Lysozyme C, spleen isozyme

Two major types of lysozyme c (M and P) occur in the mouse genus, Mus, and have been purified from an inbred laboratory strain (C58/J) of M. domesticus. They differ in physical, catalytic, and antigenic properties as well as by amino acid replacements at 6 of 49 positions in the amino-terminal sequence. Comparisons with four other mammalian lysozymes c of known sequence suggest that M and P are related by a gene duplication that took place before the divergence of the rat and mouse lineages. M lysozyme is present in most tissues; achieves its highest concentration in the kidney, lung, and spleen; and corresponds to the lysozyme partially sequenced before from another strain of M. domesticus. In M. domesticus and several related species, P lysozyme was detected chiefly in the small intestine, where it is probably produced mainly by Paneth cells. A survey of M and P levels in 22 species of muroid rodents (from Mus and six other genera) of known phylogenetic relationships suggests that a mutation that derepressed the P enzyme arose about 4 million years ago in the ancestor of the housemouse group of species. Additional regulatory shifts affecting M and P levels have taken place along lineages leading to other muroid species. Our survey of 187 individuals of wild house mice and their closest allies reveals a correlation between latitude of origin and level of intestinal lysozyme.

Lysozyme as an important nonspecific immune factor, can kill bacteria by hydrolyzing β-1,4-glycosidic linkages of peptidoglycan layer, and plays an important role in innate immune response against pathogen infection. In the present study, we report molecular cloning, tissue distribution and functional characterization of the c-type and g-type lysozymes in Qihe crucian carp Carassius auratus (designated as Ca-clys and Ca-glys, respectively). The full-length of Ca-clys and Ca-glys cDNA were cloned using RT-PCR and RACE methods. Catalytic and other conserved residues, required for functionality, were identified by multiple sequence alignment and structure predicted. The findings indicating the Ca-clys with signal peptide sequence, while the Ca-glys without, imply that the two isozymes function in different sites of cell. Phylogenetic analysis revealed that Ca-clys and Ca-glys genes evolve at different rates. Moreover, spatial expression analysis showed that Ca-clys transcript was most abundant in kidney and least in gill. However, the expression level of Ca-glys was significantly lower compared with Ca-clys in various tissues, which was the most abundant in spleen and least in brain. After intraperitoneal injection with A. hydrophila and lipopolysaccharide (LPS), the mRNA levels of Ca-clys and Ca-glys were generally up-regulated in liver and gill, but indicated the different expression changes in spleen, kidney and head kidney. With regard to the lysozyme activity, it was showed that the total enzyme activities generally increased in liver, gill, spleen, and head kidney after stimulation. These results confirmed that both Ca-clys and Ca-glys play an important role in non-specific immunity after A. hydrophila invasion. In this study, it was speculated that expressions of Ca-clys and Ca-glys were regulated in different patterns against pathogens.

Lysozyme is a widely distributed enzyme located in the serum, skin mucus, and other organs of fish, which is responsible for catalyzing the hydrolysis of the cell walls of most bacteria. A c-type of lysozyme cDNA was cloned from a kidney cDNA library of the Japanese flounder (Paralichthys olivaceus). The cDNAs consisted of 612 bp, which coded for 143 amino acid residues. The deduced amino acid sequence of Japanese flounder c-type lysozyme possessed 72.9%, 57.4%, and 65.4% identities with rainbow trout, chicken, and human c-type lysozymes, respectively. Comparison of the c-type lysozymes showed that the catalytic residues, the residues binding to sugar chains, and cysteine residues were completely conserved. Northern blot analysis indicated that the c-type lysozyme gene is apparently transcribed in the head kidney, posterior kidney, spleen, brain, and ovary of healthy flounder. When flounder were experimentally infected with Edwardsiella tarda, quantities of the c-type lysozyme mRNA increased in the head kidney, spleen, and ovary of the flounder.