A novel oligoalginate lyase from abalone, Haliotis discus hannai, that releases disaccharide from alginate polymer in an exolytic manner

We previously reported the isolation and cDNA cloning of an endolytic alginate lyase, HdAly, from abalone Haliotis discus hannai [Carbohydr. Res.2003, 338, 2841-2852]. Although HdAly preferentially degraded mannuronate-rich substrates, it was incapable of degrading unsaturated oligomannuronates smaller than tetrasaccharide. In the present study, we used conventional chromatographic techniques to isolate a novel unsaturated-trisaccharide-degrading enzyme, named HdAlex, from the digestive fluid of the abalone. The HdAlex showed a molecular weight of 32,000 on SDS-PAGE and could degrade not only unsaturated trisaccharide but also alginate and mannuronate-rich polymers at an optimal pH and temperature of 7.1 and 42 degrees C, respectively. Upon digestion of alginate polymer, HdAlex decreased the viscosity of the alginate at a slower rate than did HdAly, producing only unsaturated disaccharide without any intermediate oligosaccharides. These results indicate that HdAlex degrades the alginate polymer in an exolytic manner. Because HdAlex split saturated trisaccharide producing unsaturated disaccharide, we considered that this enzyme cleaved the alginate at the second glycoside linkage from the reducing terminus. The primary structure of HdAlex was deduced with cDNAs amplified from an abalone hepatopancreas cDNA library by the polymerase chain reaction. The translational region of 822 bp in the total 887-bp sequence of HdAlex cDNA encoded an amino-acid sequence of 273 residues. The N-terminal sequence of 16 residues, excluding the initiation methionine, was regarded as the signal peptide of this enzyme. The amino-acid sequence of the remaining 256 residues shared 62-67% identities with those of the polysaccharide lyase family-14 (PL14) enzymes such as HdAly and turban-shell alginate lyase SP2. To our knowledge, HdAlex is the first exolytic oligoalginate lyase belonging to PL14.     

Purification and cDNA cloning of a cellulase from abalone Haliotis discus hannai.

A cellulase [endo-beta-1,4-D-glucanase (EC 3.2.1.4)] was isolated from the hepatopancreas of abalone Haliotis discus hannai by successive chromatographies on TOYOPEARL CM-650M, hydroxyapatite and Sephacryl S-200 HR. The molecular mass of the cellulase was estimated to be 66 000 Da by SDS/PAGE, thus the enzyme was named HdEG66. The hydrolytic activity of HdEG66 toward carboxymethylcellulose showed optimal temperature and pH at 38 degrees C and 6.3, respectively. cDNAs encoding HdEG66 were amplified by the polymerase chain reaction from an abalone hepatopancreas cDNA library with primers synthesized on the basis of partial amino-acid sequences of HdEG66. By overlapping the nucleotide sequences of the cDNAs, a sequence of 1898 bp in total was determined. The coding region of 1785 bp located at nucleotide position 56-1840 gave an amino-acid sequence of 594 residues including the initiation methionine. The N-terminal region of 14 residues in the deduced sequence was regarded as the signal peptide as it was absent in HdEG66 protein and showed high similarity to the consensus sequence for signal peptides of eukaryote secretory proteins. Thus, matured HdEG66 was thought to consist of 579 residues. The C-terminal region of 453 residues in HdEG66, i.e. approximately the C-terminal three quarters of the protein, showed 42-44% identity to the catalytic domains of glycoside hydrolase family 9 (GHF9)-cellulases from arthropods and Thermomonospora fusca. While the N-terminal first quarter of HdEG66 showed 27% identity to the carbohydrate-binding module (CBM) of a Cellulomonas fimi cellulase, CenA. Thus, the HdEG66 was regarded as the GHF9-cellulase possessing a family II CBM in the N-terminal region. By genomic PCR using specific primers to the 3'-terminal coding sequences of HdEG66-cDNA, a DNA of 2186 bp including three introns was amplified. This strongly suggests that the origin of HdEG66 is not from symbiotic bacteria but abalone itself.     

cDNA cloning of an alginate lyase from a marine gastropod Aplysia kurodai and assessment of catalytically important residues of this enzyme

Herbivorous marine gastropods such as abalone and sea hare ingest brown algae as a major diet and degrade the dietary alginate with alginate lyase (EC 4.2.2.3) in their digestive fluid. To date alginate lyases from Haliotidae species such as abalone have been well characterized and the primary structure analyses have classified abalone enzymes into polysaccharide-lyase-family 14 (PL-14). However, other gastropod enzymes have not been so well investigated and only partial amino-acid sequences are currently available. To improve the knowledge for primary structure and catalytic residues of gastropod alginate lyases, we cloned the cDNA encoding an alginate lyase, AkAly30, from an Aplysiidae species Aplysia kurodai and assessed its catalytically important residues by site-directed mutagenesis. Alginate lyase cDNA fragments were amplified by PCR followed by 5′- and 3′-RACE from A. kurodai hepatopancreas cDNA. The finally cloned cDNA comprised 1313 bp which encoded an amino-acid sequence of 295 residues of AkAly30. The deduced sequence comprised an initiation methionine, a putative signal peptide for secretion (18 residues), a propeptide-like region (9 residues), and a mature AkAly30 domain (267 residues) which showed ∼40% amino-acid identity with abalone alginate lyases. An Escherichia coli BL21(DE3)-pCold I expression system for recombinant AkAly30 (recAkAly30) was constructed and site-directed mutagenesis was performed to assess catalytically important amino-acid residues which had been suggested in abalone and Chlorella virus PL-14 enzymes. Replacements of K99, S126, R128, Y140 and Y142 of recAkAly30 by Ala and/or Phe greatly decreased its activity as in the case of abalone and/or Chlorella virus enzymes. Whereas, H213 that was essential for Chlorella virus enzyme to exhibit the activity at pH 10.0 was originally replaced by N120 in AkAly30. The reverse replacement of N120 by His in recAkAly30 increased the activity at pH 10.0 from 8 U/mg to 93 U/mg; however, the activity level at pH 7.0, i.e., 774.8 U/mg, was still much higher than that at pH 10.0. This indicates that N120 is not directly related to the pH dependence of AkAly30 unlike H213 of vAL-1.     

Isolation and cloning of an endo-beta-1,4-mannanase from Pacific abalone Haliotis discus hannai

An endo-beta-1,4-mannanase was isolated from digestive fluid of Pacific abalone, Haliotis discus hannai, by successive chromatographies on TOYPEARL CM-650M, hydroxyapatite, and TOYOPEARL HW50F. The abalone mannanase, named HdMan in the present paper, showed a molecular mass of approximately 39,000 Da on SDS-PAGE, and exhibited high hydrolyic activity on both galactomannan from locust bean gum and glucomannan from konjac at an optimal pH and temperature of 7.5 and 45 degrees C, respectively. HdMan could degrade either beta-1,4-mannan or beta-1,4-mannooligosaccharides to mannotriose and mannobiose similarly to beta-1,4-mannanases from Pomacea, Littorina, and Mytilus. In addition, HdMan could disperse the fronds of a red alga Porphyra yezoensis into cell masses consisting of 10-20 cells that are available for cell engineering of this alga. cDNAs encoding HdMan were amplified by polymerase chain reaction from an abalone-hepatopancreas cDNA library. From the nucleotide sequences of the cDNAs, the sequence of 1232 bp in total was determined and the amino-acid sequence of 377 residues was deduced from the translational region of 1134 bp locating at nucleotide positions 15-1148. The N-terminal region of 17 residues except for the initiation Met, was regarded as the signal peptide of HdMan because it was absent in the HdMan protein and showed high similarity to the consensus sequence for signal peptides of eukaryote secretory proteins. Accordingly, mature HdMan was considered to consist of 359 residues with the calculated molecular mass of 39,627.2 Da. HdMan is classified into glycoside hydrolase family 5 (GHF5) on the basis of sequence homology to GHF5 enzymes.     

A Novel Aldo-Keto Reductase,HdRed, from the Pacific Abalone Haliotis discus hannai,Which Reduces Alginate-derived 4-Deoxy-l-erythro-5-hexoseulose Uronic Acid to 2-Keto-3-deoxy-d-gluconate

Abalone feeds on brown seaweeds and digests seaweeds'' alginate with alginate lyases (EC 4.2.2.3). However, it has been unclear whether the end product of alginate lyases (i.e. unsaturated monouronate-derived 4-deoxy-l-erythro-5-hexoseulose uronic acid (DEH)) is assimilated by abalone itself, because DEH cannot be metabolized via the Embden-Meyerhof pathway of animals. Under these circumstances, we recently noticed the occurrence of an NADPH-dependent reductase, which reduced DEH to 2-keto-3-deoxy-d-gluconate, in hepatopancreas extract of the pacific abalone Haliotis discus hannai. In the present study, we characterized this enzyme to some extent. The DEH reductase, named HdRed in the present study, could be purified from the acetone-dried powder of hepatopancreas by ammonium sulfate fractionation followed by conventional column chromatographies. HdRed showed a single band of ∼40 kDa on SDS-PAGE and reduced DEH to 2-keto-3-deoxy-d-gluconate with an optimal temperature and pH at around 50 °C and 7.0, respectively. HdRed exhibited no appreciable activity toward 28 authentic compounds, including aldehyde, aldose, ketose, α-keto-acid, uronic acid, deoxy sugar, sugar alcohol, carboxylic acid, ketone, and ester. The amino acid sequence of 371 residues of HdRed deduced from the cDNA showed 18–60% identities to those of aldo-keto reductase (AKR) superfamily enzymes, such as human aldose reductase, halophilic bacterium reductase, and sea hare norsolorinic acid (a polyketide derivative) reductase-like protein. Catalytic residues and cofactor binding residues known in AKR superfamily enzymes were fairly well conserved in HdRed. Phylogenetic analysis for HdRed and AKR superfamily enzymes indicated that HdRed is an AKR belonging to a novel family.     

Cloning and Sequence Analysis of the Gene (alyII) Coding for an Alginate Lyase of Pseudomonas sp. OS-ALG-9

Pseudomonas sp. OS-ALG-9 produces several kinds of alginate-degrading enzymes both intra- and extracellularly. As a second alginate lyase of this bacterium, the gene encoding alyII has been cloned in Escherichia coli JM109 by shotgun techniques and then sequenced. The alyII gene has an open reading frame of 2141 bp encoding 713 amino acid residues with a calculated molecular mass of 79,803 Da. The deduced amino acid sequence did not show any extensive similarity with those of other known alginate lyases, however, hydrophobic cluster analysis showed that alyII belonged to class 3 of alginate lyases. The alginate lyase from E. coli harboring the alyII gene showed a single active band, which coincided with one of four major alginate lyases from the crude cell extracts of Pseudomonas sp. OS-ALG-9 on a zymogram.     

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.     

Cloning and sequencing of a Deleya marina gene encoding for alginate lyase

A bacterial strain N-1 was isolated as a decomposer of alginate and identified as Deleya marina. The alyA encoding for alginate lyase was cloned into Escherichia coli. The structural gene, located on a 1.9-kb SalI fragment, revealed 1,122 bp encoding a mature protein of 348 amino acids and a signal peptide of 26 amino acids. The deduced amino acid sequence of the D. marina alginate lyase showed high homology to AlgL of Pseudomonas aeruginosa with 63% identity and belonging to class 1 by hydrophobic cluster analysis.     

Cloning and expression of the algL gene, encoding the Azotobacter chroococcum alginate lyase: purification and characterization of the enzyme

The alginate lyase-encoding gene (algL) of Azotobacter chroococcum was localized to a 3.1-kb EcoRI DNA fragment that revealed an open reading frame of 1,116 bp. This open reading frame encodes a protein of 42.98 kDa, in agreement with the value previously reported by us for this protein. The deduced protein has a potential N-terminal signal peptide that is consistent with its proposed periplasmic location. The analysis of the deduced amino acid sequence indicated that the gene sequence has a high homology (90% identity) to the Azotobacter vinelandii gene sequence, which has very recently been deposited in the GenBank database, and that it has 64% identity to the Pseudomonas aeruginosa gene sequence but that it has rather low homology (15 to 22% identity) to the gene sequences encoding alginate lyase in other bacteria. The A. chroococcum AlgL protein was overproduced in Escherichia coli and purified to electrophoretic homogeneity in a two-step chromatography procedure on hydroxyapatite and phenyl-Sepharose. The kinetic and molecular parameters of the recombinant alginate lyase are similar to those found for the native enzyme.     

Molecular cloning and responsive expression of macrophage expressed gene from small abalone Haliotis diversicolor supertexta

The complete cDNA sequence of macrophage expressed gene (saMpeg1), a perforin-like molecule, was isolated from small abalone (Haliotis diversicolor supertexta) by homology cloning and rapid amplification of cDNA ends (RACE). The full-length cDNA of saMpeg1 was 2781 bp, consisting of a 5'-terminal untranslated region (UTR) of 252 bp, a 3'-terminal UTR of 342 bp with a signal sequence TAA and a poly (A) tail, and an open reading frame of 2184 bp. The deduced protein (saMpeg1) was composed of 728 amino acids, and contains the cytolytic "helix-turn-helix" domain of perforin (residues 171-218), of which the alpha-helices are amphipathic as are those of perforin. A putative single transmembrane domain is located at residues 667-689, and a modified furin cleavage site (KRRRK; residues 689-693) immediately follows. The result of real time quantitative PCR showed that saMpeg1 was highly expressed at 8h and 96 h post-injection of the Gram-negative bacterium Vibrio parahaemolyticus, but there was no change after TBT exposure. The structural similarity to mammalian perforin and the different gene expression level to bacterial infection and TBT exposure suggest that saMpeg1 may play a role in the immune response against microorganisms in small abalone.     

Cloning and Characterization of a Novel Oligoalginate Lyase from a Newly Isolated Bacterium Sphingomonas sp. MJ-3

A bacterium possessing alginate-degrading activity was isolated from marine brown seaweed soup liquefied by salted and fermented anchovy. The isolated strain was designated as Sphingomonas sp. MJ-3 based on the analyses of 16S ribosomal DNA sequences, 16S-23S internal transcribed spacer region sequences, biochemical characteristics, and cellular fatty acid composition. A novel alginate lyase gene was cloned from genomic DNA library and then expressed in Escherichia coli. When the deduced amino acid sequence was compared with the sequences on the databases, interestingly, the cloned gene product was predicted to consist of AlgL (alginate lyase L)-like and heparinase-like protein domain. The MJ-3 alginate lyase gene shared below 27.0% sequence identity with exolytic alginate lyase of Sphingomonas sp. A1. The optimal pH and temperature for the recombinant MJ-3 alginate lyase were 6.5 and 50°C, respectively. The final degradation products of alginate oligosaccharides were analyzed by electrospray ionization mass spectrometry and proved to be alginate monosaccharides. Based on the results, the recombinant alginate lyase from Sphingomonas sp. MJ-3 is regarded as an oligoalginate lyase that can degrade oligoalginate and alginate into alginate monosaccharides.     

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.     

Molecular cloning and sequencing of the extracellular pectate lyase II gene from Erwinia carotovora Er.

Erwinia carotovora Er produces three extra-cellular pectate lyases (PL I, II, and III). The gene for pectate lyase II (pelII) of E. carotovora Er was cloned and expressed both in Escherichia coli and E. carotovora Er. Localization experiments in E. coli showed that PL II was exclusively in the cytoplasmic space, while PL II was excreted into the culture medium. The complete nucleotides of the pelII gene were sequenced and found to include one open reading frame of 1122 bp coding for a protein of 374 amino acid residues. From comparison of the N-terminal amino acid sequence between the purified PL II and the deduced protein from the nucleotide sequence we reached the conclusion that the mature protein is composed of 352 amino acids with a calculated molecular weight of 38,169 and is preceded by a typical signal sequence of 22 amino acid residues. PL II had 90.1% and 82.9% homologies with PL I and PL III in amino acid sequence, respectively.     

Cloning and Sequence Analysis of Vibrio halioticoli Genes Encoding Three Types of Polyguluronate Lyase

The alginate lyase-coding genes of Vibrio halioticoli IAM 14596^T, which was isolated from the gut of the abalone Haliotis discus hannai, were cloned using plasmid vector pUC 18, and expressed in Escherichia coli. Three alginate lyase-positive clones, pVHB, pVHC, and pVHE, were obtained, and all clones expressed the enzyme activity specific for polyguluronate. Three genes, alyVG1, alyVG2, and alyVG3, encoding polyguluronate lyase were sequenced: alyVG1 from pVHB was composed of a 1056-bp open reading frame (ORF) encoding 352 amino acid residues; alyVG2 gene from pVHC was composed of a 993-bp ORF encoding 331 amino acid residues; and alyVG3 gene from pVHE was composed of a 705-bp ORF encoding 235 amino acid residues. Comparison of nucleotide and deduced amino acid sequences among AlyVG1, AlyVG2, and AlyVG3 revealed low homologies. The identity value between AlyVG1 and AlyVG2 was 18.7%, and that between AlyVG2 and AlyVG3 was 17.0%. A higher identity value (26.0%) was observed between AlyVG1 and AlyVG3. Sequence comparison among known polyguluronate lyases including AlyVG1, AlyVG2, and AlyVG3 also did not reveal an identical region in these sequences. However, AlyVG1 showed the highest identity value (36.2%) and the highest similarity (73.3%) to AlyA from Klebsiella pneumoniae. A consensus region comprising nine amino acid (YFKAGXYXQ) in the carboxy-terminal region previously reported by Mallisard and colleagues was observed only in AlyVG1 and AlyVG2. Received May 7, 1999; accepted September 4, 1999.     

Molecular and genetic characterization of two pollen-expressed genes that have sequence similarity to pectate lyases of the plant pathogen Erwinia

A set of cDNAs that are expressed in tomato anthers were isolated [24]. We further characterized two of these cDNAs (LAT56 and LAT59) and their corresponding genomic clones. LAT56 and LAT59 show low levels of steady-state mRNA in immature anthers and maximal levels in mature anthers and pollen. The LAT56 and LAT59 genes are single-copy in the tomato genome, and are linked on chromosome 3, approximately 5 cM apart. Although these cDNAs did not cross-hybridize, their deduced protein sequences (P56 and P59) have 54% amino acid identity. The LAT56 and LAT59 genes each have two introns, but they are located in non-homologous positions. P56 and P59 show significant protein sequence similarity to pectate lyases of plant pathogenic bacteria. The similarity of P56 and P59 to the bacterial pectate lyases is equivalent to the homology described for different pectate lyase sequences of the genus Erwinia. We suggest that the pollen expression of LAT56 and LAT59 might relate to a requirement for pectin degradation during pollen tube growth.Abbreviations LAT, late anther tomato - bp, base pairs - MA, mature anther - PL, pectate lyase - kb, kilobase (pairs)     

Cloning, characterization and tissue expression of disk abalone (Haliotis discus discus) catalase

Catalase is an antioxidant enzyme that plays a significant role in protection against oxidative stress by detoxification of hydrogen peroxide (H2O2). A gene coding for a putative catalase was isolated from the disk abalone (Haliotis discus discus) cDNA library and denoted as Ab-catalase. The full-length (2864 bp) Ab-catalase cDNA contained 1,503 bp open reading frame (ORF), encoding 501 amino acid residues with 56 kDa predicted molecular weight. The deduced amino acid sequence of Ab-catalase has characteristic features of catalase family such as catalytic site motif (61FNRERIPERVVHAKGAG77), heme-ligand signature motif (351RLYSYSDT358), NADPH and heme binding residues. Phylogenetic and pairwise identity results indicated that Ab-catalase is more similar to scallop (Chlamys farreri) catalase with 80% amino acid identity except for other reported disk abalone catalase sequences. Constitutive Ab-catalase expression was detected in gill, mantle, gonad, hemocytes, abductor muscle and digestive tract in tissue specific manner. Ab-catalase mRNA was up-regulated in gill and digestive tract tissues for the first 3h post injection of H2O2, showing the inducible ability of abalone catalase against oxidative stress generated by H2O2. The purified recombinant catalase showed 30,000 U/mg enzymatic activity against H2O2 and biochemical properties of higher thermal stability and broad spectrum of pH. Our results suggest that abalone catalase may play an important role in regulating oxidative stress by scavenging H2O2.     

Preparation of protoplasts from Laminaria japonica using native and recombinant abalone alginate lyases

Laminaria japonica protoplasts were released with high yields using the abalone alginate lyase HdAly in combination with a cellulase and chelating agents. Addition of EDTA at concentrations higher than 10 mM to Laminaria thalli which had been preincubated with HdAly and Cellulase Onozuka, dramatically improved the yield of protoplasts. EDTA was far more effective than EGTA, indicating that chelating divalent metal ions such as Mg²⁺ and Sr²⁺ in addition to Ca²⁺ is a key factor for high-yield production of Laminaria protoplasts. Protoplasts had a mean diameter of 27 μm, suggesting that most protoplasts were derived from cortical cells rather than epidermal layer cells. Recombinant HdAly (rHdAly) was produced from a cDNA clone in the Sf9 insect cell expression system. rHdAly had substantially the same enzymatic properties and protoplast-producing ability as did native HdAly. The optimal conditions for high yield production of protoplasts from Laminaria using native and recombinant HdAlys were investigated.     

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.     

Molecular cloning and expression of interleukin-1 receptor-associated kinase 4, an important mediator of Toll-like receptor signal pathway, from small abalone Haliotis diversicolor

Mammal interleukin-1 receptor-associated kinases (IRAKs) have been demonstrated to play important functions in TLRs (Toll-like receptor) signal pathway and T cell proliferation, but there is less knowledge available on mollusc IRAKs. In this study, a molluscan IRAK-4 gene, saIRAK-4, was cloned for the first time from the small abalone (Haliotis diversicolor). Its full-length cDNA sequence was 2062 bp, with a 1548 bp open reading frame encoding a protein of 516 aa. The molecular mass of the deduced protein was approximately 57.8 kDa with an estimated pI of 5.23, and showed highest identity (47%) to acorn worm Saccoglossus kowalevskii. Amino acid sequence analysis revealed saIRAK-4 shares conserved signature motifs with other IRAK-4 proteins, including the death domain (DD), serine/threonine/tyrosine protein kinase domain (STYKc), protein kinases ATP-binding region signature, serine/threonine protein kinases active-site signature and prokaryotic membrane lipoprotein lipid attachment site. Quantitative real-time PCR was employed to investigate the tissue distribution of saIRAK-4 mRNA, and its expression in abalone under bacteria challenge and larvae at different developmental stages. The saIRAK-4 mRNA could be detected in all examined tissues, with the highest expression level in gills, and was up-regulated in hemocytes and gills after bacteria injection. Additionally, saIRAK-4 was constitutively expressed at all examined developmental stages. These results indicate that saIRAK-4 could respond to pathogenic infection and may play an important role in the adult abalone immune system and early innate immunity in the process of abalone larval development.