Response of ATP sulfurylase and serine acetyltransferase towards cadmium in hyperaccumulator Sedum alfredii Hance

We studied the responses of the activities of adenosine-triphosphate (ATP) sulfurylase (ATPS) and serine acetyltransferase (SAT) to cadmium (Cd) levels and treatment time in hyperaccumulating ecotype (HE) Sedum alfredii Hance, as compared with its non-hyperaccumulating ecotype (NHE). The results show that plant growth was inhibited in NHE but promoted in HE when exposed to high Cd level. Cd concentrations in leaves and shoots rapidly increased in HE rather than in NHE, and they became much higher in HE than in NHE along with increasing treatment time and Cd supply levels. ATPS activity was higher in HE than in NHE in all Cd treatments, and increased with increasing Cd supply levels in both HE and NHE when exposed to Cd treatment within 8 h. However, a marked difference of ATPS activity between HE and NHE was found with Cd treatment for 168 h, where ATPS activity increased in HE but decreased in NHE. Similarly, SAT activity was higher in HE than in NHE at all Cd treatments, but was more sensitive in NHE than in HE. Both ATPS and SAT activities in NHE leaves tended to decrease with increasing treatment time after 8 h at all Cd levels. The results reveal the different responses in sulfur assimilation enzymes and Cd accumulation between HE and NHE. With increasing Cd stress, the activities of sulfur assimilation enzymes (ATPS and SAT) were induced in HE, which may contribute to Cd accumulation in the hyperaccumulator Sedum alfredii Hance.

Control of sulfate concentration by miR395-targeted APS genes in Arabidopsis thaliana

Sulfur nutrition is crucial for plant growth and development,as well as crop yield and quality.Inorganic sulfate in the soil is the major sulfur source for plants.After uptake,sulfate is activated by ATP sulfurylase,and then gets assimilated into sulfur-containing metabolites.However,the mechanism of regulation of sulfate levels by ATP sulfurylase is unclear.Here,we investigated the control of sulfate levels by miR395-mediated regulation of APS1/3/4.Sulfate was over-accumulated in the shoots of miR395 over-expression plants in which the expression of the APS1,APS3,and APS4 genes was suppressed.Accordingly,reduced expression of miR395 caused a decline of sulfate concentration.In agreement with these results,over-expression of the APS1,APS3,and APS4 genes led to the reduction of sulfate levels.Differential expression of these three APS genes in response to sulfate starvation implied that they have different functions.Further investigation revealed that the regulation of sulfate levels mediated by miR395 depends on the repression of its APS targets.Unlike the APS1,APS3,and APS4 genes,which encode plastid-localized ATP sulfurylases,the APS2 gene encodes a cytosolic version of ATP sulfurylase.Genetic analysis indicated that APS2 has no significant effect on sulfate levels.Our data suggest that miR395-targeted APS genes are key regulators of sulfate concentration in leaves.