Cloning and expression analysis of c-type and g-type lysozymes in yellow catfish (<Emphasis Type="Italic">Pelteobagrus fulvidraco</Emphasis>)

Lysozymes have important roles in innate immune system. Here, a c-type and a g-type lysozyme were identified from yellow catfish (Pelteobagrus fulvidraco). The deduced amino acid sequences of both lysozymes were conserved in catalytic sites and structural features as compared to their counterparts from other species. It was interesting that the g-type lysozyme possessed a signal peptide. The c-type and g-type lysozymes had the highest identity 89.4 and 76.2 % with that from channel catfish respectively. Phylogenetic analysis showed that the two lysozymes had a closely relationship with that from channel catfish and Astyanax mexicanus. Lysozymes from one order could form more than one clade in the phylogenetic tree, which indicated the gene duplications in evolution. Expression analysis with real time quantitative PCR revealed that the two lysozyme genes were constitutively expressed in all the tested tissues. The highest expression of c-type lysozyme was observed in liver, followed by spleen, head kidney, and trunk kidney, while the g-type lysozyme had highest expression in intestine, followed by spleen, head kidney, and trunk kidney. The mRNA levels of both genes were all up-regulated after challenging with Aeromonas hydrophila. However, there were differences in tissues and time points when the mRNA levels reached its peak between the two lysozymes. It indicated the diversity in regulation mechanisms and detailed functions among lysozymes. Taking together, these results will benefit the understanding of yellow catfish lysozymes.     

Lysozymes in the animal kingdom

Lysozymes (EC 3.2.1.17) are hydrolytic enzymes, characterized by their ability to cleave the β-(1,4)-glycosidic bond between N-acetylmuramic acid and N-acetylglucosamine in peptidoglycan, the major bacterial cell wall polymer. In the animal kingdom, three major distinct lysozyme types have been identified — the c-type (chicken or conventional type), the g-type (goose-type) and the i-type (invertebrate type) lysozyme. Examination of the phylogenetic distribution of these lysozymes reveals that c-type lysozymes are predominantly present in the phylum of the Chordata and in different classes of the Arthropoda. Moreover, g-type lysozymes (or at least their corresponding genes) are found in members of the Chordata, as well as in some bivalve mollusks belonging to the invertebrates. In general, the latter animals are known to produce i-type lysozymes. Although the homology in primary structure for representatives of these three lysozyme types is limited, their three-dimensional structures show striking similarities. Nevertheless, some variation exists in their catalytic mechanisms and the genomic organization of their genes. Regarding their biological role, the widely recognized function of lysozymes is their contribution to antibacterial defence but, additionally, some lysozymes (belonging to different types) are known to function as digestive enzymes.     

Characterization of a c-type lysozyme of Scophthalmus maximus: Expression,activity, and antibacterial effect

Lysozyme is a key component of the innate immune system and plays an important role in antibacterial infection. In this study, we analyzed the expression and activity of a chicken-type (c-type) lysozyme (named SmLysC) from turbot (Scophthalmus maximus). SmLysC is composed of 143 residues and shares 67–90% overall sequence identities with the c-type lysozymes of a number of teleost fish. SmLysC possesses a typical c-type lysozyme domain, which contains the conserved residues E50 and D67 that form the putative catalytic site. SmLysC expression was detected, in increasing order, in head kidney, gill, heart, muscle, brain, spleen, blood, and liver. Bacterial infection caused significant inductions of SmLysC expression in head kidney, spleen, and liver in a time-dependent manner. Immunoblot analysis indicated that SmLysC has a subcellular localization in the extracellular milieu. Recombinant SmLysC (rSmLysC) was able to bind to bacterial cells and inhibit bacterial growth. Enzyme assay showed that the optimal temperature and pH of rSmLysC were 37 °C and pH 6.0 respectively. In contrast to rSmLysC, the mutant protein rSmLysCM1, which bears alanine substitutions at E50 and D67, displayed drastically reduced bacteriolytic activity. rSmLysC was able to inhibit the growth of several fish bacterial pathogens in a manner that depended on the dose of the protein; however, Gram-positive bacteria were in general more sensitive to rSmLysC than Gram-negative bacteria. Together these results indicate that SmLysC is a functional lysozyme that is likely to participate in innate immune defense against extracellular bacterial pathogens, in particular those of Gram-positive nature.     

Identification and expression analysis of three c-type lysozymes in Oreochromis aureus

Lysozyme is an important molecule of innate immune system for the defense against bacterial infections. Three genes encoding chicken-type (c-type) lysozymes, C1-, C2-, C3-type, were obtained from tilapia Oreochromis aureus by RT-PCR and the RACE method. Catalytic and other conserved structure residues required for functionality were identified. The amino acid sequence identities between C1- and C2-type, C1- and C3-type, C2- and C3-type were 67.8%, 65.7% and 63.9%, respectively. Phylogenetic tree analyze indicated the three genes were firstly grouped to those of higher teleosteans, Pleuronectiformes and Tetraodontiformes fishes, and then clustered to those of lower teleosteans, Cypriniformes fishes. Bioinformatic analysis of mature peptide showed that the three genes possess typical sequence characteristics, secondary and tertiary structure of c-type lysozymes. The three tilapia c-type lysozymes mRNAs were mainly expressed in liver and muscle, and C1-type lysozyme also highly expressed in intestine. C1-type lysozyme mRNA was weakly expressed in stomach, C2- and C3-type mRNAs were weakly expressed in intestine. After bacterial challenge, up-regulation was obvious in kidney and spleen for C1-type lysozyme mRNA, while for C2- and C3-type lysozyme obvious increase were observed in stomach and liver, suggesting that C1-type lysozyme may mainly play roles in defense, while C2- and C3-type lysozyme mainly conduct digestive function against bacteria infection. All the three c-type recombinant lysozymes displayed lytic activity against Gram-negative and Gram-positive bacteria. These results indicated that three c-type lysozymes play important roles in the defense of O. aureus against bacteria infections.     

Functional Characterization of a c-type Lysozyme from Indian Shrimp Fenneropenaeus indicus

Lysozyme gene from Fenneropenaeus indicus was cloned, expressed in Escherichia coli and characterized. The cDNA consists of 477 base pairs and encodes amino acid sequence of 159 residues. F. indicus lysozyme had high identity (98 %) with Fenneropenaeus merguiensis and Fenneropenaeus chinensis and exhibits low to moderate identities with lysozymes of other invertebrates and vertebrates. This lysozyme is presumed to be chicken types as it possesses two catalytic and eight cysteine residues that are conserved across c-type lysozymes and a c-terminal extension, which is a characteristic of lysozymes from marine invertebrates. Further, the antimicrobial properties of the recombinant lysozyme from F. indicus were determined in comparison with recombinant hen egg white lysozyme. This exhibited high activity against a Gram-negative pathogenic bacterium Salmonella typhimurium and two fungal strains Pichia pastoris and Saccharomyces cerevisiae in turbidimetric assay. Distribution of lysozyme gene and protein in tissues of shrimps infected with white spot syndrome virus revealed that the high levels of lysozyme are correlated with low and high viral load in abdominal muscle and tail, respectively. In conclusion, lysozyme from F. indicus has a broad spectrum of antimicrobial properties, which once again emphasizes its role in shrimp innate immune response.     

Asp and Thr are critical for cation exchange mediated by NhaD, Na/H antiporter of Vibrio cholerae

The Vc-NhaD is an Na⁺/H⁺ antiporter from Vibrio cholerae belonging to a new family of bacterial Na⁺/H⁺ antiporters, the NhaD family. In the present work we mutagenized five conserved Asp and Glu residues and one conserved Thr residue to Ala in order to identify amino acids that are critical for the antiport activity. All mutations fall into two distinct groups: (i) four variants, Glu¹⁰⁰Ala, Glu²⁵¹Ala, Glu³⁴²Ala, and Asp³⁹³Ala, did not abolish antiport activity but shifted the pH optimum to more alkaline pH, and (ii) variants Asp³⁴⁴Ala, Asp³⁴⁴Asn, and Thr³⁴⁵Ala caused a complete loss of both Na⁺/H⁺ and Li⁺/H⁺ antiport activity whereas the Asp³⁴⁴Glu variant exhibited reduced Na⁺/H⁺ and Li⁺/H⁺ antiport activity. This is the first mutational analysis of the antiporter of NhaD type and the first demonstration of Thr residue being indispensable for Na⁺/H⁺ antiport. We discuss the possible role of Asp³⁴⁴ and Thr³⁴⁵ in the functioning of Vc-NhaD.     

Monitoring of Vibrio harveyi quorum sensing activity in real time during infection of brine shrimp larvae

Quorum sensing, bacterial cell-to-cell communication, has been linked to the virulence of pathogenic bacteria. Indeed, in vitro experiments have shown that many bacterial pathogens regulate the expression of virulence genes by this cell-to-cell communication process. Moreover, signal molecules have been detected in samples retrieved from infected hosts and quorum sensing disruption has been reported to result in reduced virulence in different host–pathogen systems. However, data on in vivo quorum sensing activity of pathogens during infection of a host are currently lacking. We previously reported that quorum sensing regulates the virulence of Vibrio harveyi in a standardised model system with gnotobiotic brine shrimp (Artemia franciscana) larvae. Here, we monitored quorum sensing activity in Vibrio harveyi during infection of the shrimp, using bioluminescence as a read-out. We found that wild-type Vibrio harveyi shows a strong increase in quorum sensing activity early during infection. In this respect, the bacteria behave remarkably similar in different larvae, despite the fact that only half of them survive the infection. Interestingly, when expressed per bacterial cell, Vibrio harveyi showed around 200-fold higher maximal quorum sensing-regulated bioluminescence when associated with larvae than in the culture water. Finally, the in vivo quorum sensing activity of mutants defective in the production of one of the three signal molecules is consistent with their virulence, with no detectable in vivo quorum sensing activity in AI-2- and CAI-1-deficient mutants. These results indicate that AI-2 and CAI-1 are the dominant signals during infection of brine shrimp.     

Structures of a Bifunctional Cell Wall Hydrolase CwlT Containing a Novel Bacterial Lysozyme and an NlpC/P60 dl-Endopeptidase

Tn916-like conjugative transposons carrying antibiotic resistance genes are found in a diverse range of bacteria. Orf14 within the conjugation module encodes a bifunctional cell wall hydrolase CwlT that consists of an N-terminal bacterial lysozyme domain (N-acetylmuramidase, bLysG) and a C-terminal NlpC/P60 domain (γ-d-glutamyl-l-diamino acid endopeptidase) and is expected to play an important role in the spread of the transposons. We determined the crystal structures of CwlT from two pathogens, Staphylococcus aureus Mu50 (SaCwlT) and Clostridium difficile 630 (CdCwlT). These structures reveal that NlpC/P60 and LysG domains are compact and conserved modules, connected by a short flexible linker. The LysG domain represents a novel family of widely distributed bacterial lysozymes. The overall structure and the active site of bLysG bear significant similarity to other members of the glycoside hydrolase family 23 (GH23), such as the g-type lysozyme (LysG) and Escherichia coli lytic transglycosylase MltE. The active site of bLysG contains a unique structural and sequence signature (DxxQSSES + S) that is important for coordinating a catalytic water. Molecular modeling suggests that the bLysG domain may recognize glycan in a similar manner to MltE. The C-terminal NlpC/P60 domain contains a conserved active site (Cys-His-His-Tyr) that appears to be specific to murein tetrapeptide. Access to the active site is likely regulated by isomerism of a side chain atop the catalytic cysteine, allowing substrate entry or product release (open state), or catalysis (closed state).     

Role of Lysozyme Inhibitors in the Virulence of Avian Pathogenic Escherichia coli

Lysozymes are key effectors of the animal innate immunity system that kill bacteria by hydrolyzing peptidoglycan, their major cell wall constituent. Recently, specific inhibitors of the three major lysozyme families occuring in the animal kingdom (c-, g- and i-type) have been discovered in Gram-negative bacteria, and it has been proposed that these may help bacteria to evade lysozyme mediated lysis during interaction with an animal host. Escherichia coli produces two inhibitors that are specific for c-type lysozyme (Ivy, Inhibitor of vertebrate lysozyme; MliC, membrane bound lysozyme inhibitor of c-type lysozyme), and one specific for g-type lysozyme (PliG, periplasmic lysozyme inhibitor of g-type lysozyme). Here, we investigated the role of these lysozyme inhibitors in virulence of Avian Pathogenic E. coli (APEC) using a serum resistance test and a subcutaneous chicken infection model. Knock-out of mliC caused a strong reduction in serum resistance and in in vivo virulence that could be fully restored by genetic complementation, whereas ivy and pliG could be knocked out without effect on serum resistance and virulence. This is the first in vivo evidence for the involvement of lysozyme inhibitors in bacterial virulence. Remarkably, the virulence of a ivy mliC double knock-out strain was restored to almost wild-type level, and this strain also had a substantial residual periplasmic lysozyme inhibitory activity that was higher than that of the single knock-out strains. This suggests the existence of an additional periplasmic lysozyme inhibitor in this strain, and indicates a regulatory interaction in the expression of the different inhibitors.     

Structural evidence for lack of inhibition of fish goose-type lysozymes by a bacterial inhibitor of lysozyme

It is known that bacteria contain inhibitors of lysozyme activity. The recently discovered Escherichia coli inhibitor of vertebrate lysozyme (Ivy) and its potential interactions with several goose-type (g-type) lysozymes from fish were studied using functional enzyme assays, comparative homology modelling, protein–protein docking, and molecular dynamics simulations. Enzyme assays carried out on salmon g-type lysozyme revealed a lack of inhibition by Ivy. Detailed analysis of the complexes formed between Ivy and both hen egg white lysozyme (HEWL) and goose egg white lysozyme (GEWL) suggests that electrostatic interactions make a dominant contribution to inhibition. Comparison of three dimensional models of aquatic g-type lysozymes revealed important insertions in the β domain, and specific sequence substitutions yielding altered electrostatic surface properties and surface curvature at the protein–protein interface. Thus, based on structural homology models, we propose that Ivy is not effective against any of the known fish g-type lysozymes. Docking studies suggest a weaker binding mode between Ivy and GEWL compared to that with HEWL, and our models explain the mechanistic necessity for conservation of a set of residues in g-type lysozymes as a prerequisite for inhibition by Ivy.     

Identification of Functional Amino Acid Residues Involved in Polyamine and Agmatine Transport by Human Organic Cation Transporter 2

Polyamine (putrescine, spermidine and spermine) and agmatine uptake by the human organic cation transporter 2 (hOCT2) was studied using HEK293 cells transfected with pCMV6-XL4/hOCT2. The Km values for putrescine and spermidine were 7.50 and 6.76 mM, and the Vmax values were 4.71 and 2.34 nmol/min/mg protein, respectively. Spermine uptake by hOCT2 was not observed at pH 7.4, although it inhibited both putrescine and spermidine uptake. Agmatine was also taken up by hOCT2, with Km value: 3.27 mM and a Vmax value of 3.14 nmol/min/mg protein. Amino acid residues involved in putrescine, agmatine and spermidine uptake by hOCT2 were Asp⁴²⁷, Glu⁴⁴⁸, Glu⁴⁵⁶, Asp⁴⁷⁵, and Glu⁵¹⁶. In addition, Glu⁵²⁴ and Glu⁵³⁰ were involved in putrescine and spermidine uptake activity, and Glu⁵²⁸ and Glu⁵⁴⁰ were weakly involved in putrescine uptake activity. Furthermore, Asp⁵⁵¹ was also involved in the recognition of spermidine. These results indicate that the recognition sites for putrescine, agmatine and spermidine on hOCT2 strongly overlap, consistent with the observation that the three amines are transported with similar affinity and velocity. A model of spermidine binding to hOCT2 was constructed based on the functional amino acid residues.