N1-aminopropylagmatine, a new polyamine produced as a key intermediate in polyamine biosynthesis of an extreme thermophile, Thermus thermophilus

Structure and Mechanism of Spermidine Synthases

Aminopropyltransferases transfer aminopropyl groups from decarboxylated S-adenosylmethionine to amine acceptors, forming polyamines. Structural and biochemical studies have been carried out with the human spermidine synthase, which is highly specific for putrescine as the amine acceptor, and the Thermotoga maritima spermidine synthase, which prefers putrescine but is more tolerant of other substrates. Comparison of the structures of the human spermidine synthase with both substrates and products with the known structure of T. maritima spermidine synthase complexed to a multisubstrate analogue inhibitor and analysis of the properties of site-directed mutants provide a general mechanistic hypothesis for the aminopropyl transfer reaction. The studies also provide a structural basis for the specificity of the spermidine synthase subclass of the aminopropyltransferase family.

Unique polyamines produced by an extreme thermophile, Thermus thermophilus

Recent research progress on polyamines in extreme thermophiles is reviewed. Extreme thermophiles produce two types of unique polyamines; one is longer polyamines such as caldopentamine and caldohexamine, and the other is branched polyamines such as tetrakis(3-aminopropyl)ammonium. The protein synthesis catalyzed by a cell-free extract of Thermus thermophilus, an extreme thermophile, required the presence of a polyamine and the highest activity was found in the presence of tetrakis(3-aminopropyl)ammonium. In vitro experiments, longer polyamines efficiently stabilized double stranded nucleic acids and a branched polyamine, tetrakis(3-aminropyl)ammonium, stabilized stem-and-loop structures. In T. thermophilus, polyamines are synthesized from arginine by a new metabolic pathway; arginine is converted to agmatine and then agmatine is aminopropylated to N(1)-aminopropylagmatine which is converted to spermidine by an enzyme coded by a gene homologous to speB (a gene for agmatinase). In this new pathway spermidine is not synthesized from putrescine. Reverse genetic studies indicated that the unique polyamines are synthesized from spermidine.

Aminopropyltransferases: Function, Structure and Genetics

Aminopropyltransferases use decarboxylated S-adenosylmethionine as an aminopropyl donor and an amine acceptor to form polyamines. This review covers their structure, mechanism of action, inhibition, regulation and function. The best known aminopropyltransferases are spermidine synthase and spermine synthase but other members of this family including an N(1)-aminopropylagmatine synthase have been characterized. Spermidine synthase is an essential gene in eukaryotes and is very widely distributed. Key regions in the active site, which are very highly conserved, were identified by structural studies with spermidine synthase from Thermotoga maritima bound to S-adenosyl-1,8-diamino-3-thiooctane, a multisubstrate analog inhibitor. A general mechanism for catalysis by aminopropyltransferases can be proposed based on these studies. Spermine synthase is less widely distributed and is not essential for growth in yeast. However, Gy mice lacking spermine synthase have multiple symptoms including a profound growth retardation, sterility, deafness, neurological abnormalities and a propensity to sudden death, which can all be prevented by transgenic expression of spermine synthase. A large reduction in spermine synthase in human males due to a splice site variant causes Snyder-Robinson syndrome with mental retardation, hypotonia and skeletal abnormalities.