we present crystal structures of RlmJ in apo form, in complex with the cofactor S-adenosyl-methionine and in complex with S-adenosyl-homocysteine plus the substrate analogue adenosine monophosphate (AMP). RlmJ displays a variant of the Rossmann-like methyltransferase (MTase) fold with an inserted helical subdomain. Binding of cofactor and substrate induces a large shift of the N-terminal motif X tail to make it cover the cofactor binding site and trigger active-site changes in motifs IV and VIII. Adenosine monophosphate binds in a partly accommodated state with the target N6 atom 7 Å away from the sulphur of AdoHcy. The active site of RlmJ with motif IV sequence ₁₆₄DPPY₁₆₇ is more similar to DNA m⁶A MTases than to RNA m⁶₂A MTases, and structural comparison suggests that RlmJ binds its substrate base similarly to DNA MTases T4Dam and M.TaqI. RlmJ methylates in vitro transcribed 23S rRNA, as well as a minimal substrate corresponding to helix 72, demonstrating independence of previous modifications and tertiary interactions in the RNA substrate. RlmJ displays specificity for adenosine, and mutagenesis experiments demonstrate the critical roles of residues Y4, H6, K18 and D164 in methyl transfer.     

Specificity Profiling of Dual Specificity Phosphatase Vaccinia VH1-related (VHR) Reveals Two Distinct Substrate Binding Modes

Vaccinia VH1-related (VHR) is a dual specificity phosphatase that consists of only a single catalytic domain. Although several protein substrates have been identified for VHR, the elements that control the in vivo substrate specificity of this enzyme remain unclear. In this work, the in vitro substrate specificity of VHR was systematically profiled by screening combinatorial peptide libraries. VHR exhibits more stringent substrate specificity than classical protein-tyrosine phosphatases and recognizes two distinct classes of Tyr(P) peptides. The class I substrates are similar to the Tyr(P) motifs derived from the VHR protein substrates, having sequences of (D/E/φ)(D/S/N/T/E)(P/I/M/S/A/V)pY(G/A/S/Q) or (D/E/φ)(T/S)(D/E)pY(G/A/S/Q) (where φ is a hydrophobic amino acid and pY is phosphotyrosine). The class II substrates have the consensus sequence of (V/A)P(I/L/M/V/F)X_1–6pY (where X is any amino acid) with V/A preferably at the N terminus of the peptide. Site-directed mutagenesis and molecular modeling studies suggest that the class II peptides bind to VHR in an opposite orientation relative to the canonical binding mode of the class I substrates. In this alternative binding mode, the Tyr(P) side chain binds to the active site pocket, but the N terminus of the peptide interacts with the carboxylate side chain of Asp¹⁶⁴, which normally interacts with the Tyr(P) + 3 residue of a class I substrate. Proteins containing the class II motifs are efficient VHR substrates in vitro, suggesting that VHR may act on a novel class of yet unidentified Tyr(P) proteins in vivo.     

Structural Insight into Substrate Differentiation of the Sugar-metabolizing Enzyme Galactitol Dehydrogenase from Rhodobacter sphaeroides D

Galactitol 2-dehydrogenase (GatDH) belongs to the protein superfamily of short-chain dehydrogenases. As an enzyme capable of the stereo- and regioselective modification of carbohydrates, it exhibits a high potential for application in biotechnology as a biocatalyst. We have determined the crystal structure of the binary form of GatDH in complex with its cofactor NAD(H) and of the ternary form in complex with NAD(H) and three different substrates. The active form of GatDH constitutes a homo-tetramer with two magnesium-ion binding sites each formed by two opposing C termini. The catalytic tetrad is formed by Asn¹¹⁶, Ser¹⁴⁴, Tyr¹⁵⁹, and Lys¹⁶³. GatDH structurally aligns well with related members of the short-chain dehydrogenase family. The substrate binding pocket can be divided into two parts of different size and polarity. In the smaller part, the side chains of amino acids Ser¹⁴⁴, Ser¹⁴⁶, and Asn¹⁵¹ are important determinants for the binding specificity and the orientation of (pro-) chiral compounds. The larger part of the pocket is elongated and flanked by polar and non-polar residues, enabling a rather broad substrate spectrum. The presented structures provide valuable information for a rational design of this enzyme to improve its stability against pH, temperature, or solvent concentration and to optimize product yield in bioreactors.     

Characterization of ligand binding to the bifunctional key enzyme in the sialic acid biosynthesis by NMR: I. Investigation of the UDP-GlcNAc 2-epimerase functionality

The bifunctional enzyme UDP-N-acetylglucosamine 2-epimerase/N-acetylmannosamine kinase is the key enzyme for the biosynthesis of sialic acids. As terminal components of glycoconjugates, sialic acids are associated with a variety of pathological processes such as inflammation and cancer. For the first time, this study reveals characteristics of the interaction of the epimerase site of the enzyme with its natural substrate, UDP-N-acetylglucosamine (UDP-GlcNAc) and derivatives thereof at atomic resolution. Saturation transfer difference NMR experiments were crucial in obtaining ligand binding epitopes and to rank ligands according to their binding affinities. Employing a fragment based approach, it was possible to assign the major component of substrate recognition to the UDP moiety. In particular, the binding epitopes of the uridine moieties of UMP, UDP, UDP-GalNAc, and UDP-GlcNAc are rather similar, suggesting that the binding mode of the UDP moiety is the same in all cases. In contrast, the hexopyranose units of UDP-GlcNAc and UDP-GalNAc display small differences reflecting the inability of the enzyme to process UDP-GalNAc. Surprisingly, saturation transfer difference NMR titrations show that UDP has the largest binding affinity to the epimerase site and that at least one phosphate group is required for binding. Consequently, this study provides important new data for rational drug design.     

Mutagenesis analyses explore residues responsible for the neurotoxic and anticoagulant activities of Trimucrotoxin, a pit-viper venom Asn6-phospholipase A2

Trimucrotoxin (TmCT) is an Asn⁶-containing phospholipase A₂ (PLA₂) from Protobothrops mucrosquamatus (pit-viper) venom. In an attempt to characterize the amino acid residues responsible for the neurotoxic and anticoagulant activities of TmCT, the recombinant fusion proteins of TmCT wild type and mutants were expressed in Escherichia coli. Correct refolding and processing of 37 TmCT mutants were confirmed by their HPLC retention times, circular dichroism spectra, and masses obtained from ESI-MS spectrometry. Each mutant was assayed by pH-stat titration using zwitterionic as well as anionic micelle substrates, and the neurotoxicity was evaluated by using the contractile responses of chick biventer cervicis muscles. The results demonstrated that the residues Asn¹, Asn⁶, Lys⁷, Ile¹¹, Met¹², Gly⁵³, Thr⁷⁹, His¹⁰⁸ and Met¹¹⁸ are important to TmCT neurotoxicity. Through various tests, we also confirmed that enzymatic activity, as opposed to binding to Factor Xa, was a necessary part of TmCT’s anticoagulant effect. In addition, pulldown assays of the WT and selected mutants revealed that TmCT’s in vitro binding to crotoxin acidic subunit may involve a broad surface area. We conclude that the hot spot mutations at specific positions 53, 79, 108, and 118 during the pit-viper Asn⁶-PLA₂ evolution regulate their neurotoxicities, and that many of the neurotoxic site residues and the anticoagulant mechanism of TmCT are different from those of ammodytoxin A (a true-viper venom neurotoxic PLA₂).     

Structural basis of the broad substrate tolerance of the antibody 7B9-catalyzed hydrolysis of p-nitrobenzyl esters

Catalytic antibody 7B9, which was elicited against p-nitrobenzyl phosphonate transition-state analogue (TSA) 1, hydrolyzes a wide range of p-nitrobenzyl monoesters and thus shows broad substrate tolerance. To reveal the molecular basis of this substrate tolerance, the 7B9 Fab fragment complexed with p-nitrobenzyl ethylphosphonate 2 was crystallized and the three-dimensional structure was determined. The crystal structure showed that the strongly antigenic p-nitrobenzyl moiety occupied a relatively shallow antigen-combining site and therefore the alkyl moiety was located outside the pocket. These results support the observed broad substrate tolerance of 7B9 and help rationalize how 7B9 can catalyze various p-nitrobenzyl ester derivatives. The crystal structure also showed that three amino acid residues (Asn^H33, Ser^H95, and Arg^L96) were placed in key positions to form hydrogen bonds with the phosphonate oxygens of the transitions-state analogue. In addition, the role of these amino acid residues was examined by site-directed mutagenesis to alanine: all mutants (Asn^H33Ala, Ser^H95Ala, and Arg^L96Ala) showed no detectable catalytic activity. Coupling the findings from our structural studies with these mutagenesis results clarified the structural basis of the observed broad substrate tolerance of antibody 7B9-catalyzed hydrolyses. Our findings provide new strategies for the generation of catalytic antibodies that accept a broad range of substrates, aiding their practical application in synthetic organic chemistry.     

Insights into tRNA-Dependent Amidotransferase Evolution and Catalysis from the Structure of the Aquifex aeolicus Enzyme

Many bacteria form Gln-tRNA^Gln and Asn-tRNA^Asn by conversion of the misacylated Glu-tRNA^Gln and Asp-tRNA^Asn species catalyzed by the GatCAB amidotransferase in the presence of ATP and an amide donor (glutamine or asparagine). Here, we report the crystal structures of GatCAB from the hyperthermophilic bacterium Aquifex aeolicus, complexed with glutamine, asparagine, aspartate, ADP, or ATP. In contrast to the Staphylococcus aureus GatCAB, the A. aeolicus enzyme formed acyl-enzyme intermediates with either glutamine or asparagine, in line with the equally facile use by the amidotransferase of these amino acids as amide donors in the transamidation reaction.A water-filled ammonia channel is open throughout the length of the A. aeolicus GatCAB from the GatA active site to the synthetase catalytic pocket in the B-subunit. A non-catalytic Zn²⁺ site in the A. aeolicus GatB stabilizes subunit contacts and the ammonia channel. Judged from sequence conservation in the known GatCAB sequences, the Zn²⁺ binding motif was likely present in the primordial GatB/E, but became lost in certain lineages (e.g., S. aureus GatB). Two divalent metal binding sites, one permanent and the other transient, are present in the catalytic pocket of the A. aeolicus GatB. The two sites enable GatCAB to first phosphorylate the misacylated tRNA substrate and then amidate the activated intermediate to form the cognate products, Gln-tRNA^Gln or Asn-tRNA^Asn.     

Functional significance of some particular amino acid residues in Bombyx mori pyridoxal kinase

Pyridoxal kinase (PLK; EC 2.7.1.35) is a key enzyme for vitamin B₆ metabolism in animals. It catalyzes the ATP-dependent phosphorylation of pyridoxal, generating pyridoxal 5′-phosphate, an important cofactor for many enzymatic reactions. Bombyx mori PLK (BmPLK) is 10 or more residues shorter than mammalian PLKs, and some amino acid residues conserved in the PLKs from mammals are not maintained in the protein. Multiple sequence alignment suggested that amino acid residues Thr⁴⁷, Ile⁵⁴, Arg⁸⁸, Asn¹²¹ and Glu²³⁰ might play important roles in BmPLK. In this study, we used a site-directed specific mutagenesis approach to determine the functional significance of these particular amino acid residues in BmPLK. Our results demonstrated that the mutation of Asn¹²¹ to Glu did not affect the catalytic function of BmPLK. The corresponding site-directed mutants of Thr⁴⁷ to Asn, Ile⁵⁴ to Phe, and Arg⁸⁸ to Ile displayed a decreased catalytic efficiency and an elevated Km value for substrate relative to the wild-type value, and no enzyme activity could be detected in mutant of Trp²³⁰ to Glu. Circular dichroism analysis revealed that the mutation of Trp²³⁰ to Glu resulted in mis-folding of the protein. Our results provided direct evidence that residue Trp²³⁰ is crucial to maintain the structural and functional integrity of BmPLK. This study will add to the existing understanding of the characteristic of structure and function of BmPLK.     

Analysis of the DNA binding site of Escherichia coli RecA protein

To investigate the DNA binding site of RecA protein, we constructed 15 recA mutants having alterations in the regions homologous to the other ssDNA binding proteins. The in vivo analyses showed that the mutational change at Arg²⁴³, Lys²⁴⁸, Tyr²⁶⁴, or simultaneously at Lys⁶ and Lys¹⁹, or Lys⁶ and Lys²³ caused severe defects in the recA functions, while other mutational changes did not. Purified RecA-K6A-K23A (Lys⁶ and Lys²³ changed to Ala and Ala, respectively) protein was indistinguishable from the wild-type RecA protein in its binding to DNA. However, the RecA-R243A (Arg²⁴³ changed to Ala) and RecA-Y264A (Tyr²⁶⁴ changed to Ala) proteins were defective in binding to both ss- and ds-DNA. In self-oligomerization property, RecA-R243A was proficient but RecA-Y264A was deficient, suggesting that the RecA-R243A protein had a defect in DNA binding site and the RecA-Y264A protein was defective in its interaction with the adjacent RecA molecule. The region of residues 243–257 including the Arg²⁴³ is highly homologous to the DNA binding motif in the ssDNA binding proteins, while the eukaryotic RecA homologues have a similar structure at the amino-terminal side proximal to the nucleotide binding core. The region of residues 243–257 would be a part of the DNA binding site. The other parts of this site would be the Tyr¹⁰³ and the region of residues 178–183, which were cross-linked to ssDNA. These three regions lie in a line in the crystal structure.     

Functional Dissection and Hierarchy of Tubulin-folding Cofactor Homologues in Fission Yeast

We describe the isolation of fission yeast homologues of tubulin-folding cofactors B (Alp11) and E (Alp21), which are essential for cell viability and the maintenance of microtubules. Alp11^B contains the glycine-rich motif (the CLIP-170 domain) involved in microtubular functions, whereas, unlike mammalian cofactor E, Alp21^E does not. Both mammalian and yeast cofactor E, however, do contain leucine-rich repeats. Immunoprecipitation analysis shows that Alp11^B interacts with both α-tubulin and Alp21^E, but not with the cofactor D homologue Alp1, whereas Alp21^E also interacts with Alp1^D. The cellular amount of α-tubulin is decreased in both alp1 and alp11 mutants. Overproduction of Alp11^B results in cell lethality and the disappearance of microtubules, which is rescued by co-overproduction of α-tubulin. Both full-length Alp11^B and the C-terminal third containing the CLIP-170 domain localize in the cytoplasm, and this domain is required for efficient binding to α-tubulin. Deletion of alp11 is suppressed by multicopy plasmids containing either alp21⁺ or alp1⁺, whereas alp21 deletion is rescued by overexpression of alp1⁺ but not alp11⁺. Finally, the alp1 mutant is not complemented by either alp11⁺ or alp21⁺. The results suggest that cofactors operate in a linear pathway (Alp11^B-Alp21^E-Alp1^D), each with distinct roles.     

N Terminus Is Key to the Dominant Negative Suppression of CaV2 Calcium Channels: IMPLICATIONS FOR EPISODIC ATAXIA TYPE 2*

Expression of the calcium channels Ca_V2.1 and Ca_V2.2 is markedly suppressed by co-expression with truncated constructs containing Domain I. This is the basis for the phenomenon of dominant negative suppression observed for many of the episodic ataxia type 2 mutations in Ca_V2.1 that predict truncated channels. The process of dominant negative suppression has been shown previously to stem from interaction between the full-length and truncated channels and to result in downstream consequences of the unfolded protein response and endoplasmic reticulum-associated protein degradation. We have now identified the specific domain that triggers this effect. For both Ca_V2.1 and Ca_V2.2, the minimum construct producing suppression was the cytoplasmic N terminus. Suppression was enhanced by tethering the N terminus to the membrane with a CAAX motif. The 11-amino acid motif (including Arg⁵² and Arg⁵⁴) within the N terminus, which we have previously shown to be required for G protein modulation, is also essential for dominant negative suppression. Suppression is prevented by addition of an N-terminal tag (XFP) to the full-length and truncated constructs. We further show that suppression of Ca_V2.2 currents by the N terminus-CAAX construct is accompanied by a reduction in Ca_V2.2 protein level, and this is also prevented by mutation of Arg⁵² and Arg⁵⁴ to Ala in the truncated construct. Taken together, our evidence indicates that both the extreme N terminus and the Arg⁵², Arg⁵⁴ motif are involved in the processes underlying dominant negative suppression.     

The Archaeal Proteasome Is Regulated by a Network of AAA ATPases

The proteasome is the central machinery for targeted protein degradation in archaea, Actinobacteria, and eukaryotes. In its basic form, it consists of a regulatory ATPase complex and a proteolytic core particle. The interaction between the two is governed by an HbYX motif (where Hb is a hydrophobic residue, Y is tyrosine, and X is any amino acid) at the C terminus of the ATPase subunits, which stimulates gate opening of the proteasomal α-subunits. In archaea, the proteasome-interacting motif is not only found in canonical proteasome-activating nucleotidases of the PAN/ARC/Rpt group, which are absent in major archaeal lineages, but also in proteins of the CDC48/p97/VAT and AMA groups, suggesting a regulatory network of proteasomal ATPases. Indeed, Thermoplasma acidophilum, which lacks PAN, encodes one CDC48 protein that interacts with the 20S proteasome and activates the degradation of model substrates. In contrast, Methanosarcina mazei contains seven AAA proteins, five of which, both PAN proteins, two out of three CDC48 proteins, and the AMA protein, function as proteasomal gatekeepers. The prevalent presence of multiple, distinct proteasomal ATPases in archaea thus results in a network of regulatory ATPases that may widen the substrate spectrum of proteasomal protein degradation.     

5-Hydroxytryptamine Inhibits P2X2 Receptor Channel Pore Mutants

1.5-Hydroxytryptamine (10 M) enhanced ionic current mediated through the wild-type P2X₂ receptor/channel expressed in Xenopus oocytes.2.5-Hydroxytryptamine (10 M) inhibited a current mediated through P2X₂ receptor/channel mutants when Thr³³⁰ or Asn³³³ was replaced with Ile (T330I and N333I).3.Our results suggest that neutralization of Thr³³⁰ or Asn³³³ exposes a high-affinity, inhibitory binding site for 5-hydroxytryptamine. This implies that 5-hydroxytryptamine interacts with the P2X₂ receptor/channel at their channel pores.     

Production of Active Chimeric Pediocin AcH in Escherichia coli in the Absence of Processing and Secretion Genes from the Pediococcus pap Operon

Minimum requirements have been determined for synthesis and secretion of the Pediococcus antimicrobial peptide, pediocin AcH, in Escherichia coli. The functional mature domain of pediocin AcH (Lys⁺¹ to Cys⁺⁴⁴) is targeted into the E. coli sec machinery and secreted to the periplasm in active form when fused in frame to the COOH terminus of the secretory protein maltose-binding protein (MBP). The PapC-PapD specialized secretion machinery is not required for secretion of the MBP-pediocin AcH chimeric protein, indicating that in Pediococcus, PapC and PapD probably are required for recognition and processing of the leader peptide rather than for translocation of the mature pediocin AcH domain across the cytoplasmic membrane. The chimeric protein displays bactericidal activity, suggesting that the NH₂ terminus of pediocin AcH does not span the phospholipid bilayer in the membrane-interactive form of the molecule. However, the conserved Lys⁺¹-Tyr-Tyr-Gly-Asn-Gly-Val⁺⁷-sequence at the NH₂ terminus is important because deletion of this sequence abolishes activity. The secreted chimeric protein is released into the culture medium when expressed in a periplasmic leaky E. coli host. The MBP fusion-periplasmic leaky expression system should be generally advantageous for production and screening of the activity of bioactive peptides.     

Cleavage of the Carboxyl-Terminus of LEACS2, a Tomato 1-Aminocyclopropane-1-Carboxylic Acid Synthase Isomer, by a 64-kDa Tomato Metalloprotease Produces a Truncated but Active Enzyme

1-Aminocyclopropane-1-carboxylic acid （ACC） synthase （ACS） is the principal enzyme in phytohormone ethylene biosynthesis. Previous studies have shown that the hypervariable C-terminus of ACS is proteolytically processed in vivo. However, the protease responsible for this has not yet been identified. In the present study, we investigated the processing of the 55-kDa full-length tomato ACS （LeACS2） into 52-, 50- and 49-kDa truncated isoforms in ripening tomato （Lycopersicon esculentum Mill. cv. Cooperation 903） fruit using the sodium dodecyl sulfate-boiling method. Meanwhile, an LeACS2-processing protease was purified via multi-step column chromatography from tomato fruit. Subsequent biochemical analysis of the 64-kDa purified protease revealed that it is a metalloprotease active at multiple cleavage sites within the hypervariable C-terminus of LeACS2. N-terminal sequencing and matrix-assisted laser desorption/ionization time-of-flight analysis indicated that the LeACS2-processing metalloprotease cleaves at the C-terminal sites Lys^438, Glu^447, Lys^448, Asn^456, Ser^460, Ser^462, Lys^463, and Leu^474, but does not cleave the N- terminus of LeACS2. Four C-terminus-deleted （26-50 amino acids） LeACS2 fusion proteins were overproduced and subjected to proteolysis by this metalloprotease to identify the multiple cleavage sites located on the N-terminal side of the phosphorylation site Ser^460. The results indisputably confirmed the presence of cleavage sites within the region between the α-helix domain （H14） and Ser^460 for this metalloprotease. Furthermore, the resulting C-terminally truncated LeACS2 isoforms were active enzymatically. Because this protease could produce LeACS2 isoforms in vitro similar to those detected in vivo, it is proposed that this metalloprotease may be involved in the proteolysis of LeACS2 in vivo.