Metal tolerance protein family members are involved in Mn homeostasis through internal compartmentation and exocytosis in Brassica napus

Abstract

Mineral elements, including manganese (Mn), are indispensable for plant growth and development. However, plants cultivated on acidic soils are vulnerable to Mn2+ toxicity due to a prevalently phytotoxic level of Mn2+. Metal tolerance proteins (MTPs) were demonstrated to be essential for metal homeostasis and tolerance in different plant species. In this study, we present the functional characteristics of BnMTP8 and BnMTP9 from Brassica napus. The expression level of BnMTP8 was most prominent in rapeseed roots and was only markedly up-regulated in shoots by excess Mn2+. In contrast, BnMTP9 was most abundant in shoots. Expression of BnMTP8 and BnMTP9 in Saccharomyces cerevisiae compensated the Mn2+-hypersensitivity of Δpmr1 by increasing metal sequestration and efflux, respectively. In addition, heteroexpression of BnMTP8 restored Mn2+ tolerance of Arabidopsis mtp8 mutants and increased Mn2+ accumulation in tissues and leaf vacuoles. Expression of BnMTP9 in Arabidopsis mtp11 mutants restored their growth and reduced Mn2+ concentrations in mesophyll protoplasts and tissues upon elevated levels of Mn2+. Transient expression of GFP-fusion constructs in protoplasts showed that BnMTP8 and BnMTP9 localize to pre-vacuolar compartments and the trans-Golgi network, respectively. However, high extracellular Mn2+ in Arabidopsis root cells triggered BnMTP8-GFP relocation to the tonoplast and BnMTP9-GFP relocation to the plasma membrane, suggesting that these two proteins are involved in vacuolar Mn2+ sequestration and cytosolic Mn2+ export, respectively. Taken together, these findings indicate that BnMTP8 and BnMTP9 load Mn2+ into vesicles for subsequent delivery to the vacuole or secretion into extracellular spaces, respectively, thereby cooperating to maintain Mn2+ homeostasis in the roots and shoots of rapeseed.