Oligoalginate Lyase Research Articles

Winogradskyella immobilis sp. nov., an Alginate-Hydrolyzing Bacterium Isolated from the Brown Algae Saccharina japonica.

A novel bacterium, designated E313T, was isolated from brown algae Saccharina japonica in Weihai, China. The strain is a Gram-stain-negative, non-flagellated, non-gliding, aerobic, rod-shaped bacterium that grows optimally at 28°C with pH levels between 7.0 and 7.5 and in the presence of 2-3% (w/v) NaCl. Phylogenetic analyses based on its 16S rRNA gene sequence placed the strain within the monophyletic cluster of the genus Winogradskyella, exhibiting the highest similarity to Winogradskyella wandonensis KCTC 32579T (96.8%). Genome comparison of strain E313T with W. wandonensis KCTC 32579T and W. thalassocola KCTC 12221T revealed average nucleotide identity (ANI) values of 74.2% and 74.8%, and DNA-DNA hybridization (dDDH) values of 19.0% and 19.5%, respectively, lower than prokaryotic species delineation values. The strain E313T could hydrolyze alginate. A total of 123 carbohydrate-active enzymes were annotated according to the CAZy database. Especially, one oligo-alginate lyase and one poly(β-D-mannuronate) lyase were identified in the genome of strain E313T. Strain E313T possessed MK-6 quinone and iso-C15:0, iso-C15:1 G, iso-C17:0 3-OH, and iso-C15:0 3-OH as main fatty acids. Its major polar lipids were phosphatidylethanolamine (PE), one unidentified aminolipid, and two unknown lipids. Thus, based on phylogenetic, physiological, and chemotaxonomic analyses, we propose a novel species of the genus Winogradskyella, named Winogradskyella immobilis sp. nov., with E313T (= MCCC 1H00506T = KCTC 82731T) as the type strain.

Structure–function analysis of a new PL17 oligoalginate lyase from the marine bacterium Zobellia galactanivorans DsijT

Alginate is a major compound of brown macroalgae and as such an important carbon and energy source for heterotrophic marine bacteria. Despite the rather simple composition of alginate only comprising mannuronate and guluronate units, these bacteria feature complex alginolytic systems that can contain up to seven alginate lyases. This reflects the necessity of large enzyme systems for the complete degradation of the abundant substrate. Numerous alginate lyases have been characterized. They belong to different polysaccharide lyase (PL) families, but only one crystal structure of a family 17 (PL17) alginate lyase has been reported to date, namely Alg17c from the gammaproteobacterium Saccharophagus degradans. Biochemical and structural characterizations are helpful to link sequence profiles to function, evolution of functions and niche-specific characteristics. Here, we combined detailed biochemical and crystallographic analysis of AlyA3, a PL17 alginate lyase from the marine flavobacteria Zobellia galactanivorans DsijT, providing the first structure of a PL17 in the Bacteroidetes phylum. AlyA3 is exo-lytic and highly specific of mannuronate stretches. As part of an “alginate utilizing locus”, its activity is complementary to that of other characterized alginate lyases from the same bacterium. Structural comparison with Alg17c highlights a common mode of action for exo-lytic cleavage of the substrate, strengthening our understanding of the PL17 catalytic mechanism. We show that unlike Alg17c, AlyA3 contains an inserted flexible loop at the entrance to the catalytic groove, likely involved in substrate recognition, processivity and turn over.

Functional Characterization of a Novel Oligoalginate Lyase of Stenotrophomonas maltophilia KJ-2 Using Site-Specific Mutation Reveals Bifunctional Mode of Action, Possessing Both Endolytic and Exolytic Degradation Activity Toward Alginate in Seaweed Biomass

A novel oligoalginate lyase from the marine bacterium, Stenotrophomonas maltophilia KJ-2, completely depolymerizes alginate to monomers with generation of oligomer intermediates. In order to analyze whether KJ-2 oligoalginate lyase has endolytic and exolytic alginate lyase activities, five mutants were developed and characterized using homology modeling based on the crystal structure of Alg17c, an exolytic oligoalginate lyase from Saccharophagus degradans 2-40. The important residues of Tyr238, Arg241, Arg418 and Glu644, which were predicted to be located within hydrogen bonding distance of the non-reducing end of alginate during exolytic catalysis, were mutated to Phe, Ala, Ala and Ala, respectively. Exolytic activities of Arg241Ala, Glu644Ala and Arg241Ala_Glu644Ala mutants decreased compared to the wild type, indicating that Arg241 and Glu644 are key residues for exolytic catalysis. Interestingly, these mutants produced oligomers as the main product due to inherent endolytic degradation activity. These mutational characterization results showed that KJ-2 oligoalginate lyase possesses catalytic domains for both inherent endolytic and exolytic activities.

Biochemical Characterization of a New Oligoalginate Lyase and Its Biotechnological Application in Laminaria japonica Degradation.

Oligoalginate lyases catalyze the degradation of alginate polymers and oligomers into monomers, a prerequisite for biotechnological utilizing alginate. In this study, we report the cloning, expression and biochemical characterization of a new polysaccharide lyase (PL) family 17 oligoalginate lyase, OalV17, from the marine bacterium Vibrio sp. SY01. The recombinant OalV17 showed metal ion independent and detergent resistant properties. Furthermore, OalV17 is an exo-type enzyme that yields alginate monomers as the main product and recognizes alginate disaccharides as the minimal substrate. Site-directed mutagenesis followed by kinetic analysis indicates that the residue Arg231 plays a key role in substrate specificity. Furthermore, a rapid and efficient alginate monomer-producing method was developed directly from Laminaria japonica. These results suggest that OalV17 is a potential candidate for saccharification of alginate.

Synergetic alginate conversion by a microbial consortium of hydrolytic bacteria and methanogens

Sludge, of which alginate-like biomaterial is a major organic component, is an increasing environmental problem. Thus, efficient anaerobic degradation of alginate provides a new method for sludge utilization. In this study, anaerobic alginate hydrolytic bacteria (AHB) were proposed to enrich with methanogens synergetically to reduce the inhibition of intermediate metabolites. The COD of produced methane reached 80.7 ± 1.9% (n = 4) of initial alginate COD. After considering the microbial growth (8%–18% of COD), a good COD balance indicated that alginate was fully consumed and the main final metabolites were methane and CO2. Methanogenesis could promote alginate conversion by AHB. The enriched bacteria for alginate degradation in this study were different from that of former known AHB. The metabolic pathway of alginate degradation was revealed by metagenomics, in which oligo-alginate lyase was detected in twelve bacteria, and typical carbon metabolic pathways to convert alginate to methane were identified. More studies of bacterial isolation and biofuel production are still needed in the future.

Molecular cloning and characterization of AlgL17, a new exo-oligoalginate lyase from Microbulbifer sp. ALW1

A new alginate lyase gene of algl17 was cloned from an alginate-degrading marine bacterium Microbulbifer sp. ALW1. The gene contained 2220 bp and encoded a 739-amino acid protein classified into the PL-17 family. The recombinant alginate lyase AlgL17 was overexpressed and purified from Escherichia coli BL21 (DE3) with a molecular mass of 84.9 kDa. This enzyme showed activities towards sodium alginate, polyM and alginate oligosaccharide, but very low activity towards polyG. These results indicate that AlgL17 is a polyM-specific oligoalginate lyase. When sodium alginate was used as a substrate, the optimum reaction temperature and pH for the enzyme were 35 °C and pH 8.0, respectively. Recombinant AlgL17 was stable at 25 °C, but not stable at 30 °C and 35 °C. It showed good stability over a pH range of 5.0–8.0. The enzyme activity was increased to 1.7 times by adding NaCl to a final concentration of 0.7 M. The ability of the recombinant AlgL17 producing 4-deoxy-L-erythro-5-hexoseulose uronic acid (DEH) from sodium alginate and polyM block indicates that AlgL17 is an exo-type alginate lyase.

Characterization of a new endo-type polysaccharide lyase (PL) family 6 alginate lyase with cold-adapted and metal ions-resisted property

Alginate lyase played an important role in brown algae degradation, and its enzymatic degradation products showed various biological activities. Although many alginate lyases have been characterized, the enzymes with special characterizations are still rather rare. In this study, a new alginate lyase gene, tsaly6A, has been cloned from marine bacterium Thalassomonas sp. LD5, and expressed in Escherichia coli. The deduced alginate lyase, TsAly6A, belonged to the polysaccharide lyase (PL) family 6 and showed the highest amino acid identity (63%) with an exo-type oligoalginate lyase AlyGC. However, this study showed that TsAly6A was an endo-type enzyme yielding alginate trisaccharides (64.5%) as the main products. Compared with other alginate lyases, TsAly6A showed high trisaccharide-yielding levels. Meanwhile, TsAly6A showed the specific activity of 15,960 U/μmol at its optimal pH (pH 8.0) and temperature (35 °C). In addition, TsAly6A was a cold-adapted, salt-activated and metal ions-resisted alginate lyase, which will enable it to perform high activity in the solution containing various ions. Its cold-adaptation, metal ions-tolerance and high trisaccharides yields make TsAly6A an excellent candidate for industrial applications.

Characterization of a new oligoalginate lyase from marine bacterium Vibrio sp.

A new oligoalginate lyase encoding gene, designed oal17A, was cloned from marine bacterium Vibrio sp. W13, and then expressed in Escherichia coli. The recombinant Oal17A was purified by NTA-Ni resin with maximal activity at 30°C and pH7.0. Oal17A exhibited broad substrate specificity, and preferred to degrade alginate than polyM or polyG into monosaccharide acid. The specific activity of Oal17A toward alginate, polyM and polyG was 21.14U/mg, 12.31U/mg and 7.43U/mg, respectively. With features of high-level expression and broad substrate specificity, Oal17A would be a potential tool for alginate monomer production process of alginate utilizing for biofuels and bioethanol production.

Cloning, Expression, and Biochemical Characterization of Two New Oligoalginate Lyases with Synergistic Degradation Capability.

Alginate, the most abundant carbohydrate presents in brown macroalgae, has recently gained increasing attention as an alternative biomass for the production of biofuel. Oligoalginate lyases catalyze the degradation of alginate oligomers into monomers, a prerequisite for bioethanol production. In this study, two new oligoalginate lyase genes, oalC6 and oalC17, were cloned from Cellulophaga sp. SY116, and expressed them in Escherichia coli. The deduced oligoalginate lyases, OalC6 and OalC17, belonged to the polysaccharide lyase (PL) family 6 and 17, respectively. Both showed less than 50% amino acid identity with all of the characterized oligoalginate lyases. Moreover, OalC6 and OalC17 could degrade both alginate polymers and oligomers into monomers in an exolytic mode. Substrate specificity studies demonstrated that OalC6 preferred α-L-guluronate (polyG) blocks, while OalC17 preferred poly β-D-mannuronate (polyM) blocks. The combination of OalC6 and OalC17 showed synergistic degradation ability toward both alginate polymers and oligomers. Finally, an efficient process for the production of alginate monomers was established by combining the new-isolated exotype alginate lyases (i.e., OalC6 and OalC17) and the endotype alginate lyase AlySY08. Overall, our work provides new insights for the development of novel biotechnologies for biofuel production from seaweed.

Characterization of a novel endo-type alginate lyase derived from Shewanella sp. YH1.

Alginate, which is an anionic polysaccharide, is widely distributed in the cell wall of brown algae. Alginate and the products of its degradation (oligosaccharides) are used in stabilizers, thickeners and gelling agents, especially in the food industry. The degradation of alginate generally involves a combination of several alginate lyases (exo-type, endo-type and oligoalginate lyase). Enhancing the efficiency of the production of alginate degradation products may require the identification of novel alginate lyases with unique characteristics. In this study, we isolated an alginate-utilizing bacterium, Shewanella sp. YH1, from seawater collected off the coast of Tottori prefecture, Japan. The detected novel alginate lyase was named AlgSI-PL7, and was classified in polysaccharide lyase family 7. The enzyme was purified from Shewanella sp. YH1 and a recombinant AlgSI-PL7 was produced in Escherichia coli. The optimal temperature and pH for enzyme activity were around 45°C and 8, respectively. Interestingly, we observed that AlgSI-PL7 was not thermotolerant, but could refold to its active form following an almost complete denaturation at approximately 60°C. Moreover, the degradation of alginate by AlgSI-PL7 produced two to five oligosaccharides, implying this enzyme was an endo-type lyase. Our findings suggest that AlgSI-PL7 may be useful as an industrial enzyme.

The role of alginate lyases in the enzymatic saccharification of brown macroalgae, Macrocystis pyrifera and Saccharina latissima

In this work, we have compared the carbohydrate content and the enzymatic saccharification of the brown algae Macrocystis pyrifera from Chile and Saccharina latissima from Norway. M. pyrifera contained 40% mannitol, 31% uronic acids and 15% glucose, while S. latissima contained 37% glucose, 30% uronic acids and 25% mannitol. Thus, the ratio between mannitol and glucose was much higher for M. pyrifera. Acid pre-treated and untreated algae were enzymatically saccharified in two steps; first at pH7.5, 25°C for 12h with a blend of recombinant alginate and oligoalginate lyases, then the pH was changed to 5.2, a commercial cellulase cocktail was added and saccharification continued at 50°C for 4h. These experiments showed that the use of recombinant alginate lyases and oligoalginate lyases in combination with cellulases increased the release of glucose from untreated seaweed. However, for saccharification of pretreated algae, only cellulases were needed to achieve high glucose yields. Finally, it was shown that brown algae hydrolysates could be used as a growth medium to produce microbial ingredients, such as Candida utilis yeast.

Purification and characterization of a novel alginate lyase from the marine bacterium Cobetia sp. NAP1 isolated from brown algae.

The application of marine resources, instead of fossil fuels, for biomass production is important for building a sustainable society. Seaweed is valuable as a source of marine biomass for producing biofuels such as ethanol, and can be used in various fields. Alginate is an anionic polysaccharide that forms the main component of brown algae. Various alginate lyases (e.g. exo- and endo-types and oligoalginate lyase) are generally used to degrade alginate. We herein describe a novel alginate lyase, AlgC-PL7, which belongs to the polysaccharide lyase 7 family. AlgC-PL7 was isolated from the halophilic Gram-negative bacterium Cobetia sp. NAP1 collected from the brown algae Padina arborescens Holmes. The optimal temperature and pH for AlgC-PL7 activity were 45°C and 8, respectively. Additionally, AlgC-PL7 was thermostable and salt-tolerant, exhibited broad substrate specificity, and degraded alginate into monosaccharides. Therefore, AlgC-PL7 is a promising enzyme for the production of biofuels.

Cloning and characterization of two thermo- and salt-tolerant oligoalginate lyases from marine bacterium Halomonas sp.

Two new alginate lyase genes, oalY1 and oalY2, have been cloned from the newly isolated marine bacterium Halomonas sp. QY114 and expressed in Escherichia coli The deduced alginate lyases, OalY1 and OalY2, belonged to polysaccharide lyase (PL) family 17 and showed less than 45% amino acid identity with all of the characterized oligoalginate lyases. OalY1 and OalY2 exhibited the highest activities at 45°C and 50°C, respectively. Both of them showed more than 50% of the highest activity at 60°C, and 20% at 80°C. In addition, they were salt-dependent and salt-tolerant since both of them showed the highest activity in the presence of 0.5 M NaCl and preserved 63% and 68% of activity in the presence of 3 M NaCl. Significantly, OalY1 and OalY2 could degrade both polyM and polyG blocks into alginate monosaccharides in an exo-lytic type, indicating that they are bifunctional alginate lyases. In conclusion, our study indicated that OalY1 and OalY2 are good candidates for alginate saccharification application, and the salt-tolerance may present an exciting new concept for biofuel production from native brown seaweeds.

Comparison of different types of pretreatment and enzymatic saccharification of Macrocystis pyrifera for the production of biofuel

In this work, the brown algae Macrocystis pyrifera were pretreated with dilute sulfuric acid, water and three different types of ionic liquids (ILs): 1-ethyl-3-methylimidazolium acetate ([EMIM][OAc]), 1,5-diazabicyclo[4.3.0]non-5-ene acetate ([DBNH][OAc]) and 1,8-diazabicyclo-[5.4.0]–undec-7-ene–sulfurdioxide–monoethanolamine (DBU–MEA–SO2–SIL), to disassemble the complex polysaccharide structure. After each pretreatment procedure, enzymatic saccharification was performed to release the monosaccharides. The main building blocks of M. pyrifera were processed by derivatization via acid methanolysis and subjected to gas chromatographic analysis. It was found that the main constituents were alginate (60.6wt.%) and cellulose (22.6wt.%) of total carbohydrate content. The degradation of alginate requires the action of alginate lyase and oligoalginate lyase, which hydrolyze the main chain in a synergistic mechanism releasing uronic acid (unsaturated uronate). Upon saccharification of cellulose, cellulases and β-glucosidase were used allowing the release of glucose. It was found that the best pretreatment strategy for M. pyrifera consisted of a pretreatment with 2vol.% sulfuric acid, followed by saccharification of cellulose with a mixture of cellulases at pH5.2 for 4h at 50°C or by saccharification of alginate with the enzyme lyase/oligoalginate lyase at pH7.5 for 2h at 37°C. The process resulted in a release of 68.4wt.% of glucose (55.74±0.05mg glucose/g algae) whereas in the case of alginate 85.8wt.% of uronic acid (193.7±10.6mg uronic acid/g algae) was released. To the best of our knowledge this is the first time that saccharification of both cellulose and alginate from brown algae is reported.

Site-Directed Mutagenesis-Based Functional Analysis and Characterization of Endolytic Lyase Activity of N- and C-Terminal Domains of a Novel Oligoalginate Lyase from Sphingomonas sp. MJ-3 Possessing Exolytic Lyase Activity in the Intact Enzyme.

A novel oligoalginate lyase from a marine bacterium, Sphingomonas sp. strain MJ-3, exhibited a unique alginate degradation activity that completely depolymerizes alginate to monomers through the formation of oligomers. In order to reveal the reason why MJ-3 oligoalginate can exhibit both endolytic and exolytic alginate lyase activities, ten mutants were developed and characterized on the basis of homology modeling. When the recombinant cell lysates containing the mutated proteins of MJ-3 oligoalginate lyase were allowed to react with alginate, the Asn177Ala, His178Ala, Tyr234Phe, His389Ala, and Tyr426Phe mutants showed reduced oligoalginate lyase activity, whereas the Arg236Ala mutant exhibited endolytic activity. Interestingly, the overexpressed Arg236Ala protein (79.6 kDa) was proteolytically cleaved into two fragments, i.e., the N-terminal 32.0-kDa and the C-terminal 47.6-kDa fragments. Both the purified N-terminal and C-terminal fragments showed endolytic lyase activity. They preferentially degraded a heteropolymeric (polyMG) block than poly-β-D-mannuronate (polyM) or poly-α-L-guluronate (polyG) blocks. These results suggest that the oligoalginate lyase activity of MJ-3 enzyme is derived from the cooperative interaction between the N- and C-terminal endolytic alginate lyase domains in the intact enzyme.

Cloning and characterization of the first polysaccharide lyase family 6 oligoalginate lyase from marine Shewanella sp. Kz7.

Alginate, the most abundant carbohydrate in brown macroalgae, is widely used in the food and pharmaceutical industries. Recently, alginate has attracted increasing attention, as it may serve as an alternative biomass for the production of biofuel. The degradation of alginate into monomeric units is the prerequisite for bioethanol production. All known oligoalginate lyases belong to the polysaccharide lyase (PL) family 7, 14, 15 and 17, and most of them preferred to degrade the polyM blocks to yield 4-deoxy-l-erythro-5-hexoseulose uronic acid as the primary product. In this study, we cloned an oligoalginate lyase gene, oalS6, from Shewanella sp. Kz7 and expressed it in Escherichia coli. The PL family 6 oligoalginate lyase (OalS6) has no significant sequence similarity with other known oligoalginate lyases. OalS6 contains a chondroitinase-like domain and was assigned to the PL family 6. This lyase is an exo-type oligoalginate lyase and prefer to depolymerize polyG block into 2, 4, 5, 6-tetrahydroxytetrahydro-2H-pyran-2-carboxylic acid. All of these results indicate that OalS6 is a novel oligoalginate lyase that is structurally and functionally different from other known oligoalginate lyases. This finding provides new insights into the development of biofuel processing biotechnologies from seaweed.

알긴산을 분해하는 해양미생물인 Sphingomonas sp. MJ-3 균주의 올리고알긴산 분해효소의 상동성 모델링 및 특성연구

Alginates are found in marine brown seaweeds and in extracellular biofilms secreted by some bacteria. Previously, we reported an oligoalginate lyase from Sphingomonas sp. MJ-3 (MJ3-Oal) that had an exolytic activity and protein sequence homology with endolytic polymannuronate (polyM) lyase in the N-terminal region. In this study, the MJ3-Oal was tested for both exolytic and endolytic activity by homology modeling using the crystal structure of Alg17c from Saccharophagus degradans 2-40T. The tyrosine residue at the 426th position, which possibly formed a hydrogen bond with the substrate, was mutated to phenylalanine. The FPLC profiles showed that MJ3-Oal degraded alginate quickly to monomers as a final product through the oligmers, whereas the Tyr426Phe mutant showed only exolytic alginate lyase activity. 1H-NMR spectra also showed that MJ3-Oal degraded the endoglycosidic bond of polyM and polyMG (polymannuronate-guluronate) blocks. These results indicate that oligoalginate lyase from Sphingomonas sp. MJ-3 probably catalyzes the degradation of both exo- and endo-glycosidic bonds of alginate.

Molecular characterization of a novel oligoalginate lyase consisting of AlgL- and heparinase II/III-like domains from Stenotrophomonas maltophilia KJ-2 and its application to alginate saccharification

Molecular identification and development of a novel recombinant alginate lyase as the biocatalyst for alginate saccharification are prerequisite for bioethanol fermentation from brown seaweed biomass. We identified and characterized a novel oligoalginate lyase for complete degradation of alginate from Stenotrophomonas maltophilia KJ-2 that grow on alginate as the sole carbon source. KJ-2 oligoalginate lyase consisted of AlgL- and heparinase II/III-like domains. The recombinant KJ-2 oligoalginate lyase exhibited substrate preference toward polymannuronate and alginate as well as oligoalginate. The recombinant KJ-2 oligoalginate lyase completely degraded alginate into unsaturated uronate monomer most efficiently at pH 7.5 and 37 °C. Interestingly, AlgL-like recombinant proteins showed more like endolytic activity. The recombinant KJ-2 oligoalginate lyase was a novel oligoalginate lyase consisting of AlgL- and heparinase-like domains and could be used as a candidate for biocatalyst selection to saccharify alginate for bioethanol production from brown seaweed.

Cloning, overexpression and characterization of a new oligoalginate lyase from a marine bacterium, Shewanella sp.

Is to report an oligoalginate lyase with high enzymatic activity and high-level expression. Using site-finding PCR and degenerate PCR, a gene (designated oalS17) encoding a new oligoalginate lyase was cloned from Shewanella sp. Kz7 and expressed in Escherichia coli. The gene consisted of 2,292bp with deduced amino acid size of 763 including a putative signal peptide of 44 amino acid residues belonging to polysaccharide lyase (PL) family 17. The recombinant protein was most active at 50°C and pH 6.2 in 50mM phosphate buffer. It degraded alginate more efficiently than polyM and polyG block into a monomeric sugar acid, with a specific activity of 32Umg(-1) toward alginate, 24Umg(-1) toward polyM and 5Umg(-1) toward polyG. With the high-level expression and high enzymatic activity, the recombinant oligoalginate lyase OalS17 could be a potential enzyme for further research on alginate saccharification and biofuels production.

Comparative biochemical characterization of three exolytic oligoalginate lyases from Vibrio splendidus reveals complementary substrate scope, temperature, and pH adaptations.

Marine microbes use alginate lyases to degrade and catabolize alginate, a major cell wall matrix polysaccharide of brown seaweeds. Microbes frequently contain multiple, apparently redundant alginate lyases, raising the question of whether these enzymes have complementary functions. We report here on the molecular cloning and functional characterization of three exo-type oligoalginate lyases (OalA, OalB, and OalC) from Vibrio splendidus 12B01 (12B01), a marine bacterioplankton species. OalA was most active at 16°C, had a pH optimum of 6.5, and displayed activities toward poly-β-d-mannuronate [poly(M)] and poly-α-l-guluronate [poly(G)], indicating that it is a bifunctional enzyme. OalB and OalC were most active at 30 and 35°C, had pH optima of 7.0 and 7.5, and degraded poly(M·G) and poly(M), respectively. Detailed kinetic analyses of oligoalginate lyases with poly(G), poly(M), and poly(M·G) and sodium alginate as substrates demonstrated that OalA and OalC preferred poly(M), whereas OalB preferred poly(M·G). The catalytic efficiency (kcat/Km) of OalA against poly(M) increased with decreasing size of the substrate. OalA showed kcat/Km from 2,130 mg(-1) ml s(-1) for the trisaccharide to 224 mg(-1) ml s(-1) for larger oligomers of ∼50 residues, and 50.5 mg(-1) ml s(-1) for high-molecular-weight alginate. Although OalA was most active on the trisaccharide, OalB and OalC preferred dimers. Taken together, our results indicate that these three Oals have complementary substrate scopes and temperature and pH adaptations.