Metagenomic discovery of feruloyl esterases from rumen microflora.

Feruloyl esterases (FAEs) are a key group of enzymes that hydrolyze ferulic acids ester-linked to plant polysaccharides. The cow's rumen is a highly evolved ecosystem of complex microbial microflora capable of converting fibrous substances to energy. From direct cloning of the rumen microbial metagenome, we identified seven active phagemids conferring feruloyl esterase activity. The genomic inserts ranged from 1633 to 4143 bp, and the ORFs from 681 to 1359 bp. BLAST search reveals sequence homology to feruloyl esterases and esterases/lipases identified in anaerobes. The seven genes were expressed in Escherichia coli, and the proteins were purified to homogeneity. The FAEs were found to cover types B, C, and D in the feruloyl esterase classification system using model hydroxycinnamic acid esters. The release of ferulic acid (FA) catalyzed by these enzymes was established using natural substrates corn fiber (CF) and wheat insoluble arabinoxylan (WIA). Three of the enzymes were demonstrated to cleave diferulates and hence the capability to break down Araf-FA-FA-Araf cross-links. The wide variation in the sequence, activity, and substrate specificity observed in the FAEs discovered in this study is a confirming evidence that combined actions of a full range of FAE enzymes contribute to the high-efficiency fiber digestion in the rumen microbial ecosystem.

A novel method for rapid and sensitive metagenomic activity screening.

Direct cloning of metagenomes has proven to be a powerful tool for the exploration of the diverse sequence space of a microbial community leading to gene discovery and biocatalyst development. The key to such approach is the development of rapid, sensitive, and reliable functional screening of libraries. The majority of library screen have relied on the use of agar plates in petri dishes incorporating the target enzyme substrate for activity detection of positive clones (Iqbal et al. [1], Knietsch et al. [2], Popovic et al. [3]). In this article, a novel method is described consisting of: (1) formulation and application of substrate gel microtiter assay plates, (2) screening of libraries of clones in split pools in the wells of the assay plate, and (3) progressive enrichment and isolation of individual positive clones. The method has been successfully used in the rapid discovery of novel genes and enzymes from rumen microbial metagenome with high efficacy. •Novel substrate gel assay plates for activity screening with localized and intensified signals.•Rapid and complete screening of library clones in split pools.•Progressive enrichment scheme as a refining step for isolating target gene.

Cloning of a Novel Feruloyl Esterase from Rumen Microbial Metagenome for Substantial Yield of Mono- and Diferulic Acids from Natural Substrates.

A feruloyl esterase (FAE) gene was isolated from a rumen microbial metagenome, cloned into E. coli, and expressed in active form. The enzyme (RuFae4) was classified as a Type D feruloyl esterase based on its action on synthetic substrates and ability to release diferulates. The RuFae4 alone released ferulic acid (FA) and diferulic acid (diFA) from wheat insoluble arabinoxylan (WIA) and other natural substrates. The diFA released was confirmed by mass spectrometry. A maximum of 205±5.7 µg FA and 0.84±0.1 µg diFA were released (37°C, pH 6.5, 2 hr) when a saturating amount of RuFae4 (23 nmole for 100 mg WIA) was used. These yields represent 48.3% of FA, and 6.6% of diFAs present in the WIA substrate. Addition of GH10 endoxylanase (EX) to RuFae4 both at 1 nmole concentrations increased the release of FA and diFAs by 17 and 10 fold, respectively. Addition of GH11 EX resulted in smaller increase in the amount of both FA and diFAs. Applying additive amount of the two enzymes did not lead to additive increase in the product yields, suggesting that it was primarily the GH10 enzyme contributing synergism to FA/diFA release in mixed reactions.

Cloning of a novel feruloyl esterase gene from rumen microbial metagenome and enzyme characterization in synergism with endoxylanases.

A feruloyl esterase (FAE) gene was isolated from a rumen microbial metagenome, cloned into E. coli, and expressed in active form. The enzyme (RuFae2) was identified as a type C feruloyl esterase. The RuFae2 alone released ferulic acid from rice bran, wheat bran, wheat-insoluble arabinoxylan, corn fiber, switchgrass, and corn bran in the order of decreasing activity. Using a saturating amount of RuFae2 for 100 mg substrate, a maximum of 18.7 and 80.0 µg FA was released from 100 mg corn fiber and wheat-insoluble arabinoxylan, respectively. Addition of GH10 endoxylanase (EX) synergistically increased the release of FA with the highest level of 6.7-fold for wheat bran. The synergistic effect of adding GH11 EX was significantly smaller with all the substrates tested. The difference in the effect of the two EXs was further analyzed by comparing the rate in the release of FA with increasing EX concentration using wheat-insoluble arabinoxylan as the substrate.

Engineering Saccharomyces cerevisiae to produce feruloyl esterase for the release of ferulic acid from switchgrass.

The Aspergillus niger feruloyl esterase gene (faeA) was cloned into Saccharomyces cerevisiae via a yeast expression vector, resulting in efficient expression and secretion of the enzyme in the medium with a yield of ~2 mg/l. The recombinant enzyme was purified to homogeneity by anion-exchange and hydrophobic interaction chromatography. The specific activity was determined to be 8,200 U/µg (pH 6.5, 20°C, 3.5 mM 4-nitrophenyl ferulate). The protein had a correct N-terminal sequence of ASTQGISEDLY, indicating that the signal peptide was properly processed. The FAE exhibited an optimum pH of 6-7 and operated optimally at 50°C using ground switchgrass as the substrate. The yeast clone was demonstrated to catalyze the release of ferulic acid continuously from switchgrass in YNB medium at 30°C. This work represents the first report on engineering yeast for the breakdown of ferulic acid crosslink to facilitate consolidated bioprocessing.

Enzymatic activation of lysine 2,3-aminomutase from Porphyromonas gingivalis.

The development of lysine 2,3-aminomutase as a robust biocatalyst hinges on the development of an in vivo activation system to trigger catalysis. This is the first report to show that, in the absence of chemical reductants, lysine 2,3-aminomutase activity is dependent upon the presence of flavodoxin, ferredoxin, or flavodoxin-NADP(+) reductase.

Discovery of enzymatic activity using stable isotope metabolite labeling and liquid chromatography-mass spectrometry.

Stable isotope labeling of an intracellular chemical precursor or metabolite allows direct detection of downstream metabolites of that precursor, arising from novel enzymatic activity of interest, using metabolite profiling liquid chromatography-mass spectrometry. This approach allows the discrimination of downstream metabolites produced from novel enzymatic activity from the unlabeled form of the metabolite arising from native metabolic processes within the cell. Even for the case in which a given product of novel enzymatic activity is a transient, the novel enzymatic activity that produced it can be demonstrated to exist indirectly by identification of product-specific downstream metabolites. Therefore, direct or indirect discovery of novel enzymatic machinery engineered within a cell can be accomplished without a requirement for direct product purification or identification. The application of this approach to confirm the presence of a novel metabolic activity, alanine 2,3-aminomutase, obtained by mutagenesis and selection are discussed. The advantages of metabolite profiling approaches to metabolic engineering in terms of accelerating enzyme discovery and development of intellectual property will also be highlighted.