Abstract
Plant copper P1B-type ATPases appear to be crucial for maintaining copper homeostasis within plant cells, but until now they have been studied mostly in model plant systems. Here, we present the molecular and biochemical characterization of two cucumber copper ATPases, CsHMA5.1 and CsHMA5.2, indicating a different function for HMA5-like proteins in different plants. When expressed in yeast, CsHMA5.1 and CsHMA5.2 localize to the vacuolar membrane and are activated by monovalent copper or silver ions and cysteine, showing different affinities to Cu(+) (Km ∼1 or 0.5 μM, respectively) and similar affinity to Ag(+) (Km ∼2.5 μM). Both proteins restore the growth of yeast mutants sensitive to copper excess and silver through intracellular copper sequestration, indicating that they contribute to copper and silver detoxification. Immunoblotting with specific antibodies revealed the presence of CsHMA5.1 and CsHMA5.2 in the tonoplast of cucumber cells. Interestingly, the root-specific CsHMA5.1 was not affected by copper stress, whereas the widely expressed CsHMA5.2 was up-regulated or down-regulated in roots upon copper excess or deficiency, respectively. The copper-induced increase in tonoplast CsHMA5.2 is consistent with the increased activity of ATP-dependent copper transport into tonoplast vesicles isolated from roots of plants grown under copper excess. These data identify CsHMA5.1 and CsHMA5.2 as high affinity Cu(+) transporters and suggest that CsHMA5.2 is responsible for the increased sequestration of copper in vacuoles of cucumber root cells under copper excess.
Highlights
Plant copper HMA5-like ATPases have not been biochemically characterized yet
CsHMA5.1, which is more closely related to AtHMA5, was found on chromosome 5 (ACHR02000005.1), whereas CsHMA5.2 is located on chromosome 4 (ACHR02000004.1)
CsHMA5.2 transcript and protein levels were markedly reduced or elevated upon copper deficiency or copper excess, respectively. These findings suggest that CsHMA5.1 is a constitutive root-specific vacuolar copper transporter unaffected during copper stress, whereas CsHMA5.2 functions in copper detoxification under copper excess
Summary
Plant copper HMA5-like ATPases have not been biochemically characterized yet. Conclusion: HMA5-like ATPases may contribute to vacuolar sequestration of copper excess in plant cells. OsHMA5 was shown to be localized in the plasma membrane [18] These observations suggest that in plants HMA5 is involved in root-to-shoot translocation of copper and protects plant roots from copper toxicity [17]. Using yeast to produce the functional CsHMA5.1 and CsHMA5.2 proteins, we provide the first enzymatic characterization of HMA5-like copper ATPases in plants and show that CsHMA5.1 and CsHMA5.2 act as high affinity vacuolar Cuϩ transporters. The data suggest different biological roles of cucumber CsHMA5.1 and CsHMA5.2 and reveal differences between the function of homologous HMA5 proteins from cucumber, rice, and A. thaliana
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
