The enzymatic degradation of plant cell wall xylan requires the concerted action of a diverse enzymatic syndicate. Among these enzymes are xylan esterases, which hydrolyze the O-acetyl substituents, primarily at the O-2 position of the xylan backbone. All acetylxylan esterase structures described previously display a ␣/ hydrolase fold with a "Ser-His-Asp" catalytic triad. Here we report the structures of two distinct acetylxylan esterases, those from Streptomyces lividans and Clostridium thermocellum, in native and complex forms, with x-ray data to between 1.6 and 1.0 Å resolution. We show, using a novel linked assay system with PNP-2-O-acetylxyloside and a -xylosidase, that the enzymes are sugar-specific and metal ion-dependent and possess a single metal center with a chemical preference for Co 2؉ . Asp and His side chains complete the catalytic machinery. Different metal ion preferences for the two enzymes may reflect the surprising diversity with which the metal ion coordinates residues and ligands in the active center environment of the S. lividans and C. thermocellum enzymes. These "CE4" Many plant cell wall polysaccharides, including xylan, mannan, and pectin are present in acetylated forms. Acetylation not only modifies the physicochemical properties of polysaccharides, notably increasing the solubility for matrix applications, but also means they are less readily attacked by phytopathogen-derived cell wall-degrading endoglycosidases. To overcome the steric problems provided by acetyl substituents, plant cell wall degrading microorganisms have developed a host of acetyl esterases whose function is to deacetylate the polysaccharides prior to, or concomitant with, its complete hydrolysis by a consortium of exo-and endo-acting glycoside hydrolases. Such microbial esterases have, unsurprisingly, found widespread industrial application in both biomass conversion and for the chemoenzymatic synthesis of diverse esters (see for example Refs. 1 and 2 and reviewed in Ref.3).Xylan is a chemically and structurally complex plant cell wall polysaccharide, whose complete degradation requires the action of a dedicated enzymatic consortium, . Thus far, structures of ferulate and acetylxylan esterases have revealed a ␣/ hydrolase fold, and they display a Ser-His-Asp catalytic triad. Examples include the family CE1 (predominantly bacterial) ferulate esterases (8 -10), the currently unclassified fungal ferulate esterases (11-13) and the xylan and xylooligosaccharide esterases from families CE5 (14, 15), CE6 (putative esterases, PDB code 2APJ, Centre for Eukaryotic Structural Genomics), and CE7 (16). Enzymes in the largest sequence-based esterase family, CE4, do not, however, display the standard ␣/ hydrolase fold.The carbohydrate esterase family CE4 contains over 870 open reading frames.3 This family is notable, not merely for its size, but also as many CE4 members have been reported to be metal ion-dependent. Furthermore, family CE4 contains members with both classical de-Oacetylase activity, such as the acetylxylan est...
This study demonstrated the capacity of bacteriocin-producing lactic acid bacteria (LAB) to reduce intestinal colonization by vancomycin-resistant enterococci (VRE) in a mouse model. Lactococcus lactis MM19 and Pediococcus acidilactici MM33 are bacteriocin producers isolated from human feces. The bacteriocin secreted by P. acidilactici is identical to pediocin PA-1/AcH, while PCR analysis demonstrated that L. lactis harbors the nisin Z gene. LAB were acid and bile tolerant when assayed under simulated gastrointestinal conditions. A well diffusion assay using supernatants from LAB demonstrated strong activity against a clinical isolate of VRE. A first in vivo study was done using C57BL/6 mice that received daily intragastric doses of L. lactis MM19, P. acidilactici MM33, P. acidilactici MM33A (a pediocin mutant that had lost its ability to produce pediocin), or phosphate-buffered saline (PBS) for 18 days. This study showed that L. lactis and P. acidilactici MM33A increased the concentrations of total LAB and anaerobes while P. acidilactici MM33 decreased the Enterobacteriaceae populations. A second in vivo study was done using VRE-colonized mice that received the same inocula as those in the previous study for 16 days. In L. lactis-fed mice, fecal VRE levels 1.73 and 2.50 log 10 CFU/g lower than those in the PBS group were observed at 1 and 3 days postinfection. In the P. acidilactici MM33-fed mice, no reduction was observed at 1 day postinfection but a reduction of 1.85 log 10 CFU/g was measured at 3 days postinfection. Levels of VRE in both groups of mice treated with bacteriocin-producing LAB were undetectable at 6 days postinfection. No significant difference in mice fed the pediocin-negative strain compared to the control group was observed. This is the first demonstration that human L. lactis and P. acidilactici nisin-and pediocin-producing strains can reduce VRE intestinal colonization.
The construction of a cosmid library from the biomass produced in an enriched Sequencing Fed-Batch Reactor allowed the isolation of a new lipase by functional screening. The open reading frame of 928 bp encoded a polypeptide of 308 amino acids with a molecular mass of 32.6 kDa. The amino acid sequence analysis revealed the presence of the conserved pentapeptide GXSXG essential for lipase activity. Alignment with known sequences of proteins showed no more than 52% identity with different lipases, confirming the discovery of a novel gene sequence. The lipase was cloned and expressed in Streptomyces lividans and further purified by a combination of hydrophobic interaction and size-exclusion chromatography. Spectrophotometric assays with different p-nitrophenyl esters demonstrated a preference for long-length acyl chains, especially p-nitrophenylmyristate (C14). Moreover, the enzyme presented an optimal activity at 60 degrees C and at alkaline pH of 10.5.
The lack of a commercially available robust and inexpensive laccase is a major barrier to the widespread application of this enzyme in various industrial sectors. By using an efficient system developed in Streptomyces lividans, we have produced by homologous expression 350 mg L(-1) of a bacterial laccase with a high purity and without any extensive purification. This is the highest production yield reported in the literature for a bacterial laccase. The secreted enzyme achieved oxidation under a wide pH range depending on the substrate: 4.0 for 2,2'-azino-bis(3-ethylbenzothiazoline-6-sulfonate) and 9.0 for 2,6-dimethoxyphenol. Furthermore, this bacterial laccase was found to be quite resistant under various conditions. It withstands pH from 3.0 to 9.0, shows a great thermostability at 70 degrees C and was highly resistant toward conventional inhibitors. For instance, while the laccase of Trametes versicolor was completely inhibited by 1 mM NaN(3), the laccase of Streptomyces coelicolor was fully active under the same conditions. To assess application potential of this laccase, we have investigated its ability to decolourise Indigo carmine. This enzyme was able to rapidly decolourise the dye in the presence of syringaldehyde as a redox mediator.
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