Global Phosphoproteomic Analysis Reveals the Defense and Response Mechanisms of Jatropha Curcas Seedling under Chilling Stress.

As a promising energy plant for biodiesel, Jatropha curcas is a tropical and subtropical shrub and its growth is affected by one of major abiotic stress, chilling. Therefore, we adopt the phosphoproteomic analysis, physiological measurement and ultrastructure observation to illustrate the responsive mechanism of J. curcas seedling under chilling (4 °C) stress. After chilling for 6 h, 308 significantly changed phosphoproteins were detected. Prolonged the chilling treatment for 24 h, obvious physiological injury can be observed and a total of 332 phosphoproteins were examined to be significantly changed. After recovery (28 °C) for 24 h, 291 phosphoproteins were varied at the phosphorylation level. GO analysis showed that significantly changed phosphoproteins were mainly responsible for cellular protein modification process, transport, cellular component organization and signal transduction at the chilling and recovery periods. On the basis of protein-protein interaction network analysis, phosphorylation of several protein kinases, such as SnRK2, MEKK1, EDR1, CDPK, EIN2, EIN4, PI4K and 14-3-3 were possibly responsible for cross-talk between ABA, Ca2+, ethylene and phosphoinositide mediated signaling pathways. We also highlighted the phosphorylation of HOS1, APX and PIP2 might be associated with response to chilling stress in J. curcas seedling. These results will be valuable for further study from the molecular breeding perspective.

Phosphoproteomic Analysis of Paper Mulberry Reveals Phosphorylation Functions in Chilling Tolerance.

Paper mulberry is a valuable woody species with a good chilling tolerance. In this study, phosphoproteomic analysis, physiological measurement, and mRNA quantification were employed to explore the molecular mechanism of chilling (4 °C) tolerance in paper mulberry. After chilling for 6 h, 427 significantly changed phosphoproteins were detected in paper mulberry seedlings without obvious physiological injury. When obvious physiological injury occurred after chilling for 48 h, a total of 611 phosphoproteins were found to be significantly changed at the phosphorylation level. Several protein kinases, especially CKII, were possibly responsible for these changes according to conserved sequence analysis. The results of Gene Ontology analysis showed that phosphoproteins were mainly responsible for signal transduction, protein modification, and translation during chilling. Additionally, transport and cellular component organization were enriched after chilling for 6 and 48 h, respectively. On the basis of the protein-protein interaction network analysis, a protein kinase and phosphatases hub protein (P1959) were found to be involved in cross-talk between Ca2+, BR, ABA, and ethylene-mediated signaling pathways. We also highlighted the phosphorylation of BpSIZ1 and BpICE1 possibly impacted on the CBF/DREB-responsive pathway. From these results, we developed a schematic for the chilling tolerance mechanism at phosphorylation level.

Cloning two P5CS genes from bioenergy sorghum and their expression profiles under abiotic stresses and MeJA treatment.

Sweet sorghum (Sorghum bicolor (Linn.) Moench) has promise as a bioenergy feedstock in China and other countries for its use in the production of ethanol as the result of its high fermentable sugar accumulation in stems. To boost biofuel production and extend its range, we seek to improve its stress tolerance. Proline acts as an osmolyte that accumulates when plants are subjected to abiotic stress. P5CS (Δ1-pyrroline-5-carboxylate synthetase) is a key regulatory enzyme that plays a crucial role in proline biosynthesis. We isolated two closely related P5CS genes from sweet sorghum, designated SbP5CS1 (GenBank accession number: GQ377719) and SbP5CS2 (GenBank accession number: GQ377720), which are located on chromosome 3 and 9 and encode 729 and 716 amino acid polypeptides, respectively. The homology between the two sweet sorghum P5CS genes was 76%. Promoter analysis of the two P5CS genes revealed that both sequences not only contained the expected cis regulatory regions such as TATA and CAAT boxes, but also had many stress response elements. Expression analysis revealed that SbP5CS1 and SbP5CS2 transcripts were up-regulated after treatment of 10-day-old seedlings of sweet sorghum with drought, salt (250mM NaCl) and MeJA (10µM). The expression levels of the both SbP5CS genes were significantly increased after 3-day drought stress. Under high salt treatment, peak SbP5CS1 expression was detected at 4h and 8h for SbP5CS2 in roots, while the trends of expression were nearly identical in leaves. In contrast, under drought and high salt stress, the up-regulated expression of SbP5CS1 was higher than that of SbP5CS2. When the seedlings were exposed to MeJA, rapid transcript induction of SbP5CS1 was detected at 2h in leaves, and the SbP5CS2 expression level increase was detected at 4h post-treatment. SbP5CS1 and SbP5CS2 also show different temporal and spatial expression patterns. SbP5CS2 gene was ubiquitously expressed whereas SbP5CS1 was mainly expressed in mature vegetative and reproductive organs. Proline concentration increased after stress application and was correlated with SbP5CS expression. Our results suggest that the SbP5CS1 and SbP5CS2 are stress inducible genes but might play non-redundant roles in plant development. The two genes could have the potential to be used in improving stress tolerance of sweet sorghum and other bioenergy feedstocks.