Effect of salt stress on the regulation of maize (Zea mays L.) genes involved in polyamine biosynthesis

A cDNA for spermidine synthase (SPDS), which converts putrescine to the higher polyamine spermidine using decarboxylated S-adenosylmethionine as a cofactor, was isolated from Zea mays leaves (Zmspds2A). Comparison of the deduced amino acid sequence revealed a high homology (81.9%25) with Oryza sativa SPDS2. RT-PCR analyses showed that Zmspds2A was equally expressed in leaves, stem and roots. In contrast, transcripts of other genes related to polyamine biosynthesis (Zmodc, adc and samdc) showed tissue-specific regulation. The effect of salt stress on the expression of all these genes in maize leaves exposed to NaCl solutions of different concentrations was analysed. Our results showed that only Zmodc and Zmspds2A were up-regulated by salt stress; whereas the other two genes were barely affected by this treatment. In addition to Zmspds2A, a second transcript encoding a maize spermidine synthase (Zmspds2B) that also became up-regulated by salt stress, was identified. Comparison of partial cDNA sequences of transcripts Zmspds2A and Zmspds2B with the corresponding genomic DNA region revealed the existence of alternative splicing mechanism, opening a new aspect in plant polyamine biosynthesis modulation under abiotic stress. © Springer 2006.

Alternative splicing; Polyamines; RT-PCR; Salt stress; Spermidine synthase; Zea mays Amines; Amino acids; Biosynthesis; DNA; Enzymes; Plants (botany); Sodium chloride; Solutions; Abiotic stress; Alternative splicing; Salt stress; Genes; Genes; Plants; Polyamines; Sodium Chloride; Oryza sativa; Zea mays

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