An exotype alginate lyase in Sphingomonas sp. A1: overexpression in Escherichia coli,purification, and characterization of alginate lyase IV (A1-IV)

Sphingomonas sp. A1 (strain A1) cells contain three kinds of endotype alginate lyases [A1-I, A1-II, and A1-III], all of which are formed from a common precursor through posttranslational processing. In addition to these lyases, another type of lyase (A1-IV) that acts on oligoalginates exists in the bacterium. A1-IV was overexpressed in Escherichia coli cells through control of its gene under the T7 promoter. The expression level of the enzyme in E. coli cells was 8.6U/L-culture, which was about 270-fold higher than that in strain A1 cells. The enzyme was purified to homogeneity through three steps with an activity yield of 10.9%. The optimal pH and temperature, thermal stability, and mode of action of the purified enzyme were similar to those of the native enzyme from strain A1 cells. A1-IV exolytically degraded oligoalginates, which were produced from alginate through the reaction of A1-I, A1-II, or A1-III, into monosaccharides, indicating that the cooperative actions of these four enzymes cause the complete depolymerization of alginate in strain A1 cells.     

Molecular identification of oligoalginate lyase of Sphingomonas sp. strain A1 as one of the enzymes required for complete depolymerization of alginate

A bacterium, Sphingomonas sp. strain A1, can incorporate alginate into cells through a novel ABC (ATP-binding cassette) transporter system specific to the macromolecule. The transported alginate is depolymerized to di- and trisaccharides by three kinds of cytoplasmic alginate lyases (A1-I [66 kDa], A1-II [25 kDa], and A1-III [40 kDa]) generated from a single precursor through posttranslational autoprocessing. The resultant alginate oligosaccharides were degraded to monosaccharides by cytoplasmic oligoalginate lyase. The enzyme and its gene were isolated from the bacterial cells grown in the presence of alginate. The purified enzyme was a monomer with a molecular mass of 85 kDa and cleaved glycosidic bonds not only in oligosaccharides produced from alginate by alginate lyases but also in polysaccharides (alginate, polymannuronate, and polyguluronate) most efficiently at pH 8.0 and 37 degrees C. The reaction catalyzed by the oligoalginate lyase was exolytic and thought to play an important role in the complete depolymerization of alginate in Sphingomonas sp. strain A1. The gene for this novel enzyme consisted of an open reading frame of 2,286 bp encoding a polypeptide with a molecular weight of 86,543 and was located downstream of the genes coding for the precursor of alginate lyases (aly) and the ABC transporter (algS, algM1, and algM2). This result indicates that the genes for proteins required for the transport and complete depolymerization of alginate are assembled to form a cluster.     

Origin and diversity of alginate lyases of families PL-5 and -7 in Sphingomonas sp. strain A1

Sphingomonas sp. strain A1 has three endotype alginate lyases (A1-I, A1-II [family PL-7], and A1-III [family PL-5]), each of which is encoded by a single gene. In addition to those of these lyases, a gene (the A1-II' gene) showing significant identity with the A1-II gene was present in the bacterial genome and coded for an alginate lyase with broad substrate specificity. Since no expression of A1-II' was observed even in bacterial cells grown on alginate, the A1-II' gene was thought to be a silent gene derived from the A1-II gene, presumably through duplication, modification, and translocation.     

Molecular identification of a polyM-specific alginate lyase from Pseudomonas sp. strain KS-408 for degradation of glycosidic linkages between two mannuronates or mannuronate and guluronate in alginate

An alginate lyase gene of a newly isolated Pseudomonas sp. strain KS-408 was cloned by using PCR with the specific primers designed from homologous nucleotide sequences. A partial protein sequence of KS-408 alginate lyase was homology-modeled on the basis of the crystal structure of A1-III alginate lyase from Sphingomonas sp. strain A1. The proposed 3-D structure of KS-408 alginate lyase shows that Asn-198, His-199, Arg-246, and Tyr-253 residues are conserved for the catalytic active site. The recombinant KS-408-1F (with signal peptide) and KS-408-2F (without signal peptide) alginate lyases with the (His)(6) tag consist of 393 (44.5 kDa) and 372 (42.4 kDa) amino acids with isoelectric points of 8.64 and 8.46, respectively. The purified recombinant KS-408 alginate lyase was very stable when it was incubated at 40 °C for 30 min. Alginate oligosaccharides produced by the KS-408-2F alginate lyase were purified on a Bio-Gel P2 column and analyzed by thin-layer chromatography, fast-protein liquid chromatography, and electrospray ionization mass spectrometry. (1)H NMR data showed that the KS-408-2F alginate lyase cleaved the glycosidic linkages between two mannuronates (mannuronate-β(1-4)-mannuronate) or mannuronate and guluronate (mannuronate-β(1-4)-guluronate), indicating that the KS-408 alginate lyase is a polyM-specific lyase.     

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.     

Comparative study of three phospholipase A2s from the venom of Vipera aspis

1. Three phospholipase A2s, PLA2-I, PLA2-II and PLA2-III, were isolated from Vipera aspis venom by gel filtration and ion exchange chromatography. 2. Purified PLA2-I, -II and -III have mol. wts of 30,200, 16,000 and 13,500, and isoelectric points of 9.45, 7.65 and less than 4.1, respectively. 3. PLA2-I consists of an acidic subunit (mol. wt 13,700, pI: less than 3.5) and a basic subunit (mol. wt 16,500, pI: 10.6), which can be separated under highly acidic conditions. 4. PLA2-I possessed lethal activity and LD50 for this preparation was estimated to be 0.288 (0.209-0.397) micrograms/g, while lethality was not observed when PLA2-II, -III or each subunit of PLA2-I were administered. 5. Capillary permeability-increasing activity was found in the samples which possessed basic isoelectric points. Additionally, PLA2-I and its basic subunit drastically prolonged activated partial thromboplastin time of platelet rich plasma. 6. Intramuscular injections of PLA2-I, -II and -III increased serum creatine phosphokinase activity in mice, indicating that damage in muscle was caused by these enzymes. 7. NH2-terminal sequences of the three PLA2s were compared with other phospholipase A2s from snake venoms. Furthermore, antigenicities were tested using antiserum prepared against each sample.     

Bacterial alginate lyase gene: Nucleotide sequence and molecular route for generation of alginate lyase species

A bacterium (strain A1) isolated from a ditch synthesized three types of intracellular alginate lyases: A1-I (molecular weight [M.W.] 60,000), A1-II-2 (M.W. 25,000) and A1-III (M.W. 38,000). The nucleotide sequence of the gene for A1-I lyase, which has been cloned in Escherichia coli DH1 was determined. The open reading frame of the gene encoded 622 amino acids with a calculated M.W. of 69,153. The N-terminal amino acid sequence of A1-I lyase purified from strain A1 or E. coli DH1 cells transformed with the A1-I lyase gene was consistent with the deduced sequence from ⁵⁵His to ⁷⁴Ala, indicating that the A1-I lyase was synthesized as a precursor with a M.W. of 69,153 and then processed to a mature form with a M.W. of 63,681. The N-terminal sequence of the first twenty amino acids of A1-III lyase was found to match that of A1-I lyase. The N-terminal sequence of the first twenty amino acids of A1-II-2 lyase was consistent with the deduced amino acid sequence from ⁴¹⁴Ala to ⁴³³Val in the nucleotide sequence of the A1-I lyase gene. These results indicated that the A1-I lyase was further processed to generate A1-II-2 and A1-III lyase species.     

Structure and function of bacterial super-biosystem responsible for import and depolymerization of macromolecules

Generally, when microbes assimilate macromolecules, they incorporate low-molecular-weight products derived from macromolecules through the actions of extracellular degrading enzymes. However, a Gram-negative bacterium, Sphingomonas sp. A1, has a smart biosystem for the import and depolymerization of macromolecules. The bacterial cells directly incorporate a macromolecule, alginate, into the cytoplasm through a "superchannel", as we named it. The superchannel consists of a pit on the cell surface, alginate-binding proteins in the periplasm, and an ATP-binding cassette transporter in the inner membrane. Cytoplasmic polysaccharide lyases depolymerize alginate into the constituent monosaccharides. Other than the proteins characterized so far, novel proteins (e.g., flagellin homologs) have been found to be crucial for the import and depolymerization of alginate through genomics- and proteomics-based identification, thus indicating that the biosystem is precisely constructed and regulated by diverse proteins. In this review, we focus on the structure and function of the bacterial biosystem together with the evolution of related proteins.     

Crystal structure of the alginate (poly alpha-l-guluronate) lyase from Corynebacterium sp. at 1.2 A resolution

The crystal structure of alginate (poly alpha-l-guluronate) lyase from Corynebacterium sp. (ALY-1) was determined at 1.2A resolution using the MAD method and bromide ions. The structure of ALY-1 is abundant in beta-strands and has a deep cleft, similar to the jellyroll beta-sandwich found in 1,3-1,4-beta-glucanase. The structure suggests that alginate molecules may penetrate into the cleft to interact with the catalytic site of ALY-1. The reported crystal structure of another type of alginate lyase, A1-III, differs from that of ALY-1 in that it consists almost entirely of alpha-helical structure. Nevertheless, the putative catalytic residues in both enzymes are positioned in space in nearly identical arrangements. This finding suggests that both alginate lyases may have evolved through convergent evolution.     

Cloning of a gene for intracellular alginate lyase in a bacterium isolated from a ditch

A DNA fragment with a gene for intracellular alginate lyase in a bacterium A1 isolated from a ditch was cloned using a vector plasmid pKK223-3 and the gene was weakly expressed in Escherichia coli DH1 cells. The alginate lyase produced by E. coli DH1 cells was thought to correspond to A1-I among three kinds of alginate lyases (A1-I, A1-I-1 and A1-I-2) produced by the strain A1. Through this study, CaCl₂ was found to be a useful agent for the screening of microbial alginate lyase-producing colonies on agar plates.     

Cloning and Sequencing of Alginate Lyase Genes from Deep-Sea Strains of Vibrio and Agarivorans and Characterization of a New Vibrio Enzyme

Four alginate lyase genes were cloned and sequenced from the genomic DNAs of deep-sea bacteria, namely members of Vibrio and Agarivorans. Three of them were from Vibrio sp. JAM-A9m, which encoded alginate lyases, A9mT, A9mC, and A9mL. A9mT was composed of 286 amino acids and 57% homologous to AlxM of Photobacterium sp. A9mC (221 amino acids) and A9mL (522 amino acids) had the highest degree of similarity to two individual alginate lyases of Vibrio splendidus with 74% and 84% identity, respectively. The other gene for alginate lyase, A1mU, was shotgun cloned from Agarivorans sp. JAM-A1m. A1mU (286 amino acids) showed the highest homology to AlyVOA of Vibrio sp. with 76% identity. All alginate lyases belong to polysaccharide lyase family 7, although, they do not show significant similarity to one another with 14% to 58% identity. Among the above lyases, the recombinant A9mT was purified to homogeneity and characterized. The molecular mass of A9mT was around 28 kDa. The enzyme was remarkably salt activated and showed the highest thermal stability in the presence of NaCl. A9mT favorably degraded mannuronate polymer in alginate. We discussed substrate specificities of family 7 alginate lyases based on their conserved amino acid sequences.     

Structure and function of a hypothetical Pseudomonas aeruginosa protein PA1167 classified into family PL-7: a novel alginate lyase with a beta-sandwich fold

Structural and functional analyses of alginate lyases are important in the clarification of the biofilm-dependent ecosystem in Pseudomonas aeruginosa and in the development of therapeutic agents for bacterial disease. Most alginate lyases are classified into polysaccharide lyase (PL) family-5 and -7 based on their primary structures. Family PL-7 enzymes are still poorly characterized especially in structural properties. Among family PL-7, a gene coding for a hypothetical protein (PA1167) homologous to Sphingomonas alginate lyase A1-II was found to be present in the P. aeruginosa genome. PA1167 overexpressed in Escherichia coli cleaved glycosidic bonds in alginate and released unsaturated saccharides, indicating that PA1167 is an alginate lyase catalyzing a beta-elimination reaction. The enzyme acted preferably on heteropolymeric regions endolytically and worked most efficiently at pH 8.5 and 40 degrees C. The specific activity of PA1167, however, was much weaker than that of the known alginate lyase AlgL, suggesting that AlgL plays a main role in alginate depolymerization in P. aeruginosa. In addition to this specific activity, differences were found between PA1167 and AlgL in enzyme properties such as molecular mass, optimum pH, salt effect, and substrate specificity. The first crystal structure of the family PL-7 alginate lyase was determined at 2.0 A resolution. PA1167 was found to form a glove-like beta-sandwich composed of 15 beta-strands and 3 alpha-helices. The structural difference between the beta-sandwich PA1167 of family PL-7 and alpha/alpha-barrel AlgL of family PL-5 may be responsible for the enzyme characteristics. Crystal structures of polysaccharide lyases determined so far indicate that they can be assigned to three folding groups having parallel beta-helix, alpha/alpha-barrel, and alpha/alpha-barrel + antiparallel beta-sheet structures as basic frames. PA1167 is the fourth novel folding structure found among polysaccharide lyases.     

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.     

A novel member of glycoside hydrolase family 88: overexpression,purification, and characterization of unsaturated beta-glucuronyl hydrolase of Bacillus sp. GL1

Unsaturated beta-glucuronyl hydrolase of Bacillus sp. GL1 catalyzes the hydrolytic release of unsaturated glucuronic acids from oligosaccharides produced through the reactions of polysaccharide lyases such as gellan, xanthan, hyaluronate, and chondroitin lyases. An overexpression system for the enzyme was constructed in Escherichia coli cells involving regulation of the enzyme gene under the T7 promoter and terminator. The expression level of the enzyme in E. coli cells was 250-fold higher than that in Bacillus sp. GL1 cells. The enzyme expressed in E. coli cells was purified and characterized. The optimal pH and temperature, and substrate specificity of the purified enzyme were similar to those of the native enzyme from Bacillus sp. GL1 cells, although the enzyme expressed in E. coli cells underwent self-assembly into polymeric forms through the formation of intermolecular disulfide bonds. Circular dichroism analysis indicated that the secondary structure of the enzyme was rich in alpha-helices. Genes showing high identity (over 40% identity) with that of the enzyme were found in the genomes of some pathogenic bacteria, such as Streptococcus pyogenes and Streptococcus pneumoniae, which cause serious diseases (e.g., meningitis and pneumonia). Therefore, the enzyme of Bacillus sp. GL1 and the streptococcal proteins form a new glycoside hydrolase family, 88.     

Properties of cytochrome c and methanol dehydrogenase produced by wild type and mutant strains of Methylomonas sp. in continuous culture

The cytochrome c production of the wild type strain and a mutant strain, YK 56, of Methylomonas sp. grown with excess methanol was higher than wild with limited methanol. The wild type strain grown under both conditions contained two soluble cytochromes c (c-I and c-II), though the mutant strain contained three (c-I, c-II, and c-III). The proportions of cytochromes c-II and c-III of the mutant strain damage changed according to the culture conditions.The methanol dehydrogenase of the wild type and mutant strains was purified and characterized. The enzymes were similar; they consisted of two subunits and their molecular weight was 120,000. The reactivity of cytochromes c with methanol dehydrogenase was investigated.     

Cloning of genes encoding pectolytic enzymes from a genomic library of the phytopathogenic bacterium, Erwinia chrysanthemi

Erwinia chrysanthemi are phytopathogenic enterobacteria causing soft-rot disease due to pectolytic enzymes degrading plant cell walls. We constructed a genomic library from Sau3A-digested E. chrysanthemi B374 DNA cloned in the BamHI site of the broad-host-range cosmid pMMB33 grown in Escherichia coli. Out of 1500 kanamycin-resistant (KmR) transductants of E. coli, nine pectolytic-enzyme-positive clones were identified. One of these contained the pEW325 cosmid with a 35-kb insert of Erwinia DNA. Cell extracts of E. coli harboring the cosmid pEW325 were fractionated on a polyacrylamide electrofocusing gel; bands with pectolytic activity were found to co-focus with pectolytic enzymes of E. chrysanthemi B374 strain. Cosmid pEW325 encodes three pectolytic enzymes PL10, PL20 and PL130 with isoelectric points of about 9.3, 9.2 and 4.6, respectively. These enzymes are lyases that cleave polygalacturonate by transelimination, and give rise to unsaturated products. A 15-kb HindIII fragment coding for polygalacturonate lyases was subcloned in pBR322, and a physical map of the resulting plasmid pPL01 was constructed. Starting from the pPL01, various endonuclease-generated fragments were subcloned into pBR322. Genes encoding pectate lyases were localized within an 8-kb fragment (pPL04) and then in a 2.7-kb fragment (pPL03). Polygalacturonate lyases are expressed at various levels; they accumulated in the periplasmic space of E. coli host, whereas E. chrysanthemi secreted these enzymes into the culture medium.     

Bacterial supersystem for alginate import/metabolism and its environmental and bioenergy applications

Distinct from most alginate-assimilating bacteria that secrete polysaccharide lyases extracellularly, a gram-negative bacterium, Sphingomonas sp. A1 (strain A1), can directly incorporate alginate into its cytoplasm, without degradation, through a "superchannel" consisting of a mouth-like pit on the cell surface, periplasmic binding proteins, and a cytoplasmic membrane-bound ATP-binding cassette transporter. Flagellin homologues function as cell surface alginate receptors essential for expressing the superchannel. Cytoplasmic alginate lyases with different substrate specificities and action modes degrade the polysaccharide to its constituent monosaccharides. The resultant monosaccharides, α-keto acids, are converted to a reduced form by NADPH-dependent reductase, and are finally metabolized in the TCA cycle. Transplantation of the strain A1 superchannel to xenobiotic-degrading sphingomonads enhances bioremediation through the propagation of bacteria with an elevated transport activity. Furthermore, strain A1 cells transformed with Zymomonas mobilis genes for pyruvate decarboxylase and alcohol dehydrogenase II produce considerable amounts of biofuel ethanol from alginate when grown statically.     

Nucleotide sequences of two members of the chicken H3 histone-encoding gene family

The nucleotide sequences of two genes (H3-II and H3-III) from the chicken H3 histone-encoding gene family have been determined. H3-II and H3-III, respectively, possess possible AP-1- and Sp1-binding sequence elements of the forms 5'-CGAGTCAG and 5'-GGGCGGG, whereas all three H3 genes, including the previously sequenced H3-I gene, encode the same amino acid sequence.     

Immunological and structural properties of a pectic polymer from Glinus oppositifolius

The aim of this paper was to further elucidate the structure and the immunomodulating properties of the pectic polymer GOA2, previously isolated from Glinus oppositifolius. Enzymatic treatment of GOA2 by endo-alpha-d-(1 --> 4)-polygalacturonase led to the isolation of three pectic subunits, GOA2-I, GOA2-II, and GOA2-III, in addition to oligogalacturonides. GOA2-I was shown to consist of 1,2-linked Rhap and 1,4-linked GalpA in an approximately 1:1 ratio, and NMR-analysis showed that the monomers were linked together in a strictly alternating manner. The galactose units in GOA2-I were found as terminal-, 1,3-, 1,6-, 1,4-, 1,3,4-, and 1,3,6-linked residues, while the arabinofuranosyl existed mainly as terminal- and 1,5-linked units. A rhamnogalacturonan-I type structure was suggested being the predominant part of GOA2-I. According to linkage analysis GOA2-II and GOA2-III contained glycosidic linkages characteristic for rhamnogalacturonan-II type structures. GOA2 was shown by sedimentation velocity in the analytical ultracentrifuge, to have a broad degree of polydispersity with a mode s(20,w) value of approximately 1.9 S, results reinforced by atomic force microscopy measurements. The polydispersity, as manifested by the proportion of material with s(20,w) > 3 S, decreased significantly with enzyme treatment. The abilities of GOA2, GOA2-I, GOA2-II, and GOA2-III to induce the proliferation of B cells, and to exhibit complement fixing activities were tested. In both test systems, GOA2-I showed significantly greater effects compared to its native pectin GOA2. GOA2-I was in addition shown to exhibit a more potent intestinal immune stimulating activity compared to GOA2. The ability of GOA2 to induce secretion of proinflammatory cytokines was examined. Marked upregulations in mRNA for IL-1beta from rat macrophages and IFN-gamma from NK cells were found.