It has previously been reported that norspermidine, one of the unusual polyamines, is present in Vibrio species. To expand this observation, the cellular polyamine compositions of additional species and strains in the family Vibrionaceae (Vibrio, Photobacterium, Listonella, and Shewanella) as well as Aeromonas species and Plesiomonas shigelloides, which have been proposed to be excluded from Vibrionacea, were determined by using gas-liquid chromatography. Some Vibrio species previously reported were reexamined under the same conditions, and their results are included in this report. Norspermidine was detected as a major triamine in 23 of 24 Vibrio species, all of 4 Listonella species, and 3 of 5 Photobacterium species. Vibrio costicola, Photobacterium fischeri, and Photobacterium phosphoreum contained no norspermidine. Listonella species were indistinguishable from Vibrio species in their polyamine profiles. However, Schewanella putrefaciens ATCC 8071, formerly allocated in the genus Alteromonas, contained no norspermidine, and its polyamine profile was similar to those of four Aeromonas species, in which putrescine was exclusively found. Plesiomonas shigelloides was very similar to Escherichia coli in that putrescine and spermidine were predominant polyamines. Our data indicate that the occurrence of norspermidine may be very helpful as a generic marker in identification and classification of Vibrio and Listonella species. A gas-liquid chromatographic method with a nitrogen-selective detector was presented for rapid and sensitive detection of cellular norspermidine.
The effects of various synthetic triamines having a general structure, H2N(CH2)xNH(CH2)yNH2, where x = 2-5 and y = 2-8 (abbreviated, x-y; with 3-4 being spermidine itself), on poly(U)-directed polypeptide synthesis of Escherichia coli and on growth of its polyamine-requiring mutants were examined in comparison with those of spermidine. Except for 2-2 and 2-3, all of the triamines stimulated more or less polypeptide synthesis at suboptimal Mg2+ concentrations, but the Mg2+ concentration required for the maximal stimulatory effect was different for each triamine. The degree of maximal stimulation caused by 3-3 (norspermidine), 4-4 (homospermidine), or 4-5 was nearly comparable with that by spermidine. The acetylspermidines were inactive, however, they inhibited the spermidine-stimulated polyphenylalanine synthesis. Many of the triamines examined reduced the ratio of leucine to phenylalanine incorporation into polypeptides during poly(U)-directed translation, and the degree of this effect did not necessarily correspond with that of the stimulatory effect. Moreover, 2-4, 2-5, 3-3 and 4-4 could stimulate the growth of a polyamine auxotroph of E. coli, MA 261, as effectively as did spermidine. However, 3-3 was the only triamine which could fully replaced spermidine in promoting growth of a mutant strain, KK 101, which is more dependent on polyamines than MA 261. Thus, these results demonstrated that some synthetic triamines were as active as spermidine in eliciting these effects, and also that there were some differences among these effects in the structural requirement for triamine.
N 1‐Acetylnorspermidine [CH3CONH(CH2)3NH(CH2)3NH3] was identified in Vibrio parahaemolyticus, which contains norspermidine as a major polyamine. This is the first example for the natural occurence of monoacetylated unusual polyamine. The N1‐acetylnorspermidine content was the highest 4 h after inoculation. Incubation of norspermidine and acetyl CoA with a cell extract from V. parahaemolyticus produced N1‐acetylnorspermidine. A remarkable increase in specific activity of the acetyltransferase was observed at the exponential phase of growth. Spermidine also served as a substrate for the enzyme, with the formation of two isomers of the acetylspermidines (N1‐acetylspermidine was predominant), but the reaction rate was less than 50% of that with norspermidine. These results suggest that norspermidine in V. parahaemolyticus may be associated with the cell growth and its role may be controlled through acetylation, as reported for spermidine in Escherichia coli.
The effect of norspermidine and its structurally related triamines on the cell-free polyphenylalanine synthesizing system from Vibrio parahaemolyticus was examined in connection with the requirement of the system for monovalent cation . In the absence of norspermidine, the maximal incorporation of [14C] phenylalanine into hot trichloroacetic acid insoluble material was observed under ionic conditions of 12 mm Mg2+ and 50 mm NH4+. K+ could partially substitute for NH4+ , but Na+ could not. The addition of norspermidine to the polyphenylalanine synthetic reaction mixture not only lowered the optimal Mg2+ concentration , but it also stimulated the polyphenylalanine synthesis up to 2-fold with no significant increase in misincorporation of [ 14C]leucine.Other triamines having one or two methylene chains more than norspermidine were also effective in eliciting these effects . Furthermore, Na could not support the polyphenylalanine synthesis even in the presence of norspermidine and, on the contrary, inhibited the polyphenylalanine synthesis induced by NH4+ regardless of whether norspermidine was present or not . These findings are discussed in comparison with the properties of other bacterial cell-free systems.
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