Activation of the l,d‐transpeptidation peptidoglycan cross‐linking pathway by a metallo‐d,d‐carboxypeptidase in Enterococcus faecium

Bypass of the penicillin‐binding proteins by an l ,d ‐transpeptidase (Ldt_fm) confers cross‐resistance to β‐lactam and glycopeptide antibiotics in mutants of Enterococcus faecium selected in vitro. Ldt_fm is produced by the parental strain D344S although it insignificantly contributes to peptidoglycan cross‐linking as pentapeptide stems cannot be used as acyl donors by this enzyme. Here we show that production of the tetrapeptide substrate of Ldt_fm is controlled by a two‐component regulatory system (DdcRS) and a metallo‐d ,d ‐carboxypeptidase (DdcY). The locus was silent in D344S and its activation was due to amino acid substitutions in DdcS or DdcR that led to production of DdcY and hydrolysis of the C‐terminal d ‐Ala residue of the cytoplasmic peptidoglycan precursor UDP‐MurNAc‐pentapeptide. The T¹⁶¹A and T¹⁶¹M substitutions affected a position of DdcS known to be essential for the phosphatase activity of related sensor kinases. Complete elimination of UDP‐MurNAc‐pentapeptide, which was required specifically for resistance to glycopeptides, involved substitutions in DdcY that increased the catalytic efficiency of the enzyme (E¹²⁷K) and affected its interaction with the cell envelope (I¹⁴N). The ddc locus displays striking similarities with portions of the van vancomycin resistance gene clusters, suggesting possible routes of emergence of cross‐resistance to glycopeptides and β‐lactams in natural conditions.     

Kinetic Features of L,D-Transpeptidase Inactivation Critical for β-Lactam Antibacterial Activity

Active-site serine D,D-transpeptidases belonging to the penicillin-binding protein family (PBPs) have been considered for a long time as essential for peptidoglycan cross-linking in all bacteria. However, bypass of the PBPs by an L,D-transpeptidase (Ldt_fm) conveys high-level resistance to β-lactams of the penam class in Enterococcus faecium with a minimal inhibitory concentration (MIC) of ampicillin >2,000 µg/ml. Unexpectedly, Ldt_fm does not confer resistance to β-lactams of the carbapenem class (imipenem MIC = 0.5 µg/ml) whereas cephems display residual activity (ceftriaxone MIC = 128 µg/ml). Mass spectrometry, fluorescence kinetics, and NMR chemical shift perturbation experiments were performed to explore the basis for this specificity and identify β-lactam features that are critical for efficient L,D-transpeptidase inactivation. We show that imipenem, ceftriaxone, and ampicillin acylate Ldt_fm by formation of a thioester bond between the active-site cysteine and the β-lactam-ring carbonyl. However, slow acylation and slow acylenzyme hydrolysis resulted in partial Ldt_fm inactivation by ampicillin and ceftriaxone. For ampicillin, Ldt_fm acylation was followed by rupture of the C⁵–C⁶ bond of the β-lactam ring and formation of a secondary acylenzyme prone to hydrolysis. The saturable step of the catalytic cycle was the reversible formation of a tetrahedral intermediate (oxyanion) without significant accumulation of a non-covalent complex. In agreement, a derivative of Ldt_fm blocked in acylation bound ertapenem (a carbapenem), ceftriaxone, and ampicillin with similar low affinities. Thus, oxyanion and acylenzyme stabilization are both critical for rapid L,D-transpeptidase inactivation and antibacterial activity. These results pave the way for optimization of the β-lactam scaffold for L,D-transpeptidase-inactivation.     

Meropenem inhibits D,D‐carboxypeptidase activity in Mycobacterium tuberculosis

Carbapenems such as meropenem are being investigated for their potential therapeutic utility against highly drug‐resistant tuberculosis. These β‐lactams target the transpeptidases that introduce interpeptide cross‐links into bacterial peptidoglycan thereby controlling rigidity of the bacterial envelope. Treatment of Mycobacterium tuberculosis (Mtb) with the β‐lactamase inhibitor clavulanate together with meropenem resulted in rapid, polar, cell lysis releasing cytoplasmic contents. In Mtb it has been previously demonstrated that 3‐3 cross‐linkages [involving two diaminopimelate (DAP) molecules] predominate over 4‐3 cross‐linkages (involving one DAP and one D‐alanine) in stationary‐phase cells. We purified and analysed peptidoglycan from Mtb and found that 3‐3 cross‐linkages predominate throughout all growth phases and the ratio of 4‐3/3‐3 linkages does not vary significantly under any growth condition. Meropenem treatment was accompanied by a dramatic accumulation of unlinked pentapeptide stems with no change in the tetrapeptide pools, suggesting that meropenem inhibits both a D,D‐carboxypeptidase and an L,D‐transpeptidase. We purified a candidate D,D‐carboxypeptidase DacB2 and showed that meropenem indeed directly inhibits this enzyme by forming a stable adduct at the enzyme active site. These results suggest that the rapid lysis of meropenem‐treated cells is the result of synergistically inhibiting the transpeptidases that introduce 3,3‐cross‐links while simultaneously limiting the pool of available substrates available for cross‐linking.     

Elucidating the role of Trp105 in the KPC-2 ��-lactamase

The molecular basis of resistance to β‐lactams and β‐lactam‐β‐lactamase inhibitor combinations in the KPC family of class A enzymes is of extreme importance to the future design of effective β‐lactam therapy. Recent crystal structures of KPC‐2 and other class A β‐lactamases suggest that Ambler position Trp105 may be of importance in binding β‐lactam compounds. Based on this notion, we explored the role of residue Trp105 in KPC‐2 by conducting site‐saturation mutagenesis at this position. Escherichia coli DH10B cells expressing the Trp105Phe, ‐Tyr, ‐Asn, and ‐His KPC‐2 variants possessed minimal inhibitory concentrations (MICs) similar to E. coli cells expressing wild type (WT) KPC‐2. Interestingly, most of the variants showed increased MICs to ampicillin‐clavulanic acid but not to ampicillin‐sulbactam or piperacillin‐tazobactam. To explain the biochemical basis of this behavior, four variants (Trp105Phe, ‐Asn, ‐Leu, and ‐Val) were studied in detail. Consistent with the MIC data, the Trp105Phe β‐lactamase displayed improved catalytic efficiencies, k_cat/K_m, toward piperacillin, cephalothin, and nitrocefin, but slightly decreased k_cat/K_m toward cefotaxime and imipenem when compared to WT β‐lactamase. The Trp105Asn variant exhibited increased K_ms for all substrates. In contrast, the Trp105Leu and ‐Val substituted enzymes demonstrated notably decreased catalytic efficiencies (k_cat/K_m) for all substrates. With respect to clavulanic acid, the K_is and partition ratios were increased for the Trp105Phe, ‐Asn, and ‐Val variants. We conclude that interactions between Trp105 of KPC‐2 and the β‐lactam are essential for hydrolysis of substrates. Taken together, kinetic and molecular modeling studies define the role of Trp105 in β‐lactam and β‐lactamase inhibitor discrimination.     

Nonclassical Transpeptidases of Mycobacterium tuberculosis Alter Cell Size,Morphology, the Cytosolic Matrix,Protein Localization,Virulence, and Resistance to β-Lactams

Virtually all bacteria possess a peptidoglycan layer that is essential for their growth and survival. The β-lactams, the most widely used class of antibiotics in human history, inhibit d,d-transpeptidases, which catalyze the final step in peptidoglycan biosynthesis. The existence of a second class of transpeptidases, the l,d-transpeptidases, was recently reported. Mycobacterium tuberculosis, an infectious pathogen that causes tuberculosis (TB), is known to possess as many as five proteins with l,d-transpeptidase activity. Here, for the first time, we demonstrate that loss of l,d-transpeptidases 1 and 2 of M. tuberculosis (Ldt_Mt1 and Ldt_Mt2) alters cell surface morphology, shape, size, organization of the intracellular matrix, sorting of some low-molecular-weight proteins that are targeted to the membrane or secreted, cellular physiology, growth, virulence, and resistance of M. tuberculosis to amoxicillin-clavulanate and vancomycin.     

Insight into a strategy for attenuating AmpC‐mediated β‐lactam resistance: Structural basis for selective inhibition of the glycoside hydrolase NagZ

NagZ is an exo‐N‐acetyl‐β‐glucosaminidase, found within Gram‐negative bacteria, that acts in the peptidoglycan recycling pathway to cleave N‐acetylglucosamine residues off peptidoglycan fragments. This activity is required for resistance to cephalosporins mediated by inducible AmpC β‐lactamase. NagZ uses a catalytic mechanism involving a covalent glycosyl enzyme intermediate, unlike that of the human exo‐N‐acetyl‐β‐glucosaminidases: O‐GlcNAcase and the β‐hexosaminidase isoenzymes. These latter enzymes, which remove GlcNAc from glycoconjugates, use a neighboring‐group catalytic mechanism that proceeds through an oxazoline intermediate. Exploiting these mechanistic differences we previously developed 2‐N‐acyl derivatives of O‐(2‐acetamido‐2‐deoxy‐D ‐glucopyranosylidene)amino‐N‐phenylcarbamate (PUGNAc), which selectively inhibits NagZ over the functionally related human enzymes and attenuate antibiotic resistance in Gram‐negatives that harbor inducible AmpC. To understand the structural basis for the selectivity of these inhibitors for NagZ, we have determined its crystallographic structure in complex with N‐valeryl‐PUGNAc, the most selective known inhibitor of NagZ over both the human β‐hexosaminidases and O‐GlcNAcase. The selectivity stems from the five‐carbon acyl chain of N‐valeryl‐PUGNAc, which we found ordered within the enzyme active site. In contrast, a structure determination of a human O‐GlcNAcase homologue bound to a related inhibitor N‐butyryl‐PUGNAc, which bears a four‐carbon chain and is selective for both NagZ and O‐GlcNAcase over the human β‐hexosamnidases, reveals that this inhibitor induces several conformational changes in the active site of this O‐GlcNAcase homologue. A comparison of these complexes, and with the human β‐hexosaminidases, reveals how selectivity for NagZ can be engineered by altering the 2‐N‐acyl substituent of PUGNAc to develop inhibitors that repress AmpC mediated β‐lactam resistance.     

Conformational flexibility of the glycosidase NagZ allows it to bind structurally diverse inhibitors to suppress β‐lactam antibiotic resistance

NagZ is an N‐acetyl‐β‐d ‐glucosaminidase that participates in the peptidoglycan (PG) recycling pathway of Gram‐negative bacteria by removing N‐acetyl‐glucosamine (GlcNAc) from PG fragments that have been excised from the cell wall during growth. The 1,6‐anhydromuramoyl‐peptide products generated by NagZ activate β‐lactam resistance in many Gram‐negative bacteria by inducing the expression of AmpC β‐lactamase. Blocking NagZ activity can thereby suppress β‐lactam antibiotic resistance in these bacteria. The NagZ active site is dynamic and it accommodates distortion of the glycan substrate during catalysis using a mobile catalytic loop that carries a histidine residue which serves as the active site general acid/base catalyst. Here, we show that flexibility of this catalytic loop also accommodates structural differences in small molecule inhibitors of NagZ, which could be exploited to improve inhibitor specificity. X‐ray structures of NagZ bound to the potent yet non‐selective N‐acetyl‐β‐glucosaminidase inhibitor PUGNAc (O‐(2‐acetamido‐2‐deoxy‐d ‐glucopyranosylidene) amino‐N‐phenylcarbamate), and two NagZ‐selective inhibitors – EtBuPUG, a PUGNAc derivative bearing a 2‐N‐ethylbutyryl group, and MM‐156, a 3‐N‐butyryl trihydroxyazepane, revealed that the phenylcarbamate moiety of PUGNAc and EtBuPUG completely displaces the catalytic loop from the NagZ active site to yield a catalytically incompetent form of the enzyme. In contrast, the catalytic loop was found positioned in the catalytically active conformation within the NagZ active site when bound to MM‐156, which lacks the phenylcarbamate extension. Displacement of the catalytic loop by PUGNAc and its N‐acyl derivative EtBuPUG alters the active site conformation of NagZ, which presents an additional strategy to improve the potency and specificity of NagZ inhibitors.     

Phylogenetic variation in glycosidases and glycanases acting on plant cell wall polysaccharides, and the detection of transglycosidase and trans-β-xylanase activities

Wall polysaccharide chemistry varies phylogenetically, suggesting a need for variation in wall enzymes. Although plants possess the genes for numerous putative enzymes acting on wall carbohydrates, the activities of the encoded proteins often remain conjectural. To explore phylogenetic differences in demonstrable enzyme activities, we extracted proteins from 57 rapidly growing plant organs with three extractants, and assayed their ability to act on six oligosaccharides ‘modelling’ selected cell‐wall polysaccharides. Based on reaction products, we successfully distinguished exo‐ and endo‐hydrolases and found high taxonomic variation in all hydrolases screened: β‐d ‐xylosidase, endo‐(1→4)‐β‐d ‐xylanase, β‐d ‐mannosidase, endo‐(1→4)‐β‐d ‐mannanase, α‐d ‐xylosidase, β‐d ‐galactosidase, α‐l ‐arabinosidase and α‐l ‐fucosidase. The results, as GHATAbase, a searchable compendium in Excel format, also provide a compilation for selecting rich sources of enzymes acting on wall carbohydrates. Four of the hydrolases were accompanied, sometimes exceeded, by transglycosylase activities, generating products larger than the substrate. For example, during β‐xylosidase assays on (1→4)‐β‐d ‐xylohexaose (Xyl₆), Marchantia, Selaginella and Equisetum extracts gave negligible free xylose but approximately equimolar Xyl₅ and Xyl₇, indicating trans‐β‐xylosidase activity, also found in onion, cereals, legumes and rape. The yield of Xyl₉ often exceeded that of Xyl_7–8, indicating that β‐xylanase was accompanied by an endotransglycosylase activity, here called trans‐β‐xylanase, catalysing the reaction 2Xyl₆→ Xyl₃ + Xyl₉. Similar evidence also revealed trans‐α‐xylosidase, trans‐α‐arabinosidase and trans‐α‐arabinanase activities acting on xyloglucan oligosaccharides and (1→5)‐α‐l ‐arabino‐oligosaccharides. In conclusion, diverse plants differ dramatically in extractable enzymes acting on wall carbohydrate, reflecting differences in wall polysaccharide composition. Besides glycosidase and glycanase activities, five new transglycosylase activities were detected. We propose that such activities function in the assembly and re‐structuring of the wall matrix.     

Conformations within soluble oligomers and insoluble aggregates revealed by resonance energy transfer

A fluorescently labeled 20‐residue polyglutamic acid (polyE) peptide 20 amino acid length polyglutamic acid (E₂₀) was used to study structural changes which occur in E₂₀ as it co‐aggregates with other unlabeled polyE peptides. Resonance energy transfer (RET) was performed using an o‐aminobenzamide donor at the N‐terminus and 3‐nitrotyrosine acceptor at the C‐terminus of E₂₀. PolyE aggregates were not defined as amyloid, as they were nonfibrillar and did not bind congo red. Circular dichroism measurements indicate that polyE aggregation involves a transition from α‐helical monomers to aggregated β‐sheets. Soluble oligomers are also produced along with aggregates in the reaction, as determined through size exclusion chromatography. Time‐resolved and steady‐state RET measurements reveal four dominant E₂₀ conformations: (1) a partially collapsed conformation (24 Å donor–acceptor distance) in monomers, (2) an extended conformation in soluble oligomers (>29 Å donor–acceptor distance), (3) a minor partially collapsed conformation (22 Å donor‐acceptor distance) in aggregates, and (4) a major highly collapsed conformation (13 Å donor–acceptor distance) in aggregates. These findings demonstrate the use of RET as a means of determining angstrom‐level structural details of soluble oligomer and aggregated states of proteins. © 2009 Wiley Periodicals, Inc. Biopolymers 93: 299–317, 2010. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com     

Chemical shift perturbations induced by the acylation of Enterococcus faecium l,d-transpeptidase catalytic cysteine with ertapenem

Penicillin-binding proteins were long considered as the only peptidoglycan cross-linking enzymes and one of the main targets of β-lactam antibiotics. A new class of transpeptidases, the l,d-transpeptidases, has emerged in the last decade. In most Gram-negative and Gram-positive bacteria, these enzymes generally have nonessential roles in peptidoglycan synthesis. In some clostridiae and mycobacteria, such as Mycobacterium tuberculosis, they are nevertheless responsible for the major peptidoglycan cross-linking pathway. l,d-Transpeptidases are thus considered as appealing new targets for the development of innovative therapeutic approaches. Carbapenems are currently investigated in this perspective as they are active on extensively drug-resistant M. tuberculosis and represent the only β-lactam class inhibiting l,d-transpeptidases. The molecular basis of the enzyme selectivity for carbapenems nevertheless remains an open question. Here we present the backbone and side-chain ¹H, ¹³C, ¹⁵N NMR assignments of the catalytic domain of Enterococcus faecium l,d-transpeptidase before and after acylation with the carbapenem ertapenem, as a prerequisite for further structural and functional studies.     

Isolation and basic characterization of a β‐glucosidase from a strain of Lactobacillus brevis isolated from a malolactic starter culture

Aims: To study glycosidase activities of a Lactobacillus brevis strain and to isolate an intracellular β‐glucosidase from this strain. Methods and Results: Lactic acid bacteria (LAB) isolated from a commercially available starter culture preparation for malolactic fermentation were tested for β‐glycosidase activities. A strain of Lact. brevis showing high intracellular β‐d ‐glucosidase, β‐d ‐xylosidase and α‐l ‐arabinosidase activities was selected for purification and characterization of its β‐glucosidase. The pure glucosidase from Lact. brevis has also side activities of xylosidase, arabinosidase and cellobiosidase. It is a homotetramer of 330 kDa and has an isoelectric point at pH 3·5. The K_m for p‐nitrophenyl‐β‐d ‐glucopyranoside and p‐nitrophenyl‐β‐d ‐xylopyranoside is 0·22 and 1·14 mmol l^?1, respectively. The β‐glucosidase activity was strongly inhibited by gluconic acid δ‐lactone, partially by glucose and gluconate, but not by fructose. Ethanol and methanol were found to increase the activity up to twofold. The free enzyme was stable at pH 7·0 (t_1/2 = 50 day) but not at pH 4·0 (t_1/2 = 4 days). Conclusions: The β‐glucosidase from Lact. brevis is widely different to that characterized from Lactobacillus casei ( Coulon et al. 1998 ) and Lactobacillus plantarum ( Sestelo et al. 2004 ). The high tolerance to fructose and ethanol, the low inhibitory effect of glucose on the enzyme activity and the good long‐term stability could be of great interest for the release of aroma compounds during winemaking. Significance and Impact of the study: Although the release of aroma compounds by LAB has been demonstrated by several authors, little information exists on the responsible enzymes. This study contains the first characterization of an intracellular β‐glucosidase isolated from a wine‐related strain of Lact. brevis.     

Cloning and comparison of phylogenetically related chitinases from Listeria monocytogenes EGD and Enterococcus faecalis V583

Aims: To compare enzymatic activities of two related chitinases, ChiA and EF0361, encoded by Listeria monocytogenes and Enterococcus faecalis, respectively. Methods and Results: The chiA and EF0361 genes were amplified by PCR, cloned and expressed with histidine tags, allowing easy purification of the gene products. ChiA had a molecular weight as predicted from the amino acid sequence, whereas EF0361 was 1840 Da lower than expected because of C‐terminal truncation. The ChiA and EF0361 enzymes showed activity towards 4‐nitrophenyl N,N′‐diacetyl‐β‐d ‐chitobioside with K_m values of 1·6 and 2·1 mmol l^?1, respectively, and k_cat values of 21·6 and 6·5 s^?1. The enzymes also showed activity towards 4‐nitrophenyl β‐d ‐N, N′, N″‐triacetylchitotriose and carboxy‐methyl‐chitin‐Remazol Brilliant Violet but not towards 4‐nitrophenyl N‐acetyl‐β‐d ‐glucosaminide. Chitinolytic specificities of the enzymes were supported by their inactivity towards the substrates 4‐nitrophenyl β‐d ‐cellobioside and peptidoglycan. The pH and temperature profiles for catalytic activities were relatively similar for both the enzymes. Conclusion: The ChiA and EF0361 enzymes show a high degree of similarity in their catalytic activities although their hosts share environmental preferences only to some extent. Significance and Impact of the Study: This study contributes to an understanding of the chitinolytic activities by L. monocytogenes and Ent. faecalis. Detailed information on their chitinolytic systems will help define potential reservoirs in the natural environment and possible transmission routes into food‐manufacturing plants.     

Crystallographic and mutational analyses of cystathionine β‐synthase in the H2S‐synthetic gene cluster in Lactobacillus plantarum

Cystathionine β‐synthase (CBS) catalyzes the formation of l ‐cystathionine from l ‐serine and l ‐homocysteine. The resulting l ‐cystathionine is decomposed into l ‐cysteine, ammonia, and α‐ketobutylic acid by cystathionine γ‐lyase (CGL). This reverse transsulfuration pathway, which is catalyzed by both enzymes, mainly occurs in eukaryotic cells. The eukaryotic CBS and CGL have recently been recognized as major physiological enzymes for the generation of hydrogen sulfide (H₂S). In some bacteria, including the plant‐derived lactic acid bacterium Lactobacillus plantarum, the CBS‐ and CGL‐encoding genes form a cluster in their genomes. Inactivation of these enzymes has been reported to suppress H₂S production in bacteria; interestingly, it has been shown that H₂S suppression increases their susceptibility to various antibiotics. In the present study, we characterized the enzymatic properties of the L. plantarum CBS, whose amino acid sequence displays a similarity with those of O‐acetyl‐l ‐serine sulfhydrylase (OASS) that catalyzes the generation of l ‐cysteine from O‐acetyl‐l ‐serine (l ‐OAS) and H₂S. The L. plantarum CBS shows l ‐OAS‐ and l ‐cysteine‐dependent CBS activities together with OASS activity. Especially, it catalyzes the formation of H₂S in the presence of l ‐cysteine and l ‐homocysteine, together with the formation of l ‐cystathionine. The high affinity toward l ‐cysteine as a first substrate and tendency to use l ‐homocysteine as a second substrate might be associated with its enzymatic ability to generate H₂S. Crystallographic and mutational analyses of CBS indicate that the Ala70 and Glu223 residues at the substrate binding pocket are important for the H₂S‐generating activity.     

Conformations of helical Aib peptides containing a pair of l‐amino acid and d‐amino acid

A pair of l ‐leucine (l ‐Leu) and d ‐leucine (d ‐Leu) was incorporated into α‐aminoisobutyric acid (Aib) peptide segments. The dominant conformations of four hexapeptides, Boc‐l ‐Leu‐Aib‐Aib‐Aib‐Aib‐l ‐Leu‐OMe (1a), Boc‐d ‐Leu‐Aib‐Aib‐Aib‐Aib‐l ‐Leu‐OMe (1b), Boc‐Aib‐Aib‐l ‐Leu‐l ‐Leu‐Aib‐Aib‐OMe (2a), and Boc‐Aib‐Aib‐d ‐Leu‐l ‐Leu‐Aib‐Aib‐OMe (2b), were investigated by IR, ¹H NMR, CD spectra, and X‐ray crystallographic analysis. All peptides 1a,b and 2a,b formed 3₁₀‐helical structures in solution. X‐ray crystallographic analysis revealed that right‐handed (P) 3₁₀‐helices were present in 1a and 1b and a mixture of right‐handed (P) and left‐handed (M) 3₁₀‐helices was present in 2b in their crystalline states. Copyright © 2012 European Peptide Society and John Wiley & Sons, Ltd.     

DIFFERENCES IN POLYSACCHARIDE STRUCTURE BETWEEN CALCIFIED AND UNCALCIFIED SEGMENTS IN THE CORALLINE CALLIARTHRON CHEILOSPORIOIDES (CORALLINALES,RHODOPHYTA)1

The articulated coralline Calliarthron cheilosporioides Manza produces segmented fronds composed of calcified segments (intergenicula) separated by uncalcified joints (genicula), which allow fronds to bend and reorient under breaking waves in the wave‐swept intertidal zone. Genicula are formed when calcified cells decalcify and restructure to create flexible tissue. The present study has identified important differences in the main agaran disaccharidic repeating units [→3)‐β‐d ‐Galp (1→ 4)‐α‐l ‐Galp(1→] synthesized by genicular and intergenicular segments. Based on chemical and spectroscopical analyses, we report that genicular cells from C. cheilosporioides biosynthesize a highly methoxylated galactan at C‐6 position with low levels of branching with xylose side stubs on C‐6 of the [→3)‐β‐d ‐Galp (1→] units, whereas intergenicular segments produce xylogalactans with high levels of xylose and low levels of 6‐O‐methyl β‐d ‐Gal units. These data suggest that, during genicular development, xylosyl branched, 3‐linked β‐d ‐Galp units present in the xylogalactan backbones from intergenicular walls are mostly replaced by 6‐O‐methyl‐d‐ galactose units. We speculate that this structural shift is a consequence of a putative and specific methoxyl transferase that blocks the xylosylation on C‐6 of the 3‐linked β‐d ‐Galp units. Changes in galactan substitutions may contribute to the distinct mechanical properties of genicula and may lend insight into the calcification process in coralline algae.     

Inhibitory effects of enterococci on the production of hydrogen sulfide by hydrogen sulfide-producing bacteria in raw meat

Aims: Applying competitive exclusion micro‐organisms to control hydrogen sulfide (H₂S) gas produced by hydrogen sulfide–producing bacteria (SPB) in chicken meat. Methods and Results: Five SPB strains, isolated from animal by‐products, were used for screening lactic acid bacteria (LAB) that can inhibit the production of H₂S by SPB in trypticase soy broth supplemented with l ‐cysteine (TSB‐l ‐cys). A sensitive and accurate test strip method was developed for H₂S determination in real time. One LAB strain, isolate L86, from cheese whey, demonstrated the highest inhibitory activity against the production of H₂S by SPB. The isolate L86 was confirmed as Enterococcus faecium that does not possess genes encoding for vancomycin resistance based on PCR analysis. Enterococcus faecium strain L86 reduced (P < 0·05) the yield of H₂S upto 51·2% in 10 h at 35°C in TSB‐l ‐cys medium. In fresh chicken meat, the yield of H₂S produced by the artificially inoculated SPB was reduced (P < 0·05) by 48·6, 49·7 and 69·8% in 10 h at 35, 30 and 25°C, respectively. Enterococcus faecium strain L86 also reduced (P < 0·05) by 53·8% on the yield of H₂S produced by the indigenous SPB in partially spoiled chicken meat at 35°C for 10 h. Conclusions: Enterococcus faecium strain L86 is effective on inhibiting the production of H₂S by SPB. Significance and Impact of the Study: The application of this biological agent to raw animal by‐products will provide a safer working environment in rendering processing plants and produce higher‐quality rendered products.     

Structure of the pneumococcal l,d‐carboxypeptidase DacB and pathophysiological effects of disabled cell wall hydrolases DacA and DacB

Bacterial cell wall hydrolases are essential for peptidoglycan turnover and crucial to preserve cell shape. The d ,d ‐carboxypeptidase DacA and l ,d ‐carboxypeptidase DacB of Streptococcus pneumoniae function in a sequential manner. Here, we determined the structure of the surface‐exposed lipoprotein DacB. The crystal structure of DacB, radically different to that of DacA, contains a mononuclear Zn²⁺ catalytic centre located in the middle of a large and fully exposed groove. Two different conformations were found presenting a different arrangement of the active site topology. The critical residues for catalysis and substrate specificity were identified. Loss‐of‐function of DacA and DacB altered the cell shape and this was consistent with a modified peptidoglycan peptide composition in dac mutants. Contrary, an lgt mutant lacking lipoprotein diacylglyceryl transferase activity required for proper lipoprotein maturation retained l ,d ‐carboxypeptidase activity and showed an intact murein sacculus. In addition we demonstrated pathophysiological effects of disabled DacA or DacB activities. Real‐time bioimaging of intranasal infected mice indicated a substantial attenuation of ΔdacB and ΔdacAΔdacB pneumococci, while ΔdacA had no significant effect. In addition, uptake of these mutants by professional phagocytes was enhanced, while the adherence to lung epithelial cells was decreased. Thus, structural and functional studies suggest DacA and DacB as optimal drug targets.     

Genomic insights into the metabolic potential of the polycyclic aromatic hydrocarbon degrading sulfate‐reducing Deltaproteobacterium N47

Anaerobic degradation of polycyclic aromatic hydrocarbons (PAHs) is an important process during natural attenuation of aromatic hydrocarbon spills. However, knowledge about metabolic potential and physiology of organisms involved in anaerobic degradation of PAHs is scarce. Therefore, we introduce the first genome of the sulfate‐reducing Deltaproteobacterium N47 able to catabolize naphthalene, 2‐methylnaphthalene, or 2‐naphthoic acid as sole carbon source. Based on proteomics, we analysed metabolic pathways during growth on PAHs to gain physiological insights on anaerobic PAH degradation. The genomic assembly and taxonomic binning resulted in 17 contigs covering most of the sulfate reducer N47 genome according to general cluster of orthologous groups (COGs) analyses. According to the genes present, the Deltaproteobacterium N47 can potentially grow with the following sugars including d ‐mannose, d ‐fructose, d ‐galactose, α‐d ‐glucose‐1P, starch, glycogen, peptidoglycan and possesses the prerequisites for butanoic acid fermentation. Despite the inability for culture N47 to utilize NO₃^‐ as terminal electron acceptor, genes for nitrate ammonification are present. Furthermore, it is the first sequenced genome containing a complete TCA cycle along with the carbon monoxide dehydrogenase pathway. The genome contained a significant percentage of repetitive sequences and transposase‐related protein domains enhancing the ability of genome evolution. Likewise, the sulfate reducer N47 genome contained many unique putative genes with unknown function, which are candidates for yet‐unknown metabolic pathways.     

Chromatographic profiles of tryptophan and kynurenine enantiomers derivatized with (S)‐4‐(3‐isothiocyanatopyrrolidin‐1‐yl)‐7‐(N,N‐dimethylaminosulfonyl)‐2,1,3‐benzoxadiazole using LC–MS/MS on a triazole‐bonded column

d ‐ and l ‐Tryptophan (Trp) and d ‐ and l ‐kynurenine (KYN) were derivatized with a chiral reagent, (S )‐4‐(3‐isothiocyanatopyrrolidin‐1‐yl)‐7‐(N,N‐dimethylaminosulfonyl)‐2,1,3‐benzoxadiazole (DBD‐PyNCS), and were separated enantiomerically by high‐performance liquid chromatography (HPLC) equipped with a triazole‐bonded column (Cosmosil HILIC) using tandem mass spectrometric (MS/MS) detection. Effects of column temperature, salt (HCO₂NH₄) concentration, and pH of the mobile phase in the enantiomeric separation, followed by MS detection of (S )‐DBD‐PyNCS‐d ,l ‐Trp and ‐d ,l ‐KYN, were investigated. The mobile phase consisting of CH₃CN/10 mM ammonium formate in H₂O (pH 5.0) (90/10) with a column temperature of 50–60 °C gave satisfactory resolution (R s) and mass‐spectrometric detection. The enantiomeric separation of d ,l ‐Trp and d ,l ‐KYN produced R s values of 2.22 and 2.13, and separation factors (α) of 1.08 and 1.08, for the Trp and KYN enantiomers, respectively. The proposed LC–MS/MS method provided excellent detection sensitivity of both enantiomers of Trp and KYN (5.1–19 nM).