Agnieszka MIEREK ADAMSKA, Zuzanna ZNAJEWSKA, Anna GOC, Grazyna Barbara DABROWSKA

Molecular cloning and characterization of Ipomoea nil metallothioneins

Metallothioneins are low-molecular-weight, cysteine-rich proteins able to bind a variety of heavy metal ions. They are involvedin the maintenance of micronutrient homeostasis and detoxification of nonessential heavy metals. Plant metallothioneins are classifiedinto four main types based on the number and arrangement of cysteine residues. Here we report on the isolation of novel complementaryand genomic DNA from a model for a short-day plant, Ipomoea nil (Japanese morning glory), that encodes 66- or 76-amino acid residueproteins. In silico and phylogenetic analysis of putative amino acid sequences confirmed that these 66- and 76-amino acid residueproteins belong, respectively, to type 1 and type 2 plant metallothioneins. In genomic sequences of the analyzed metallothioneins,two introns were recognized, one of them located at an evolutionary conserved position. Furthermore, examination of the expressionpatterns of cloned metallothioneins in I. nil organs and in cotyledons in response to copper and zinc exposure suggested that theirphysiological functions could be diversified. Moreover, the observed changes of analyzed I. nil metallothioneins in response to heavymetal treatment indicate that InMT1 may be involved in copper homeostasis in I. nil cotyledons. The role of InMT2 in micronutrienthomeostasis remains questionable.

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