New Insights into the Fructosyltransferase Activity of Schwanniomyces occidentalis β-Fructofuranosidase,Emerging from Nonconventional Codon Usage and Directed Mutation

Schwanniomyces occidentalis β-fructofuranosidase (Ffase) releases β-fructose from the nonreducing ends of β-fructans and synthesizes 6-kestose and 1-kestose, both considered prebiotic fructooligosaccharides. Analyzing the amino acid sequence of this protein revealed that it includes a serine instead of a leucine at position 196, caused by a nonuniversal decoding of the unique mRNA leucine codon CUG. Substitution of leucine for Ser196 dramatically lowers the apparent catalytic efficiency (k_cat/K_m) of the enzyme (approximately 1,000-fold), but surprisingly, its transferase activity is enhanced by almost 3-fold, as is the enzymes'' specificity for 6-kestose synthesis. The influence of 6 Ffase residues on enzyme activity was analyzed on both the Leu196/Ser196 backgrounds (Trp47, Asn49, Asn52, Ser111, Lys181, and Pro232). Only N52S and P232V mutations improved the transferase activity of the wild-type enzyme (about 1.6-fold). Modeling the transfructosylation products into the active site, in combination with an analysis of the kinetics and transfructosylation reactions, defined a new region responsible for the transferase specificity of the enzyme.β-Fructofuranosidases (EC 3.2.1.26) are enzymes of biotechnological interest that catalyze the release of β-fructose from the nonreducing termini of various β-d-fructofuranoside substrates. In general, they exhibit a high degree of sequence homology, and based on their amino acid sequences, they fall into family 32 of the glycosyl-hydrolases (GH), along with invertases, inulinases, and fructosyltransferases (http://www.cazy.org). The GH32 family has been studied intensely, and some three-dimensional structures are now available, such as that of inulinase from Aspergillus awamorii (26), fructan-exohydrolase from Cichorium intybus (CiFEH) (34, 36), or invertase from Thermotoga maritima (2, 3) and Arabidopsis thaliana (35). These proteins contain a five-blade β-propeller N-terminal catalytic module and a C-terminal β-sandwich domain (19). Multiple-sequence alignment of GH32 proteins, which are included in the GH-J clan together with the GH68 proteins of the inulosucrase family, reveals the presence of three conserved motifs, each containing a key acidic residue (in boldface) implicated in substrate binding and hydrolysis: Asn-Asp-Pro-Asn-Gly (NDPNG), Arg-Asp-Pro (RDP), and Glu-Cys (EC) (28). These conserved residues are implicated in a double-displacement reaction in which a covalent glycosyl-enzyme intermediate is formed. Thus, the catalytic mechanism proposed for the Saccharomyces cerevisiae invertase implies that Asp23 (NDPNG) acts as a nucleophile and Glu204 (EC) acts as the acid/base catalyst (29), whereas Asp309 (RDP) of Acetobacter diazotropicus levansucrase influences the efficiency of sucrose hydrolysis (7) and Arg188 and Asp189 of the latter motif define the substrate binding and specificity of exoinulinase from A. awamorii toward fructopyranosyl residues (26).As well as hydrolyzing sucrose, β-fructofuranosidases may also catalyze the synthesis of short-chain fructooligosaccharides (FOS), in which one to three fructosyl moieties are linked to the sucrose skeleton by different glycosidic bonds, depending on the source of the enzyme (12, 21, 31). FOS act as prebiotics, and they exert a beneficial effect on human health, participating in the prevention of cardiovascular diseases, colon cancer, and osteoporosis (16). Currently, FOS are mainly produced by Aspergillus fructosyltransferase in industry (10, 31), providing a mixture of FOS with an inulin-type structure that contains β-(2→1)-linked fructose oligomers (¹F-FOS: 1-kestose or nystose). Curiously, when the link between two fructose units (⁶F-FOS: 6-kestose) or between fructose and the glucosyl moiety (⁶G-FOS: neokestose) involves a β-(2→6) link, the prebiotic properties of the FOS may be enhanced beyond that of commercial FOS (23).The yeast Schwanniomyces occidentalis (also called Debaryomyces occidentalis) produces a number of extracellular enzymes that make it of interest in biotechnology. Several of its amylolytic enzymes have been characterized, including amylases and glucoamylase (1, 9), as well as an invertase (17). In addition, we also characterized an extracellular β-fructofuranosidase (Ffase) from this yeast that hydrolyzes sucrose, 1-kestose, and nystose (5). This enzyme exhibited a transfructosylating activity that efficiently produces the trisaccharides 6-kestose and 1-kestose in the ratio 3:1, generating the highest 6-kestose yield yet reported, as far as we know. The Ffase three-dimensional structure has recently been solved (6) and represented as a homodimer, each modular subunit arranged like other GH32 enzymes. The Asp50 (NDPNG) and Glu230 (EC) located at the center of the propeller are the catalytic residues implicated in substrate binding and hydrolysis, whereas Arg178 and Asp179 form the RDP motif (6).The genetic codes of some yeasts incorporate certain variations. For example, while CUG was believed to be a universal codon for leucine, in the cytoplasm of certain species of the genus Candida (15) it encodes a serine, as in Pichia farinosa (33). The reassignment of this codon is mediated by a novel serine-tRNA that acquired a leucine 5′-CAG-3′ anticodon (25).Here, we show that deviation from the standard use of the CUG leucine codon to encode serine was correlated with the transferase capacity and specificity of the Ffase enzyme. Indeed, the S196L substitution enhanced the transferase activity of the enzyme 3-fold. Several site-directed mutants were generated and characterized to study their transferase capacities. These results are considered on the basis of the enzymes'' three-dimensional structure, which enables a novel putative binding site of sucrose that serves as a water substitute donor in the hydrolytic reaction yielding the tranglycosylation product 6-kestose to be identified.     

Left-sided infective endocarditis caused by Pseudomonas aeruginosa treated medically

Infective endocarditis due to Pseudomonas aeruginosa is a rare clinical condition, difficult to diagnose and associated with high mortality. Herein we present a case of a 51 years old male without history of intravenous drug use or valvular disease, with past medical history of cholecystectomy in the previous month, who presented to the emergency department with fever, gastrointestinal symptoms, and subsequent signs of distant embolization, positive blood cultures for P. aeruginosa and development of multiple complications of the disease. The clinical presentation of infective endocarditis is nonspecific, leading to delayed diagnosis, and preventing early and effective treatment. Valvular replacement is indicated in fungal or P. aeruginosa endocarditis. This case is notable because of the resolution with amikacin combined with meropenem, in a patient with several complications that contraindicated surgery.     

Diversity of Glycosyl Hydrolases from Cellulose-Depleting Communities Enriched from Casts of Two Earthworm Species

The guts and casts of earthworms contain microbial assemblages that process large amounts of organic polymeric substrates from plant litter and soil; however, the enzymatic potential of these microbial communities remains largely unexplored. In the present work, we retrieved carbohydrate-modifying enzymes through the activity screening of metagenomic fosmid libraries from cellulose-depleting microbial communities established with the fresh casts of two earthworm species, Aporrectodea caliginosa and Lumbricus terrestris, as inocula. Eight glycosyl hydrolases (GHs) from the A. caliginosa-derived community were multidomain endo-β-glucanases, β-glucosidases, β-cellobiohydrolases, β-galactosidase, and β-xylosidases of known GH families. In contrast, two GHs derived from the L. terrestris microbiome had no similarity to any known GHs and represented two novel families of β-galactosidases/α-arabinopyranosidases. Members of these families were annotated in public databases as conserved hypothetical proteins, with one being structurally related to isomerases/dehydratases. This study provides insight into their biochemistry, domain structures, and active-site architecture. The two communities were similar in bacterial composition but significantly different with regard to their eukaryotic inhabitants. Further sequence analysis of fosmids and plasmids bearing the GH-encoding genes, along with oligonucleotide usage pattern analysis, suggested that those apparently originated from Gammaproteobacteria (pseudomonads and Cellvibrio-like organisms), Betaproteobacteria (Comamonadaceae), and Alphaproteobacteria (Rhizobiales).Microorganisms producing diverse glycosyl hydrolases (GHs) are widespread and typically thrive in environments where plant materials tend to accumulate and deteriorate (42, 73). The habitats of microorganisms with great GH diversity are the ruminant animal rumen, mouse bowel, and rabbit cecum (10, 24, 26, 28, 49, 74). Microorganisms associated with soil invertebrates in general and with soil earthworms in particular carry out metabolic processes that contribute to element cycling and are essential in sustaining processes which their hosts are unable to perform (20, 52, 72, 76). Although some species of earthworms produce cellulases (15, 55), they generally rely on microbes inhabiting their gastrointestinal (GI) tracts to perform cellulose utilization processes (31, 47, 77). Casts are of special interest in this respect. Considering that the overall numbers of cellulolytic microbes in earthworm casts are greater than those in soil (57), earthworm casts seem to play an important role in the decomposition of plant litter, serving as an inoculum for cellulosic substrates (9). It is important to note that microorganisms from preingested substratum (soil or plant litter) are predominant in the gut lumen (20); however, microbial populations in earthworm casts differ from those in soil in terms of diversity and the relative abundance of different taxa (29, 57, 63). It is anticipated that the enzymatic repertoire of such microbial communities must be especially broad toward diverse sugar-based polymeric, oligomeric, and monomeric substrates; however, among approximately 115 families of GHs with thousands of members known to date (12), none of the GHs have been derived from microorganisms of earthworm-associated microbial communities.The aim of the present work was therefore to examine the diversity of GHs in metagenome libraries derived from fresh casts of Aporrectodea caliginosa and Lumbricus terrestris earthworms via functional screening. Other important tasks of this work were to characterize individual enzymes and to gain insight into their structural-functional features. Finally, we performed sequence analysis of large contiguous DNA fragments of fosmids harboring the genes for GHs to associate them with the organism(s) that may produce them, which was complemented by conventional small-subunit (SSU) rRNA clone library sequencing analysis.     

Enzymatic hydrolysis and fermentation of palm kernel press cake for production of bioethanol

Palm kernel press cake (PKC) is a residue of palm oil extraction, which was found to contain 48.5% of total carbohydrates of which 35.2% was mannan. The present study examines enzymatic hydrolysis of polysaccharides from the cell-wall material present in PKC to obtain monosaccharides that can be substrate in various fermentation processes such as ethanol production. The requirements for pretreatment were investigated and it was found that mannan in PKC was readily hydrolysed without any pretreatment. Several enzyme preparations were tested and Mannaway 25L was found as the best for releasing mannose, and Gammanase 1.0L worked well in degrading cellulose and mannose. Binary mixtures of enzymes were tested to increase the conversion, and 1:1 mixture of Mannaway 25L and Gammanase 1.0L showed good synergistic effect releasing 30% more mannose than the sum obtained using these enzymes individually. Using an enzyme loading of 2.3 mg protein/g PKC resulted in 63% of mannan in PKC being hydrolysed to mannose in 24 h, and in 96 h a total of 365 g mannose and glucose could be produced per kg PKC. Finally, PKC was hydrolysed and fermented using Saccharomyces cerevisiae with an ethanol yield of 125 g/kg PKC.