A plasma-membrane linker for the phosphoinositide-specific phospholipase C in tobacco plants.

We previously screened genes that were transcriptionally activated during the early stage of wound response in tobacco plants (Nicotiana tabacum), and isolated a particular clone, which encoded a membrane-located protein, designated as NtC7. Upon overexpression in tobacco plants, NtC7 conferred a marked tolerance to osmotic stress, suggesting it to be involved in maintenance of osmotic adjustments. In this study, we searched for proteins which interact with NtC7 by the yeast two-hybrid screening, and isolated a clone encoding phosphoinositide-specific phospholipase C, designated as NtPI-PLC. Physical interaction between NtC7 and C2 domain of NtPI-PLC was confirmed by the pull-down assay. Expression of fused protein to green-fluorescence protein in onion epidermal cell layers indicated both proteins to predominantly localize to the plasma membrane. Their interaction in planta was shown by the bimolecular fluorescence complementation, which exhibited a clear fluorescence of reconstituted yellow fluorescence protein. Transcripts of NtC7 and NtPI-PLC were markedly increased 30 to 60 min after wounding. PI-PLC is one of key enzymes in metabolism of inositol phospholipids, which function in signal transduction and also in response to stresses including osmotic changes. It was shown to localize to plasma-membrane and, to a lesser extent, to cytosol. However, molecular mechanism of membrane localization has remained to be determined, because of the apparent lack of domains for membrane association. The present results suggest that one of such mechanisms is tethering NtPI-PLC to the plasma membrane through interaction with NtC7, which possesses a transmembrane domain at the C-terminus.

A novel protein phosphorylation pathway involved in osmotic-stress response in tobacco plants.

Osmotic stress is one of the severest environmental pressures for plants, commonly occurring under natural growing condition due to drought, salinity, cold and wounding. Plants sensitively respond to these stresses by activating a set of genes, which encode proteins necessary to overcome the crises. We screened such genes from tobacco plants, and identified a particular clone, which encoded a 45 kDa protein kinase belonging to the plant receptor-like cytoplasmic protein kinase class-VII, NAK (novel Arabidopsis protein kinase) group. The clone was consequently designated as NtNAK (Nicotiana tabacum NAK, accession number: DQ447159). GFP-NtNAK fusion protein was localized in both cytoplasm and nucleus, and bacterially expressed NtNAK exhibited in vitro kinase activity. Its transcripts were clearly induced upon treatments of leaves with salt, mannitol, low temperature and also with abscisic and jasmonic acids and ethylene. These properties indicated NtNAK to be a typical osmo-stress-responsive protein kinase. Its target protein(s) were then screened by the yeast two-hybrid system, and one clone encoding a 32 kDa protein was identified. The protein resembled a potato stress-responsive protein CK251806, and designated as NtCK25 (accession number: DQ448851). Bacterially expressed NtCK25 was phosphorylated by NtNAK, and NtCK25-GFP fusion protein was exclusively localized in nucleus. The structure of NtCK25 was found to be similar to a human nuclear body protein, SP110, which is involved in DNA/protein binding regulation. This suggested that, perceiving osmo-stress signal, NtNAK phosphorylates and activates NtCK25, which might function in regulation of nucleus function. The present study thus suggests that NtNAK/NtCK25 constitutes a novel phosphorylation pathway for osmotic-stress response in plants.

Expression of a WIPK-activated transcription factor results in increase of endogenous salicylic acid and pathogen resistance in tobacco plants.

NtWIF is a transcription factor activated upon phosphorylation by wound-induced protein kinase (WIPK) in tobacco plants. Transgenic tobacco plants overexpressing NtWIF exhibited constitutive accumulation of transcripts for pathogenesis-related genes, PR-1a and PR-2. Salicylic acid levels were 50-fold higher than those in wild-type plants. The levels of jasmonic acid and IAA did not significantly differ, while an increase of ABA upon wounding was delayed by 3 h in the transgenics. When challenged with tobacco mosaic virus, lesions developed faster and were smaller in the transgenic plants. The results suggest that NtWIF is likely to influence salicylic acid biosynthesis, being located downstream of WIPK.

Activation of a novel transcription factor through phosphorylation by WIPK, a wound-induced mitogen-activated protein kinase in tobacco plants.

Wound-induced protein kinase (WIPK) is a tobacco (Nicotiana tabacum) mitogen-activated protein kinase known to play an essential role in defense against wounding and pathogens, although its downstream targets have yet to be clarified. This study identified a gene encoding a protein of 648 amino acids, which directly interacts with WIPK, designated as N. tabacum WIPK-interacting factor (NtWIF). The N-terminal region with approximately 250 amino acids showed a high similarity to the plant-specific DNA binding domain, B3, but no other similarity with known proteins. The C terminus of approximately 200 amino acids appeared to be essential for the interaction with WIPK, and a Luciferase-reporter gene assay using Bright Yellow 2 cells indicated the full-length protein to possess trans-activation activity, located to the middle region of approximately 200 amino acids. In vitro phosphorylation assays indicated that WIPK efficiently phosphorylates the full-length protein and the N terminus but not the C terminus. When full-length NtWIF was coexpressed with WIPK in Bright Yellow 2 cells, the Luciferase transcriptional activity increased up to 5-fold that of NtWIF alone, whereas no effect was observed with a kinase-deficient WIPK mutant. Transcripts of NtWIF began to simultaneously accumulate with those of WIPK 30 min after wounding and 1 h after the onset of hypersensitive response upon tobacco mosaic virus infection. These results suggest that NtWIF is a transcription factor that is directly phosphorylated by WIPK, thereby being activated for transcription of target gene(s) involved in wound and pathogen responses.

A hypersensitive response-induced ATPase associated with various cellular activities (AAA) protein from tobacco plants.

The hypersensitive response (HR) is one of the most critical defense systems in higher plants. In order to understand its molecular basis, we have screened tobacco genes that are transcriptionally activated during the early stage of the HR by the differential display method. Among six genes initially identified, one was found encoding a 57 kDa polypeptide with 497 amino acids not showing significant similarity to any reported proteins except for the AAA domain (ATPase associated with various cellular activities) spanning over 230 amino acids. The bacterially expressed protein exhibited ATP hydrolysis activity, and a green fluorescent protein-fusion protein localized in the cytoplasm of onion epidermis cells. The protein was subsequently designated as NtAAA1 (Nicotiana tabacum AAA1). NtAAA1 transcripts were induced 6 h after HR onset not only by TMV but also by incompatible Psuedomonas syringae, indicating that NtAAA1 is under the control of the N-gene with a common role in pathogen responses. Expression of NtAAA1 was induced by jasmonic acid and ethylene, but not by salicylic acid (SA). It also occurred at a high level in SA-deficient tobacco plants upon TMV infection. When NtAAA1 was silenced by the RNAi method, accumulation of transcripts for PR-1a significantly increased during the HR. Treatments with SA induced higher expression of PR-1a and acidic PR-2 in RNAi transgenic plants than in wild-type counterparts. These results suggest that NtAAA1 mitigates the SA signaling pathway, and therefore that NtAAA1 modulates the pathogen response of the host plants by adjusting the HR to an appropriate level.