Abstract: | A new column chromatography procedure, based on ion exchange, chromatofocusing, and reverse phase high pressure liquid chromatography was employed to isolate the two main proteinaceous, toxic, cytolytic, pore-forming factors from the secretion of the Red Sea Moses sole Pardachirus marmoratus. Pardaxin I, comprising 10% of the gland secretion proteins, was shown to be 5-10 times more toxic, cytolytic, and active in membrane pore formation than pardaxin II (8% of gland secretion proteins). Gel electrophoresis, amino acid analysis, and NH2-terminal amino acid sequence reveals a high degree of homogeneity and resemblance between the two toxins. They are rich in aspartic acid, serine, glycine, and alanine and devoid of arginine, tyrosine, and tryptophan. Their NH2-terminal residue sequence was found to be NH2-Gly-Phe-Phe. Their hydrophobicity is evident from chromatographic behavior on a hydrophobic matrix, presence of 9 successive hydrophobic residues at the NH2 terminus, and a decrease in drop size during elution of active fractions during chromatographic purification. The minimal molecular weight of pardaxin I is about 3500 as determined by sodium dodecyl sulfate gel electrophoresis and amino acid analyses. It is composed of 35 amino acids and is free of carbohydrate and sialic acid residues. Mass spectrometry of the ethyl acetate extract of the gland secretion and purified toxin reveals the presence of sterols in the secretion but their absence in the purified toxins. Pardaxin I was iodinated without affecting its chemical and pore-forming properties. It binds to liposomes of different phospholipid compositions. In hyperpolarized unilamellar liposomes, pardaxin I produced a fast, nonspecific permeabilization and in multilamellar liposomes, a slow, cation-specific pore. It is suggested that pardaxins exert their effects due to their hydrophobic and pore-formation properties. |