Leaf proteome characterization in the context of physiological and morphological changes in response to copper stress in sorghum.

Copper (Cu) is an essential micronutrient required for normal growth and development of plants; however, at elevated concentrations in soil, copper is also generally considered to be one of the most toxic metals to plant cells due to its inhibitory effects against many physiological and biochemical processes. In spite of its potential physiological and economical significance, molecular mechanisms under Cu stress has so far been grossly overlooked in sorghum. To explore the molecular alterations that occur in response to copper stress, the present study was performed in ten-day-old Cu-exposed leaves of sorghum seedlings. The growth characteristics were markedly inhibited, and ionic alterations were prominently observed in the leaves when the seedlings were exposed to different concentrations (0, 100, and 150 µM) of CuSO4. Using two-dimensional gels with silver staining, 643 differentially expressed protein spots (≥1.5-fold) were identified as either significantly increased or reduced in abundance. Of these spots, a total of 24 protein spots (≥1.5-fold) from Cu-exposed sorghum leaves were successfully analyzed by MALDI-TOF-TOF mass spectrometry. Of the 24 differentially expressed proteins from Cu-exposed sorghum leaves, 13 proteins were up-regulated, and 11 proteins were down-regulated. The abundance of most identified protein species, which function in carbohydrate metabolism, stress defense and protein translation, was significantly enhanced, while that of another protein species involved in energy metabolism, photosynthesis and growth and development were severely reduced. The resulting differences in protein expression patterns together with related morpho-physiological processes suggested that these results could help to elucidate plant adaptation to Cu stress and provide insights into the molecular mechanisms of Cu responses in C4 plants.

Morpho-Physiological and Proteome Level Responses to Cadmium Stress in Sorghum.

Cadmium (Cd) stress may cause serious morphological and physiological abnormalities in addition to altering the proteome in plants. The present study was performed to explore Cd-induced morpho-physiological alterations and their potential associated mechanisms in Sorghum bicolor leaves at the protein level. Ten-day-old sorghum seedlings were exposed to different concentrations (0, 100, and 150 µM) of CdCl2, and different morpho-physiological responses were recorded. The effects of Cd exposure on protein expression patterns in S. bicolor were investigated using two-dimensional gel electrophoresis (2-DE) in samples derived from the leaves of both control and Cd-treated seedlings. The observed morphological changes revealed that the plants treated with Cd displayed dramatically altered shoot lengths, fresh weights and relative water content. In addition, the concentration of Cd was markedly increased by treatment with Cd, and the amount of Cd taken up by the shoots was significantly and directly correlated with the applied concentration of Cd. Using the 2-DE method, a total of 33 differentially expressed protein spots were analyzed using MALDI-TOF/TOF MS. Of these, treatment with Cd resulted in significant increases in 15 proteins and decreases in 18 proteins. Major changes were absorbed in the levels of proteins known to be involved in carbohydrate metabolism, transcriptional regulation, translation and stress responses. Proteomic results revealed that Cd stress had an inhibitory effect on carbon fixation, ATP production and the regulation of protein synthesis. Our study provides insights into the integrated molecular mechanisms involved in responses to Cd and the effects of Cd on the growth and physiological characteristics of sorghum seedlings. We have aimed to provide a reference describing the mechanisms involved in heavy metal damage to plants.

Analysis of soybean root proteins affected by gibberellic acid treatment under flooding stress.

Flooding is a serious abiotic stress for soybean because it restricts growth and reduces grain yields. To investigate the effect of gibberellic acid (GA) on soybean under flooding stress, root proteins were analyzed using a gel-free proteomic technique. Proteins were extracted from the roots of 4-days-old soybean seedlings exposed to flooding stress in the presence and absence of exogenous GA3 for 2 days. A total of 307, 324, and 250 proteins were identified from untreated, and flooding-treated soybean seedlings without or with GA3, respectively. Secondary metabolism- and cell-related proteins, and proteins involved in protein degradation/synthesis were decreased by flooding stress; however, the levels of these proteins were restored by GA3 supplementation under flooding. Fermentation- and cell wall-related proteins were not affected by GA3 supplementation. Furthermore, putative GA-responsive proteins, which were identified by the presence of a GA-responsive element in the promoter region, were less abundant by flooding stress; however, these proteins were more abundant by GA3 supplementation under flooding. Taken together, these results suggest that GA3 affects the abundance of proteins involved in secondary metabolism, cell cycle, and protein degradation/synthesis in soybeans under flooding stress.

Identification of nuclear proteins in soybean under flooding stress using proteomic technique.

Flooding stress restricts soybean growth, it results in decrease the production. In this report, to understand how nuclear proteins in soybean affected by flooding, abundance changes of those proteins was analyzed. Nuclear proteins were extracted from the root tips of soybean treated with or without flooding stress. The extracted proteins were analyzed using a label-free quantitative proteomic technique. Of a total of 94 nuclear proteins that were found to be responsive to flooding, the 19 and 75 proteins were increased and decreased, respectively. The identified flooding-responsive proteins were functionally classified, revealing that 8 increased proteins changed in protein synthesis, posttranslational modification, and protein degradation, while 34 decreased proteins were involved in transcription, RNA processing, DNA synthesis, and chromatin structure maintenance. Among these proteins, those whose levels changed more than 10 fold included two poly ADP-ribose polymerases and a novel G-domain-containing protein that might be involved in RNA binding. The mRNA expression levels of these three proteins indicated a similar tendency to their protein abundance changes. These results suggest that acceleration of protein poly-ADP-ribosylation and suppression of RNA metabolism may be involved in root tip of soybean under flooding stress.

Proteome analysis of roots of wheat seedlings under aluminum stress.

The root apex is considered the first sites of aluminum (Al) toxicity and the reduction in root biomass leads to poor uptake of water and nutrients. Aluminum is considered the most limiting factor for plant productivity in acidic soils. Aluminum is a light metal that makes up 7 % of the earth's scab dissolving ionic forms. The inhibition of root growth is recognized as the primary effect of Al toxicity. Seeds of wheat cv. Keumkang were germinated on petridish for 5 days and then transferred hydroponic apparatus which was treated without or with 100 and 150 µM AlCl3 for 5 days. The length of roots, shoots and fresh weight of wheat seedlings were decreased under aluminum stress. The concentration of K(+), Mg(2+) and Ca(2+) were decreased, whereas Al(3+) and P2O5 (-) concentration was increased under aluminum stress. Using confocal microscopy, the fluorescence intensity of aluminum increased with morin staining. A proteome analysis was performed to identify proteins, which are responsible to aluminum stress in wheat roots. Proteins were extracted from roots and separated by 2-DE. A total of 47 protein spots were changed under Al stress. Nineteen proteins were significantly increased such as sadenosylmethionine, oxalate oxidase, malate dehydrogenase, cysteine synthase, ascorbate peroxidase and/or, 28 protein spots were significantly decreased such as heat shock protein 70, O-methytransferase 4, enolase, and amylogenin. Our results highlight the importance and identification of stress and defense responsive proteins with morphological and physiological state under Al stress.

Analysis of response mechanism in soybean under low oxygen and flooding stresses using gel-base proteomics technique.

A proteomics approach was used to analyze the response mechanism in soybean seedlings under low oxygen and flooding stresses. Three-day-old soybean seedlings were subjected to low oxygen and flooding stresses. Growth of root was suppressed in both stresses with more extent of suppression in flooded seedlings at 3 and 6 days following the treatments. Proteins were extracted from roots and separated by two-dimensional polyacrylamide gel electrophoresis. Of total 1,233 protein spots, 27 protein spots were commonly changed under low oxygen and flooding stresses; while the differential change in 4 and 18 protein spots was specific to low oxygen and flooding stresses, respectively. Proteins related to metabolism and energy were increased; while protein destination/storage related proteins were decreased commonly under low oxygen and flooding stresses. Protein specie, TCP domain class transcription factor was decreased specifically under low oxygen stress; while decrease of nine proteins related to metabolism, protein destination/storage and disease/defense was specific in flooded seedlings. The decrease in majority of the proteins related to protein destination/storage specifically in flooded seedlings implies the misfolding of proteins resulting in flooded injuries in an independent way of oxygen deprivation. These results suggest that decrease in proteins related to protein destination/storage and disease/defense causes more growth suppression in soybean seedlings under flooding stress compared to low oxygen stress.