Hye-Yeon Seok

Overexpression of Arabidopsis ZEP enhances tolerance to osmotic stress.

Zeaxanthin epoxidase (ZEP) is an enzyme important in ABA biosynthesis and in the xanthophyll cycle. ABA, a plant hormone, is a key molecule that regulates plant responses to abiotic stress, such as drought and salinity, and is required for stress tolerance. To investigate the biological roles of the Arabidopsis thaliana ZEP gene (AtZEP) in stress response, we generated transgenic plants overexpressing the AtZEP gene and analyzed their responses to salt and drought stresses. AtZEP-overexpressing plants exhibited more vigorous growth under high salt and drought treatments than wild-type plants. In addition to enhanced de novo ABA biosynthesis, AtZEP-overexpressing plants also exhibited much higher expression of the endogenous stress-responsive genes RD29A and Rab18 than wild-type plants under salt stress. Moreover, the stomatal aperture of the AtZEP-overexpressing plants was smaller than wild-type plants after exposure to light. Our results therefore indicated that AtZEP plays important roles in response to osmotic stress.

AtERF71/HRE2 transcription factor mediates osmotic stress response as well as hypoxia response in Arabidopsis

Various transcription factors are involved in the response to environmental stresses in plants. In this study, we characterized AtERF71/HRE2, a member of the Arabidopsis AP2/ERF family, as an important regulator of the osmotic and hypoxic stress responses in plants. Transcript level of AtERF71/HRE2 was highly increased by anoxia, NaCl, mannitol, ABA, and MV treatments. aterf71/hre2 loss-of-function mutants displayed higher sensitivity to osmotic stress such as high salt and mannitol, accumulating higher levels of ROS under high salt treatment. In contrast, AtERF71/HRE2-overexpressing transgenic plants showed tolerance to salt and mannitol as well as flooding and MV stresses, exhibiting lower levels of ROS under high salt treatment. AtERF71/HRE2 protein was localized in the nucleus, and the C-terminal region of AtERF71/HRE2 was required for transcription activation activity. Taken together, our results suggest that AtERF71/HRE2 might function as a transcription factor involved in the response to osmotic stress as well as hypoxia.

EMF1 Interacts with EIP1, EIP6 or EIP9 Involved in the Regulation of Flowering Time in Arabidopsis

The EMBRYONIC FLOWER (EMF) 1 gene has been shown to be necessary for maintenance of vegetative development. To investigate the molecular mechanism of EMF1-mediated plant development, we screened EMF1-interacting proteins and identified 11 candidate proteins using the yeast two-hybrid system. Among the candidate genes, three EMF1-Interacting Protein (EIP) genes, EIP1, EIP6 and EIP9, are predicted to encode a WNK (with-no-lysine) kinase, a B-box zinc-finger protein and a DnaJ-domain protein, respectively. The expression patterns of EIP1, EIP6 and EIP9 were similar to that of EMF1, and EMF1-EIP1, EMF1-EIP6 and EMF1-EIP9 heterodimers were localized in the nucleus. In addition, eip1, eip6 and eip9 mutants flowered early and showed increased expression of flowering-time and floral organ identity genes, while EIP1-, EIP6- and EIP9-overexpressing transgenic plants showed late flowering phenotypes. Our results suggest that EMF1 interacts with EIP1, EIP6 and EIP9 during vegetative development to regulate flowering time in Arabidopsis.

Arabidopsis MKKK20 is involved in osmotic stress response via regulation of MPK6 activity

Plants have developed various regulatory pathways to adapt to environmental stresses. In this study, we identified Arabidopsis MKKK20 as a regulator in the response to osmotic stress. mkkk20 mutants were found to be sensitive to high concentration of salt and showed higher water loss rates than wild-type (WT) plants under dehydration conditions. In addition, mkkk20 mutants showed higher accumulation of superoxide, a reactive oxygen species (ROS), compared to WT plants under high salt condition. In contrast, transgenic plants overexpressing MKKK20 displayed tolerance to salt stress. MKKK20 transcripts were increased by the treatments with NaCl, mannitol, MV, sorbitol, and cold, suggesting that MKKK20 is involved in the response to osmotic, ROS, and cold stresses. In-gel kinase assay showed that MKKK20 regulates the activity of MPK6 under NaCl, cold, and H2O2 treatments. Taken together, our results suggest that MKKK20 might be involved in the response to various abiotic stresses, especially osmotic stress, through its regulation of MPK6 activity.

Rice ternary MADS protein complexes containing class B MADS heterodimer

To investigate ternary MADS protein complexes involved in the regulation of floral organ development in rice, we identified MADS proteins interacting with the class B MADS heterodimers, OsMADS16-OsMADS4 and OsMADS16-OsMADS2, using yeast three-hybrid assay. The class B heterodimers interacted with OsMADS6, 7, 8, 14 and 17, which belong to AP1-like, SEP-like or AGL6-like MADS proteins, generating ternary complexes. The entire region of the K and C domains of OsMADS4 was required for the formation of the OsMADS16-OsMADS4-OsMADS6 and OsMADS16-OsMADS4-OsMADS7 ternary complexes. Analysis results of transgenic plants concomitantly suppressing OsMADS4 and OsMADS6, together with the results of previous studies, suggest that the OsMADS16-OsMADS4-OsMADS6 ternary complex plays an important role in floral development, especially lodicule development.

Arabidopsis AtNAP functions as a negative regulator via repression of AREB1 in salt stress response

AbstractMain conclusionAtNAP, anArabidopsisNAC transcription factor family gene, functions as a negative regulator via transcriptional repression ofAREB1in salt stress response. AtNAP is an NAC family transcription factor in Arabidopsis and is known to be a positive regulator of senescence. However, its exact function and underlying molecular mechanism in stress responses are not well known. Here, we investigated functional roles of AtNAP in salt stress response. AtNAP expression significantly increased at the seedling stage, with higher expression in both shoots and roots under NaCl, mannitol, and ABA treatments. T-DNA insertional loss-of-function mutants of AtNAP were more tolerant to salt stress than wild type (WT), whereas AtNAP-overexpressing transgenic plants (OXs) were more sensitive to salt stress than WT during germination, seedling development, and mature plant stage. Transcript levels of stress-responsive genes in the ABA-dependent pathway, such as AREB1, RD20, and RD29B, were significantly higher and lower in atnap mutants and AtNAP OXs, respectively, than in WT under salt stress conditions, suggesting that AtNAP might negatively regulate the expression of those genes under salt stress conditions. Indeed, AtNAP repressed the promoter activity of AREB1 under normal and salt stress conditions. These results indicate that AtNAP functions as a negative regulator in the salt stress response. Our results, together with previous studies, suggest that AtNAP functions as a negative regulator in osmotic stress responses, whereas it functions as a positive regulator in senescence.

Arabidopsis Qc-SNARE gene AtSFT12 is involved in salt and osmotic stress responses and Na(+) accumulation in vacuoles.

Key messageAtSFT12, anArabidopsisQc-SNARE protein, is localized to Golgi organelles and is involved in salt and osmotic stress responses via accumulation of Na+in vacuoles.AbstractTo reduce the detrimental effects of environmental stresses, plants have evolved many defense mechanisms. Here, we identified an Arabidopsis Qc-SNARE gene, AtSFT12, involved in salt and osmotic stress responses using an activation-tagging method. Both activation-tagged plants and overexpressing transgenic plants (OXs) of the AtSFT12 gene were tolerant to high concentrations of NaCl, LiCl, and mannitol, whereas loss-of-function mutants were sensitive to NaCl, LiCl, and mannitol. AtSFT12 transcription increased under NaCl, ABA, cold, and mannitol stresses but not MV treatment. GFP-fusion AtSFT12 protein was juxtaposed with Golgi marker, implying that its function is associated with Golgi-mediated transport. Quantitative measurement of Na+ using induced coupled plasma atomic emission spectroscopy revealed that AtSFT12 OXs accumulated significantly more Na+ than WT plants. In addition, Na+-dependent fluorescence analysis of Sodium Green showed comparatively higher Na+ accumulation in vacuoles of AtSFT12 OX cells than in those of WT plant cells after salt treatments. Taken together, our findings suggest that AtSTF12, a Golgi Qc-SNARE protein, plays an important role in salt and osmotic stress responses and functions in the salt stress response via sequestration of Na+ in vacuoles.

Arabidopsis HRE1α, a splicing variant of AtERF73/HRE1, functions as a nuclear transcription activator in hypoxia response and root development.

Key messageHRE1α shows transcriptional activation activity in its C-terminal region via GCC box but not DRE/CRT and plays an important role in root development via root meristem cell division regulation.AbstractAtERF73/HRE1 protein, a member of the Arabidopsis AP2/ERF family, contains a conserved AP2/ERF DNA-binding domain. Here, we studied the molecular function of HRE1α, a splicing variant of AtERF73/HRE1, as well as its role in root development. HRE1α-overexpressing transgenic plants (OXs) showed tolerance to submergence. HRE1α showed transcriptional activation activity via GCC box but not DRE/CRT. The 121–211 aa region of HRE1α was responsible for the transcriptional activation activity, and the region was conserved among homologs of other species but was not found in other Arabidopsis proteins. HRE1α OXs showed increased primary root length due to elevated root cell division. Our results suggest that HRE1α functions as a transcription activator in the nucleus, and plays an important role in root development through regulation of root meristem cell division.

The Arabidopsis chloroplast protein S-RBP11 is involved in oxidative and salt stress responses

AbstractKey messageS-RBP11, a chloroplast protein, which was isolated using activation tagging system, is shown to be the firstArabidopsissmall RNA-binding group protein involved in oxidative and salt stress responses.Abstract Activation tagging is one of the most powerful tools in reverse genetics. In this study, we isolated S-RBP11, encoding a small RNA-binding protein in Arabidopsis, by salt-resistant activation tagging line screen and then characterized its function in the abiotic stress response. The isolated activation tagging line of S-RBP11 as well as transgenic plants overexpressing S-RBP11 showed increased tolerance to salt and MV stresses compared to WT plants, whereas s-rbp11 mutants were more sensitive to salt stresses. Transcription of S-RBP11 was elevated upon MV treatment but not NaCl or cold treatment. Interestingly, S-RBP11 protein was localized in the chloroplast and the N-terminal 34 amino acid region of S-RBP11 was necessary for its chloroplast targeting. Our results suggest that S-RBP11 is a chloroplast protein involved in the responses to salt and oxidative stresses.

AtC3H17, a Non-Tandem CCCH Zinc Finger Protein, Functions as a Nuclear Transcriptional Activator and Has Pleiotropic Effects on Vegetative Development, Flowering and Seed Development in Arabidopsis

Despite increasing reports that CCCH zinc finger proteins function in plant development and stress responses, the functions and molecular aspects of many CCCH zinc finger proteins remain uncharacterized. Here, we characterized the biological and molecular functions of AtC3H17, a unique Arabidopsis gene encoding a non-tandem CCCH zinc finger protein. AtC3H17 was ubiquitously expressed throughout the life cycle of Arabidopsis plants and their organs. The rate and ratio of seed germination of atc3h17 mutants were slightly slower and lower, respectively, than those of the wild type (WT), whereas AtC3H17-overexpressing transgenic plants (OXs) showed an enhanced germination rate. atc3h17 mutant seedlings were smaller and lighter than WT seedlings while AtC3H17 OX seedlings were larger and heavier. In regulation of flowering time, atc3h17 mutants showed delayed flowering, whereas AtC3H17 OXs showed early flowering compared with the WT. In addition, overexpression of AtC3H17 affected seed development, displaying abnormalities compared with the WT. AtC3H17 protein was localized to the nucleus and showed transcriptional activation activity in yeast and Arabidopsis protoplasts. The N-terminal region of AtC3H17, containing a conserved EELR-like motif, was necessary for transcriptional activation activity, and the two conserved glutamate residues in the EELR-like motif played an important role in transcriptional activation activity. Real-time PCR and transactivation analyses showed that AtC3H17 might be involved in seed development via transcriptional activation of OLEO1, OLEO2 and CRU3. Our results suggest that AtC3H17 has pleiotropic effects on vegetative development such as seed germination and seedling growth, flowering and seed development, and functions as a nuclear transcriptional activator in Arabidopsis.