Biochemical and Domain Analyses of FSUAxe6B,a Modular Acetyl Xylan Esterase,Identify a Unique Carbohydrate Binding Module in Fibrobacter succinogenes S85

Acetyl xylan esterase (EC 3.1.1.72) is a member of a set of enzymes required to depolymerize hemicellulose, especially xylan that is composed of a main chain of β-1,4-linked xylopyranoside residues decorated with acetyl side groups. Fibrobacter succinogenes S85 Axe6B (FSUAxe6B) is an acetyl xylan esterase encoded in the genome of this rumen bacterium. The enzyme is a modular protein comprised of an esterase domain, a carbohydrate-binding module, and a region of unknown function. Sequences that are homologous to the region of unknown function are paralogously distributed, thus far, only in F. succinogenes. Therefore, the sequences were designated Fibrobacter succinogenes-specific paralogous module 1 (FPm-1). The FPm-1s are associated with at least 24 polypeptides in the genome of F. succinogenes S85. A bioinformatics search showed that most of the FPm-1-appended polypeptides are putative carbohydrate-active enzymes, suggesting a potential role in carbohydrate metabolism. Truncational analysis of FSUAxe6B, together with catalytic and substrate binding studies, has allowed us to delineate the functional modules in the polypeptide. The N-terminal half of FSUAxe6B harbors the activity that cleaves side chain acetyl groups from xylan-like substrates, and the binding of insoluble xylan was determined to originate from FPm-1. Site-directed mutagenesis studies of highly conserved active-site residues in the esterase domain suggested that the esterase activity is derived from a tetrad composed of Ser₄₄, His₂₇₃, Glu₁₉₄, and Asp₂₇₀, with both Glu₁₉₄ and Asp₂₇₀ functioning as helper acids, instead of a single carboxylate residue proposed to initiate catalysis.The development of strategies for biomass conversion to fuels (biofuels) is a subject of keen interest as we search for energy resources alternative to fossil fuels (39). Plant cell matter accounts for 150 to 200 billion tons of biomass on our planet annually (31). It is technically possible, but economically far from realization, to convert plant cell wall to biofuels (41). Thus, currently, plant cell wall utilization as a source of biofuels is mostly at the laboratory scale, although there is a great impetus to move production to the industrial scale.The main components of the plant cell wall are cellulose, hemicellulose, and lignin. These components form complex structures that provide the plant with physical strength (42). Biologically, there are two major steps in the production of alcohols from plant-based feedstock. The first step is an enzymatic hydrolysis of the plant cell wall components to fermentable sugars, and the second step is fermentation of the resultant sugars into alcohols. A major limitation of the process is the lack of highly efficient biocatalysts required for the first step. However, it is known that microbes, either as individuals or consortia, that harbor genes encoding enzymes that hydrolyze plant cell wall polysaccharides abound in nature. Research efforts directed at deepening knowledge of how multiple enzymes participate synergistically to degrade the plant cell wall will accelerate the capacity to achieve the goal of converting biomass to biofuels on a large scale (12, 27). However, improvement of “enzyme cocktails” developed for depolymerization of lignocellulosic biomass will be dependent on a better understanding of the structure/function of individual enzymes that together constitute the arsenal of enzymes (hydrolyzome) used by naturally occurring organisms known to be highly efficient in plant cell wall degradation.Ruminant animals harbor a variety of plant cell wall-degrading bacteria in their first stomach or rumen (26). These animals digest forages with the aid of a microbial consortium that is able to metabolize plant cell wall polysaccharides to short-chain fatty acids, the main energy source for the ruminant host. Fibrobacter succinogenes is a ubiquitous rumen bacterium and has been estimated in previous reports to occupy 0.1% to 1.0% of the microbial population in the cattle rumen, based on the quantification of 16S rRNA genes as a marker (25, 43). F. succinogenes is a significant cellulolytic rumen bacterium, and it has the ability to grow on crystalline cellulose as a sole source of carbon and energy (17). Additionally, it has been demonstrated that this bacterium can solubilize hemicelluloses, although it only partially utilized the constituent monosaccharides released (34). As further evidence, F. succinogenes failed to grow on xylose (33), a constituent of most hemicelluloses. Since F. succinogenes is a highly versatile microbe capable of degrading both cellulose and hemicellulose, strains of this bacterium are attractive models to study natural strategies for efficient deconstruction of plant cell wall polysaccharides.Through analysis of the genome sequence of F. succinogenes S85, a gene cluster that encodes more than 10 hemicellulose-targeting enzymes was identified. Most of the enzymes in the cluster are modular polypeptides, a common feature in many carbohydrate-active enzymes. Kam and coworkers (23) previously identified two acetyl xylan esterases (Axe6A and Axe6B) in this cluster and predicted that each gene encoded a polypeptide composed of two domains: an esterase catalytic domain and a family 6 carbohydrate-binding module (CBM6). Whereas Axe6A was fairly well characterized, difficulties in expression of recombinant Axe6B restricted its characterization (23). In this report, overproduction of recombinant F. succinogenes S85 Axe6B (FSUAxe6B) is demonstrated, and furthermore, it is shown that rather than having two domains, the polypeptide harbors three domains composed of an esterase, CBM6, and a region of unknown function. Bioinformatics analysis suggested that the unknown domain observed in FSUAxe6B is, so far, distributed only in F. succinogenes S85; thus, it was designated F. succinogenes-specific paralogous module 1 or FPm-1. Twenty-four polypeptides, with the majority containing glycoside hydrolase family motifs and CBMs, were found to harbor this peptide at the extreme C-terminal region. In addition to assigning a carbohydrate binding function to FPm-1, critical residues that confer esterase activity to the N-terminal half of FSUAxe6B were also identified through site-directed mutagenesis.