Uronic acid sequence in alginate from different sources

Alginate may be considered as a block co-polymer of D-mannuronic and L-guluronic acids, and consists of three types of blocks: homopolymeric blocks of mannuronic acid (MM) and of guluronic acid (GG), and blocks with an alternating sequence (MG). The block composition of alginates has been characterized by a simple chemical method involving partial hydrolysis with acid, followed by fractional precipitation of the acid-resistant part of the alginate. Alginates from eleven different species of brown algae have been examined and, for five species, alginates from different tissues have been compared. The results indicate that young tissue is rich in MM blocks, and that the difference between the alginates from different species is mainly due to the alginates from the older parts of the plants. Extracellular alginates from two types of bacteria have been examined.     

Characterization of the alginates from algae harvested at the Egyptian Red Sea coast

The alginates from five species of brown algae from the Egyptian Red Sea coast, namely: Cystoseira trinode, Cystoseira myrica, Sargassum dentifolium, Sargassum asperifolium, and Sargassum latifolium, were isolated and their compositions and structures studied by 1H NMR spectroscopy. All the alginates studied contain more guluronic acid (G) than mannuronic acid (M) and have a homopolymeric block-type structure (eta<1). The intrinsic viscosity of the alginate samples range from 8.6 to 15.2 and the gel strength ranges from 10.97 to 15.51. The constitutional G- and M-blocks of alginates from two different species (C. trinode and S. latifolium) were separated after partial acid hydrolysis. The 1H NMR spectral data of the blocks GG and MM obtained by chemical fractionation were compared with those of polymeric alginates. The monomeric uronic acids were separated by complete acid hydrolysis of S. asperifolium alginate and the G and M monomers were characterized by 1H, 13C NMR spectroscopy as well as by paper electrophoresis.     

Seasonal studies on the alginate and its biochemical composition I: Sargassum polycystum (Fucales), Phaeophyceae

Investigations were made on the brown seaweed Sargassum polycystum C. Agardh collected from Rameswaram Coast, Tamil Nadu. The alginates extracted from ‘leaf’, ‘stem’ and entire thallus of S. polycystum were investigated for their viscosity and chemical constituents, namely β‐D‐mannuronic acid (M‐block), α‐L‐guluronic acid (G‐block) and alternating sequences of β‐D‐mannuronic acid and α‐L‐guluronic acid (MG‐block) for six different seasons between August 1998 and November 1999. Significant seasonal variation (P< 0.05) was observed with high yield of alginate in February. The alginate extracted from the ‘leaf’ region showed a maximum yield whereas the ‘stem’ region exhibited maximum viscosity. The amount of G‐block was found to be more than M‐ and MG‐blocks in all the samples tested. The amount of G‐block was high in ‘stem’ followed by leaf and entire thallus. A positive correlation was recorded between viscosity and G‐block. Among the three alginates, the ratio of M/G was low in the ‘stem’ followed by ‘leaf’ and entire thallus.     

Bacterial alginate lyase inactive on alginate biosynthesized by Pseudomonas aeruginosa

A bacterium (strain Al) isolated from a ditch produces three kinds of intracellular alginate lyases [Al-I (molecular weight: M.W. 60,000), Al-II-1 (M.W. 60,000) and Al-II-2]; the former two lyases have been purified and characterized (Yonemoto et al., J. Ferment. Bioeng., 72, 152–157, 1991). As part of a series of studies, Al-II-2 lyase was purified from cell-free extract of the bacterium. The lyase, with a M.W. of 25,000, depolymerized sodium-, potassium- and propyleneglycol alginates most efficiently at pH 8.0, 70°C, but it was inactive toward bacterial alginates with O-acetyl groups.     

Catalytic properties and specificity of a recombinant, overexpressed D-mannuronate lyase

Lysis of alginates and of their saturated and unsaturated fragments was monitored by 1H NMR spectroscopy. AlxM(B) alginate lyase performs beta-elimination on the mannuronic acid (M) residues. It does not cleave the guluronic acid (G) sequences, nor the M-G or the G-M diads. In consequence, it is a true mannuronate lyase. The end product of the reaction is O-(4-deoxy-alpha-L-ery-thro-hex-4-enopyranosyl-uronic acid)-(1->(4)-O-(beta-D-mannopyranosyluronic acid)-(1->4)-O-beta-D-mannpyranuronic acid. Viscosity measurements made during degradation of a polymannuronate alginate showed that AlxM(B) behaves as an endo-enzyme. HPLC analysis of the degradation products of oligomannuronates and oligoalginates suggested that the beta-elimination requires the interaction of the enzyme with at least three sequential mannuronic acid residues. The catalytic site may possess 5 sub-sites and accommodate pentamers with different M/G ratio. Kinetic measurements showed that the specificity constant Vm/Km increased with the number of mannuronic acid residues. AlxM(B) may be reversibly inhibited by heteropolymeric blocks in a competitive manner.     

New hypothesis on the role of alternating sequences in calcium-alginate gels

The availability of mannuronan and mannuronan C-5 epimerases allows the production of a strictly alternating mannuronate-guluronate (MG) polymer and the MG-enrichment of natural alginates, providing a powerful tool for the analysis of the role of such sequences in the calcium-alginate gel network. In view of the calcium binding properties of long alternating sequences revealed by circular dichroism studies which leads eventually to the formation of stable hydrogels, their direct involvement in the gel network is here suggested. In particular, 1H NMR results obtained from a mixed alginate sample containing three polymeric species, G blocks, M blocks, and MG blocks, without chemical linkages between the block structures, indicate for the first time the formation of mixed junctions between G and MG blocks. This is supported by the analysis of the Young's modulus of hydrogels from natural and epimerized samples obtained at low calcium concentrations. Furthermore, the "zipping" of long alternating sequences in secondary MG/MG junctions is suggested to account for the shrinking (syneresis) of alginate gels in view of its dependence on the length of the MG blocks. As a consequence, a partial network collapse, macroscopically revealed by a decrease in the Young's modulus, occurred as the calcium concentration in the gel was increased. The effect of such "secondary" junctions on the viscoelastic properties of alginate gels was evaluated measuring their creep compliance under uniaxial compression. The experimental curves, fitted by a model composed of a Maxwell and a Voigt element in series, revealed an increase in the frictional forces between network chains with increasing length of the alternating sequences. This suggests the presence of an ion mediated mechanism preventing the shear of the gel.     

Bacterial alginate lyase highly active on acetylated alginates

A bacterium (strain A1) isolated from a ditch synthesized three kinds of intracellular alginate lyases: A1-I (molecular weight [M.W.] 60,000), A1-II-1 (M.W. 60,000) and A1-II-2 (M.W. 25,000) in laboratory-scale cultures. However, when cells of strain A1 were grown on an industrial scale, another lyase (A1-III) was produced other than A1-I, A1-II-1 and A1-II-2. The A1-III lyase was a monomer with a M.W. of about 38,000, and its activity toward bacterial (acetylated) alginates was much higher (2-fold) than that toward seaweed (non-acetylated) alginates. The N-terminal amino acid sequence of A1-III lyase was consistent with that of A1-I lyase.     

Direct quantification of M/G ratio from C CP-MAS NMR spectra of alginate powders by multivariate curve resolution

Multivariate curve resolution (MCR) was applied to ¹³C cross-polarisation (CP) magic angle spinning (MAS) nuclear magnetic resonance (NMR) spectra of non-depolymerised alginate powders obtained from brown seaweed plus a pure mannuronate sample isolated from Pseudomonas fluorescens for estimation of the mannuronic acid/guluronic acid ratio (M/G ratio). An excellent MCR model with a correlation coefficient of r² = 0.99 was established between the estimated M/G ratios and the M/G ratios obtained from the traditional ¹H solution state NMR method. The new method allows for successful determination of the M/G ratio independent of the calcium content (at least up to 2.4%, which was the upper limit in this study) with a root mean square error of prediction of 0.05. It is thus concluded that ¹³C CP-MAS NMR in combination with multivariate curve resolution is a reliable, convenient (no sample preparation is required) and relatively rapid method for M/G ratio determinations of alginates and it may serve as a good alternative to the chemical techniques traditionally used.     

The Pseudomonas syringae genome encodes a combined mannuronan C-5-epimerase and O-acetylhydrolase, which strongly enhances the predicted gel-forming properties of alginates

Alginates are industrially important, linear copolymers of beta-d-mannuronic acid (M) and its C-5-epimer alpha-l-guluronic acid (G). The G residues originate from a postpolymerization reaction catalyzed by mannuronan C-5-epimerases (MEs), leading to extensive variability in M/G ratios and distribution patterns. Alginates containing long continuous stretches of G residues (G blocks) can form strong gels, a polymer type not found in alginate-producing bacteria belonging to the genus Pseudomonas. Here we show that the Pseudomonas syringae genome encodes a Ca(2+)-dependent ME (PsmE) that efficiently forms such G blocks in vitro. The deduced PsmE protein consists of 1610 amino acids and is a modular enzyme related to the previously characterized family of Azotobacter vinelandii ME (AlgE1-7). A- and R-like modules with sequence similarity to those in the AlgE enzymes are found in PsmE, and the A module of PsmE (PsmEA) was found to be sufficient for epimerization. Interestingly, an R module from AlgE4 stimulated Ps-mEA activity. PsmE contains two regions designated M and RTX, both presumably involved in the binding of Ca(2+). Bacterial alginates are partly acetylated, and such modified residues cannot be epimerized. Based on a detailed computer-assisted analysis and experimental studies another PsmE region, designated N, was found to encode an acetylhydrolase. By the combined action of N and A PsmE was capable of redesigning an extensively acetylated alginate low in G from a non gel-forming to a gel-forming state. Such a property has to our knowledge not been previously reported for an enzyme acting on a polysaccharide.     

Extraction and physicochemical characterization of Sargassum vulgare alginate from Brazil

Alginate fractions from Sargassum vulgare brown seaweed were characterized by (1)H NMR and fluorescence spectroscopy and by rheological measurements. The alginate extraction conditions were investigated. In order to carry out the structural and physicochemical characterization, samples extracted for 1 and 5h at 60 degrees C were further purified by re-precipitation with ethanol and denoted as SVLV (S. vulgare low viscosity) and SVHV (S. vulgare high viscosity), respectively. The M/G ratio values for SVLV and SVHV were 1.56 and 1.27, respectively, higher than the ratio for most Sargassum spp. alginates (0.19-0.82). The homopolymeric blocks F(GG) and F(MM) of these fractions characterized by (1)H NMR spectroscopy were 0.43 and 0.55 for SVHV and 0.36 and 0.58 for SVLV samples, respectively, these values typically being within 0.28-0.77 and 0.07-0.41, respectively. Therefore, the alginate samples from S. vulgare are much richer in mannuronic block structures than those from other Sargassum species. Values of M(w) for alginate samples were also calculated using intrinsic viscosity data. The M(w) value for SVLV (1.94 x 10(5)g/mol) was lower than that for SVHV (3.3 x 10(5)g/mol). Newtonian behavior was observed for a solution concentration as high as 0.7% for SVLV, while for SVHV the solutions behaved as a Newtonian fluid up to 0.5%. The optimal conditions for obtaining the alginates from S. vulgare were 60 degrees C and 5h extraction. Under these conditions, a more viscous alginate in higher yield was extracted from the seaweed biomass.     

Changes in M:G ratios of extracted and residual alginate fractions on boiling with water the dried brown alga Kjellmaniella crassifolia (Laminariales,Phaeophyta)

Kjellmaniella crassifolia, the edible macro-brown alga in Japan contained nearly 27% of alginates of which nearly 7% was extractable from the fronds with boiling water for 6 h and the residual alginates in the frond were almost exhaustively extracted with a dilute alkali at 60 °C for 6 h. The alginates dissolved in all these extracts with both boiling water and dilute alkali were purified by fractionation with MgCl₂ and alcohol.The content of MM blocks in the boiling water-soluble alginate sample increased remarkably during heating for 6 h while that of GG blocks from the same sample decreased. In contrast, MM blocks in the alkali-soluble alginate sample decreased during 6 h heating while GG blocks continued to increase. Since the amounts of MG blocks showed slight fluctation, the M:G ratio of alginates extracted with boiling water increased towards the end of extraction whereas the reverse is true for the alkali-soluble alginates.     

Mode of action and subsite studies of the guluronan block-forming mannuronan C-5 epimerases AlgE1 and AlgE6

AlgE1, AlgE5 and AlgE6 are members of a family of mannuronan C-5 epimerases encoded by the bacterium Azotobacter vinelandii, and are active in the biosynthesis of alginate, where they catalyse the post-polymerization conversion of beta-D-mannuronic acid (M) residues into alpha-L-guluronic acid residues (G). All enzymes show preference for introducing G-residues neighbouring a pre-existing G. They also have the capacity to convert single M residues flanked by G, thus 'condensing' G-blocks to form almost homopolymeric guluronan. Analysis of the length and distribution of G-blocks based on specific enzyme degradation combined with size-exclusion chromatography, electrospray ionization MS, HPAEC-PAD (high-performance anion-exchange chromatography and pulsed amperometric detection), MALDI (matrix-assisted laser-desorption ionization)-MS and NMR revealed large differences in block length and distribution generated by AlgE1 and AlgE6, probably reflecting their different degree of processivity. When acting on polyMG as substrates, AlgE1 initially forms only long homopolymeric G-blocks >50, while AlgE6 gives shorter blocks with a broader block size distribution. Analyses of the AlgE1 and AlgE6 subsite specificities by the same methodology showed that a mannuronan octamer and heptamer respectively were the minimum substrate chain lengths needed to accommodate enzyme activities. The fourth M residue from the non-reducing end is epimerized first by both enzymes. When acting on MG-oligomers, AlgE1 needed a decamer while AlgE6 an octamer to accommodate activity. By performing FIA (flow injection analysis)-MS on the lyase digests of epimerized and standard MG-oligomers, the M residue in position 5 from the non-reducing end was preferentially attacked by both enzymes, creating an MGMGGG-sequence (underlined and boldface indicate the epimerized residue).     

FT-IR spectra of alginic acid block fractions in three species of brown seaweeds

Sodium alginates obtained by alkaline extraction of Lessonia flavicans, Desmarestia ligulata and Desmarestia distans (Phaeophyta) from southern Chile were partially hydrolyzed with HCl. Each alginate gave three fractions that were characterized using FT-IR spectroscopy. The fractions soluble in 0.3M HCl presented in the fingerprint region four vibrations at around 960, 911, 890 and 815 cm(-1) that were assigned to heteropolymeric blocks. The fractions soluble at pH 2.85 showed bands at around 948, 888 and 820 cm(-1) attributed to homopolymannuronic acid blocks, the first band is resolved in the second-derivative spectra into two bands at 951 and 936 cm(-1). The fractions insoluble at pH 2.85 presented four bands at around 947, 903, 812 and 781 cm(-1), which were assigned to homopolyguluronic acid blocks. For some samples, the second derivative FT-IR spectra showed new bands indicating the presence of other structures, in low proportions. Structures deduced by FT-IR spectroscopy were corroborated by solution (1)H and (13)C NMR spectroscopy. Two-dimensional spectra were collected to confirm the fine structure of the hetero- and homopolymeric fractions. A geometrically optimized model for the disaccharide alpha-l-gulopyranuronosyl-(1-->4)-alpha-l-gulopyranuronic acid was calculated using density functional theory; good agreement was obtained between its corresponding calculated vibrations and the experimental bands assigned to homopolyguluronic acid blocks.     

Effect of molecular weight on the antioxidant property of low molecular weight alginate from Laminaria japonica

In this study, three alginate fractions with different molecular weights and ratios of mannuronic acid (M) to guluronic acid (G) were prepared by enzymatic hydrolysis and ultrafiltration to assess the antioxidant property of alginates from Laminaria japonica with molecular weight below 10 kDa. The antioxidant properties of different molecular weight alginates were evaluated by determining the scavenging abilities on superoxide, hydroxyl, and hypochlorous acid and inhibitory effect on Fe²⁺-induced lipid peroxidation in yolk homogenate. The results showed that low molecular weight alginates exhibited high scavenging capacities on superoxide, hydroxyl, and hypochlorous acid radicals and good inhibition of Fe²⁺-induced lipid peroxidation in yolk. By comparison, alginate A1 with molecular weight below 1 kDa and M/G of 1.84 had better scavenging activity on superoxide, hydroxyl, and hypochlorous acid radicals in vitro than A2 (1–6 kDa), A3 (6–10 kDa), ascorbic acid, and carnosine. With similar M/G ratio, A2 exhibited better antioxidant activity on superoxide and hypochlorous acid radicals than A3. However, fraction A3 with molecular weight of 6–10 kDa exhibited higher inhibitory ability on lipid peroxidation in yolk in vitro than A1 and A2. The results indicated that molecular weight played a more important role than M/G ratio on alginate to determine the antioxidant ability. By comparison, low molecular weight alginates composed of guluronic acid and mannuronic acid exhibited better antioxidant ability on oxygen free radicals than sulfated polysaccharides from L. japonica in our previous study and represent a good source of marine polysaccharide with potential application as natural antioxidant.     

Influence of oligoguluronates on alginate gelation, kinetics, and polymer organization

Structural polysaccharides of the alginate family form gels in aqueous Ca2+-containing solutions by lateral association of chain segments. The effect of adding oligomers of alpha-l-guluronic acid (G blocks) to gelling solutions of alginate was investigated using rheology and atomic force microscopy (AFM). Ca-alginate gels were prepared by in situ release of Ca2+. The gel strength increased with increasing level of calcium saturation of the alginate and decreased with increasing amount of free G blocks. The presence of free G blocks also led to an increased gelation time. The gel point and fractal dimensionalities of the gels were determined based on the rheological characterization. Without added free G blocks the fractal dimension of the gels increased from df = 2.14 to df = 2.46 when increasing [Ca2+] from 10 to 20 mM. This increase was suggested to arise from an increased junction zone multiplicity induced by the increased concentration of calcium ions. In the presence of free G blocks (G block/alginate = 1/1) the fractal dimension increased from 2.14 to 2.29 at 10 mM Ca2+, whereas there was no significant change associated with addition of G blocks at 20 mM Ca2+. These observations indicate that free G blocks are involved in calcium-mediated bonds formed between guluronic acid sequences within the polymeric alginates. Thus, the added oligoguluronate competes with the alginate chains for the calcium ions. The gels and pregel situations close to the gel point were also studied using AFM. The AFM topographs indicated that in situations of low calcium saturation microgels a few hundred nanometers in diameter develop in solution. In situations of higher calcium saturation lateral association of a number of alginate chains are occurring, giving ordered fiber-like structures. These results show that G blocks can be used as modulators of gelation kinetics as well as local network structure formation and equilibrium properties in alginate gels.     

New Family of Ulvan Lyases Identified in Three Isolates from the Alteromonadales Order

Ulvan is the main polysaccharide component of the Ulvales (green seaweed) cell wall. It is composed of disaccharide building blocks comprising 3-sulfated rhamnose linked to d-glucuronic acid (GlcUA), l-iduronic acid (IdoUA), or d-xylose (Xyl). The degradation of ulvan requires ulvan lyase, which catalyzes the endolytic cleavage of the glycoside bond between 3-sulfated rhamnose and uronic acid according to a β-elimination mechanism. The first characterized ulvan lyase was identified in Nonlabens ulvanivorans, an ulvanolytic bacterial isolate. In the current study, we have identified and biochemically characterized novel ulvan lyases from three Alteromonadales isolated bacteria. Two homologous ulvan lyases (long and short) were found in each of the bacterial genomes. The protein sequences have no homology to the previously reported ulvan lyases and therefore are the first representatives of a new family of polysaccharide lyases. The enzymes were heterologously expressed in Escherichia coli to determine their mode of action. The heterologous expressed enzymes were secreted into the milieu subsequent to their signal sequence cleavage. An endolytic mode of action was observed and studied using gel permeation chromatography and ¹H NMR. In contrast to N. ulvanivorans ulvan lyase, cleavage occurred specifically at the GlcUA residues. In light of the genomic context and modular structure of the ulvan lyase families identified to date, we propose that two ulvan degradation pathways evolved independently.     

Cloning, sequence analysis and expression of gene alyVI encoding alginate lyase from marine bacterium Vibrio sp. QY101.

The gene (alyVI) encoding an alginate lyase of marine bacterium Vibrio sp. QY101, which was isolated from a decaying thallus of Laminaria, was cloned using a strategy of combined degenerate PCR and long range-inverse PCR (LR-IPCR), then sequenced and expressed in Escherichia coli. Gene alyVI was composed of a 1014 bp open reading frame (ORF) encoding 338 amino acid residues. The calculated molecular mass of alyVI product is 38.4 kDa, but a signal peptide is cleaved off, leaving a mature protein of 34 kDa. AlyVI was purified from culture supernatants to electrophoretic homogeneity using affinity chromatography. AlyVI was most active at pH 7.5 and 40 degrees C in the presence of 1 mM ZnCl2. A nine-amino-acid consensus region (YXRESLREM), which was only found in polyguluronate lyases, was also observed in the amino-terminal region of AlyVI. However, AlyVI could degrade both M block and G block. These results indicate that a novel alginate lyase-encoding gene has been cloned.     

Mannuronan C-5-epimerases and their application for in vitro and in vivo design of new alginates useful in biotechnology

The industrially important polysaccharide alginate is a linear copolymer of beta-D-mannuronic acid (M) and alpha-L-guluronic acid (G). It is produced commercially by extraction from brown seaweeds, although some of the bacteria belonging to the genera Azotobacter and Pseudomonas also synthesize alginates. Alginates are synthesized as mannuronan, and varying amounts of the M residues in the polymer are then epimerized to G residues by mannuronan C-5-epimerases. The gel-forming, water-binding, and immunogenic properties of the polymer are dependent on the relative amount and sequence distribution of M and G residues. A family of seven calcium-dependent, secreted epimerases (AlgE1-7) from Azotobacter vinelandii have now been characterized, and in this paper the properties of all these enzymes are described. AlgE4 introduces alternating M and G residues into its substrate, while the remaining six enzymes introduce a mixture of continuous stretches of G residues and alternating sequences. Two of the enzymes, AlgE1 and AlgE3, are composed of two catalytically active domains, each introducing different G residue sequence patterns in alginate. These results indicate that the enzymes can be used for production of alginates with specialized properties.     

Biochemical Properties and Substrate Specificities of a Recombinantly Produced Azotobacter vinelandii Alginate Lyase

Alginate is a polysaccharide composed of β-d-mannuronic acid (M) and α-l-guluronic acid (G). An Azotobacter vinelandii alginate lyase gene, algL, was cloned, sequenced, and expressed in Escherichia coli. The deduced molecular mass of the corresponding protein is 41.4 kDa, but a signal peptide is cleaved off, leaving a mature protein of 39 kDa. Sixty-three percent of the amino acids in this mature protein are identical to those in AlgL from Pseudomonas aeruginosa. AlgL was partially purified, and the activity was found to be optimal at a pH of 8.1 to 8.4 and at 0.35 M NaCl. Divalent cations are not necessary for activity. The pI of the enzyme is 5.1. When an alginate rich in mannuronic acid was used as the substrate, the K_m was found to be 4.6 × 10⁻⁴ M (sugar residues). AlgL was found to cleave M-M and M-G bonds but not G-M or G-G bonds. Bonds involving acetylated residues were also cleaved, but this activity may be sensitive to the extent of acetylation.

Alginate is a family of 1-4-linked copolymers of β-d-mannuronic acid (M) and α-l-guluronic acid (G). It is produced by brown algae and by some bacteria belonging to the genera Azotobacter and Pseudomonas (8, 17, 18, 31). The polymer is widely used in industry and biotechnology (36, 44), and the genetics of its biosynthesis in Pseudomonas aeruginosa has been extensively studied due to its role in the disease cystic fibrosis (33). In bacterial alginates, some of the M residues may be O-2- and/or O-3-acetylated (42). The polymer is initially synthesized as mannuronan, and the G residues are introduced at the polymer level by mannuronan C-5-epimerases (13, 22, 23). The epimerized alginates contain a mixture of blocks of consecutive G residues (G blocks), consecutive M residues (M blocks), and alternating M and G residues (MG blocks). Alginates from Pseudomonas sp. do not contain G blocks (42).Alginate lyases catalyze the depolymerization of alginates by β-elimination, generating a molecule containing 4-deoxy-l-erythro-hex-4-enepyranosyluronate at the nonreducing end. Such lyases have been found in organisms using alginate as a carbon source, in bacteriophages specific for alginate-producing organisms, and in alginate-producing bacteria (45). An alginate molecule may contain four different glycosidic bonds, M-M, G-M, M-G, or G-G, and the relative rates at which each of these bonds are cleaved vary among different lyases (36a). The lyases also differ in the extent to which they are affected by acetylation (35, 43, 46).Davidson et al. (10) described an Azotobacter vinelandii lyase which preferred M blocks as a substrate. Kennedy et al. (28) later reported the purification of periplasmic alginate lyases from A. vinelandii and from Azotobacter chroococcum which also seemed to prefer deacetylated, M-rich alginate. The activities of these enzymes were found to be optimal at pH 6.8 and 7.2, respectively, while the enzyme reported by Davidson et al. (10) was found to display optimal activity at pH 7.8.A gene, algL, encoding an alginate lyase has been cloned from P. aeruginosa (2, 41). The gene was found to be located in a cluster containing most of the genes necessary for the biosynthesis of alginate. A homologous gene cluster has recently been identified in A. vinelandii (38) and shown to encode an alginate lyase (32). In our previous report, we showed that plasmid pHE102, which contains a part of this gene cluster, contains a DNA sequence sharing homology with algL from P. aeruginosa (38). We have now subcloned, sequenced, and expressed this gene in Escherichia coli. The lyase was shown to preferentially cleave deacetylated M-M and M-G bonds, but acetylated substrates were also cleaved.     

Cloning and Expression of Three New Azotobacter vinelandii Genes Closely Related to a Previously Described Gene Family Encoding Mannuronan C-5-Epimerases

The cloning and expression of a family of five modular-type mannuronan C-5-epimerase genes from Azotobacter vinelandii (algE1 to -5) has previously been reported. The corresponding proteins catalyze the Ca²⁺-dependent polymer-level epimerization of β-d-mannuronic acid to α-l-guluronic acid (G) in the commercially important polysaccharide alginate. Here we report the identification of three additional structurally similar genes, designated algE6, algE7, and algY. All three genes were sequenced and expressed in Escherichia coli. AlgE6 introduced contiguous stretches of G residues into its substrate (G blocks), while AlgE7 acted as both an epimerase and a lyase. The epimerase activity of AlgE7 leads to formation of alginates with both single G residues and G blocks. AlgY did not display epimerase activity, but a hybrid gene in which the 5′-terminal part was exchanged with the corresponding region in algE4 expressed an active epimerase. Southern blot analysis of genomic A. vinelandii DNA, using the 5′ part of algE2 as a probe, indicated that all hybridization signals originated from algE1 to -5 or the three new genes reported here.Alginate is a linear copolymer composed of β-d-mannuronic acid (M) and its C-5 epimer, α-l-guluronic acid (G). The M and G residues are organized in blocks of consecutive M residues (M blocks), consecutive G residues (G blocks), or alternating M and G (MG blocks), and the lengths and distributions of the different block types vary among alginates isolated from brown algae or from different bacteria belonging to the genera Azotobacter and Pseudomonas (36, 37). Alginates are the most abundant polysaccharides in brown algae (comprising up to 40% of the dry matter), and their functions are to supply strength and flexibility to the algal tissues (38). The bacterium Azotobacter vinelandii produces alginate both as a vegetative state capsule and as an integrated part of a particular resting stage form (cyst) of this organism (31). The opportunistic pathogen Pseudomonas aeruginosa produces alginate as a capsule-like exopolysaccharide during infection of the lungs of cystic fibrosis patients (12, 23). Alginates from brown algae and A. vinelandii have M, G, and MG blocks (29, 36, 37), while alginates from P. aeruginosa and other Pseudomonas species do not contain G blocks (34, 36). In contrast to the alginates produced by brown algae, bacterial alginates are partially O-acetylated at O-2 and/or O-3 on mannuronic acid residues (36).The relative amount and distribution of G residues determine most of the physicochemical properties of the polymer. Alginates with G blocks can form gels by reversible cross-linking with divalent cations such as Ca²⁺, Ba²⁺, and Sr²⁺ (41), and the gelling and viscosifying properties of alginate are utilized in pharmaceutical, food, textile, and paper industries (26). In addition, alginate has a very interesting potential in a variety of biotechnological applications and in biomedicine. Alginate rich in M blocks stimulates cytokine production (27) and has a much higher antitumor activity than alginates with a high fraction of G blocks (14). G-rich alginates can be used for encapsulation of cells and enzymes (35), and Langerhans islets immobilized in alginates rich in G have been evaluated as a potential treatment for type 1 diabetes (39, 40).Both in brown algae and in alginate-producing bacteria, the polymer is first synthesized as mannuronan, and the enzyme mannuronan C-5-epimerase catalyzes the epimerization of M to G at the polymer level (7, 12, 21, 22). Ertesvåg et al. (7) have previously reported the cloning and expression of five genes encoding a family of Ca²⁺-dependent epimerases in A. vinelandii (algE1 to -5). The deduced AlgE protein sequences consist of two types of structural modules, designated A (385 amino acids each; one or two copies) and R (155 amino acids each; one to seven copies), and each R module contains four to six nine-amino-acid-long repeated sequences corresponding to putative Ca²⁺-binding motifs. The molecular masses of AlgE1 to -5 vary from 57.7 (AlgE4) to 191 kDa (AlgE3), depending on the number of A and R modules in the proteins. Four of the epimerase genes are clustered in the chromosome (algE1 to -4), while algE5 is located in another part of the A. vinelandii genome. Nuclear magnetic resonance (NMR) spectroscopy analyses demonstrate that the reaction products at least of AlgE2 and AlgE4 differ with respect to sequence distributions of M and G residues. AlgE2 leads to formation of mainly G blocks, while AlgE4 forms predominantly alginates with MG blocks.The A. vinelandii chromosome also encodes a Ca²⁺-independent mannuronan C-5-epimerase, designated AlgG (30). Sequence alignments demonstrate that algG does not belong to the algE gene family but shares 66% sequence identity to a mannuronan C-5-epimerase gene (also designated algG) from P. aeruginosa (12). The algG gene in P. aeruginosa is localized in a cluster of alg genes encoding enzymes involved in alginate biosynthesis, and sequence analysis of genomic DNA flanking algG in A. vinelandii suggests that this gene also is part of an alg gene cluster organized as in P. aeruginosa (30).Southern blot analysis of genomic A. vinelandii DNA using the 5′-terminal 800 bp in the A sequence of algE2 as the probe (A probe) demonstrated that the chromosome probably encodes more A-like sequences than are present in algE1 to -5 (7). In this report, we show that the A. vinelandii genome encodes two additional mannuronan C-5-epimerase genes, designated algE6 and algE7, and also a third highly related gene apparently not encoding an active epimerase.