Roles of ethylene receptor NTHK1 domains in plant growth, stress response and protein phosphorylation

Ethylene receptors sense ethylene and regulate downstream signaling events. Tobacco ethylene receptor NTHK1, possessing Ser/Thr kinase activity, has been found to function in plant growth and salt-stress responses. NTHK1 contains transmembrane domains, a GAF domain, a kinase domain and a receiver domain. We examined roles of these domains in regulation of plant leaf growth, salt-stress responses and salt-responsive gene expressions using an overexpression approach. We found that the transgenic Arabidopsis plants harboring the transmembrane domain plus kinase domain exhibited large rosettes, had reduction in ethylene sensitivity, and showed enhanced salt sensitivity. The transgenic plants harboring the transmembrane domain plus GAF domain also showed larger rosettes. Truncations of NTHK1 affected salt-induced gene expressions. Transmembrane domain plus kinase domain promoted RD21A and VSP2 expression but decreased salt-induction of AtNAC2. The kinase domain itself promoted AtERF4 gene expression. The GAF domain itself enhanced Cor6.6 induction. Moreover, the NTHK1 functional kinase domain phosphorylated the HIS and ATP subdomains, and five putative phosphorylation sites were identified in these two subdomains. In addition, the salt-responsive element of the NTHK1 gene was in the transmembrane-coding region but not in the promoter region. These results indicate that NTHK1 domains or combination of them have specific functions in plant leaf growth, salt-stress response, gene expression and protein phosphorylation.     

Expression of tobacco ethylene receptor NTHK1 alters plant responses to salt stress

Ethylene has been regarded as a stress hormone involved in many stress responses. However, ethylene receptors have not been studied for the roles they played under salt stress condition. Previously, we characterized an ethylene receptor gene NTHK1 from tobacco, and found that NTHK1 is salt-inducible. Here, we report a further investigation towards the function of NTHK1 in response to salt stress by using a transgenic approach. We found that NTHK1 promotes leaf growth in the transgenic tobacco seedlings but affects salt sensitivity in these transgenic seedlings under salt stress condition. Differential Na+/K+ ratio was observed in the control Xanthi and NTHK1-transgenic plants after salt stress treatment. We further found that the NTHK1 transgene is also salt-inducible in the transgenic plants, and the higher NTHK1 expression results in early inductions of the ACC (1-aminocyclopropane-1-carboxylic acid) oxidase gene NtACO3 and ethylene responsive factor (ERF) genes NtERF1 and NtERF4 under salt stress. However, NTHK1 suppresses the salt-inducible expression of the ACC synthase gene NtACS1. These results indicate that NTHK1 regulates salt stress responses by affecting ion accumulation and related gene expressions, and hence have significance in elucidation of ethylene receptor functions during stress signal transduction.     

Evidence for serine/threonine and histidine kinase activity in the tobacco ethylene receptor protein NTHK2

Ethylene plays important roles in plant growth, development, and stress responses. Two ethylene receptors, ETR1 from Arabidopsis and NTHK1 from tobacco (Nicotiana tabacum), have been found to have His kinase (HK) activity and Ser/Thr kinase activity, respectively, although both show similarity to bacterial two-component HK. Here, we report the characterization of another ethylene receptor homolog gene, NTHK2, from tobacco. This gene also encodes a HK-like protein and is induced by dehydration and CaCl(2) but not significantly affected by NaCl and abscisic acid treatments. The biochemical properties of the yeast (Schizosaccharomyces pombe)-expressed NTHK2 domains were further characterized. We found that NTHK2 possessed Ser/Thr kinase activity in the presence of Mn(2+) and had HK activity in the presence of Ca(2+). Several lines of evidence supported this conclusion, including hydrolytic stability, phosphoamino acid analysis, mutation, deletion, and substrate analysis. These properties have implications in elucidation of the complexity of the ethylene signal transduction pathway and understanding of ethylene functions in plants.     

Spatial expression and characterization of a putative ethylene receptor protein NTHK1 in tobacco

A putative ethylene receptor gene NTHK1 encodes a protein with a putative signal peptide, three transmembrane segments, a putative histidine kinase domain and a putative receiver domain. The receiver domain was expressed in an Escherichia coli expression system, purified and used to generate polyclonal antibodies for immunohistochemistry analysis. The spatial expression of the NTHK1 protein was then investigated. We found that NTHK1 was abundant during flower and ovule development. It was also expressed in glandular hairs, stem, and in leaves that had been wounded. The NTHK1 gene was further introduced into the tobacco plant and we found that, in different transgenic lines, the NTHK1 gene was transcribed to various degrees. Upon ACC treatment, the etiolated transgenic seedlings showed reduced ethylene sensitivity when compared with the control, indicating that NTHK1 is a functional ethylene receptor in plants.     

Serine/threonine kinase activity in the putative histidine kinase-like ethylene receptor NTHK1 from tobacco

A histidine kinase-based signaling system has been proposed to function in ethylene signal transduction pathway of plants and one ethylene receptor has been found to possess His kinase activity. Here we demonstrate that a His kinase-like ethylene receptor homologue NTHK1 from tobacco has serine/threonine (Ser/Thr) kinase activity, but no His kinase activity. Evidence obtained by analyzing acid/base stability, phosphoamino acid and substrate specificity of the phosphorylated kinase domain, supports this conclusion. In addition, mutation of the presumptive phosphorylation site His (H378) to Gln did not affect the kinase activity whereas deletion of the ATP-binding domain eliminated it, indicating that the conserved His (H378) is not required for the kinase activity and this activity is intrinsic to the NTHK1-KD. Moreover, confocal analysis of NTHK1 expression in insect cells and plant cells suggested the plasma membrane localization of the NTHK1 protein. Thus, NTHK1 may represent a distinct Ser/Thr kinase-type ethylene receptor and function in an alternative mechanism for ethylene signal transduction.     

Mutational analysis of the ethylene receptor ETR1. Role of the histidine kinase domain in dominant ethylene insensitivity

The ethylene receptor family of Arabidopsis consists of five members, one of these being ETR1. The N-terminal half of ETR1 contains a hydrophobic domain responsible for ethylene binding and membrane localization. The C-terminal half of the polypeptide contains domains with homology to histidine (His) kinases and response regulators, signaling motifs originally identified in bacteria. The role of the His kinase domain in ethylene signaling was examined in planta. For this purpose, site-directed mutations were introduced into the full-length wild-type ETR1 gene and into etr1-1, a mutant allele that confers dominant ethylene insensitivity on plants. The mutant forms of the receptor were expressed in Arabidopsis and the transgenic plants characterized for their ethylene responses. A mutation that eliminated His kinase activity did not affect the ability of etr1-1 to confer ethylene insensitivity. A truncated version of etr1-1 that lacks the His kinase domain also conferred ethylene insensitivity. Possible mechanisms by which a truncated version of etr1-1 could exert dominance are discussed.     

烟草乙烯受体类似物NTHK2全长基因的克隆及其激酶结构域生化特性

应用5＇-RACE方法克隆到烟草NTHK2的全长cDNA.其全长cDNA共有3 216bp,其中5'非编码区为509bp,3＇非编码区为427bp,编码区为2 280bp,编码产物为760个氨基酸.NTHK2氨基酸序列与植物中的许多杂合型的两组分乙烯受体基因有较高的同源性,具有推测的组氨酸激酶结构域和接受域;但是,在激酶结构域中没有保守的组氨酸,而是被一个天冬氨酸残基所替代.为了研究其生化特性,在酵母中以融合蛋白的形式表达了激酶结构域.体外激酶分析表明,当有Mg2+存在的情况下NTHK2能够自我磷酸化.进一步的研究应阐明NTHK2在植物体内是否能够作为乙烯受体,参与乙烯的信号传导过程.     

烟草乙烯受体类似物NTHK2全长基因的克隆及其激酶结构域生化特性

应用5′-ARCE方法克隆到烟草NTHK2的全长cDNA。其全长cDNA共有3216bp,其中5′非编码区为509bp,3′非编码区为427bp,编码区为2280bp,编码产物为760个氨基酸。NTHK2氨基酸序列与植物中的许多杂合型的两组分乙烯受体基因有较高的同源性,具有推测的组氨酸激酶结构域和接受域。但是,在激酶结构域中没有保守的组氨酸,而是被一个天冬氨酸残基所替代。为了研究其生化特性,在酵母中以融合蛋白的形式表达了激酶结构域,体外激酶分析表明,当有Mg^2 存在的情况下NTHK2能够自我磷酸化。进一步的研究应阐明NTHK2在植物体内是否能够作为乙烯受体。参与乙烯的信号传导过程。     

Cloning of an H+-PPase gene from Thellungiella halophila and its heterologous expression to improve tobacco salt tolerance

An H(+)-pyrophosphatase (PPase) gene named TsVP involved in basic biochemical and physiological mechanisms was cloned from Thellungiella halophila. The deduced translation product has similar characteristics to H(+)-PPases from other species, such as Arabidopsis and rice, in terms of bioinformation. The heterologous expression of TsVP in the yeast mutant ena1 suppressed Na(+) hypersensitivity and demonstrated the function of TsVP as an H(+)-PPase. Transgenic tobacco overexpressing TsVP had 60% greater dry weight than wild-type tobacco at 300 mM NaCl and higher viability of mesophyll protoplasts under salt shock stress conditions. TsVP and AVP1, another H(+)-PPase from Arabidopsis, were heterologously expressed separately in both the yeast mutant ena1 and tobacco. The salt tolerance of TsVP or AVP1 yeast transformants and transgenic tobacco were improved to almost the same level. The TsVP transgenic tobacco lines TL3 and TL5 with the highest H(+)-PPase hydrolytic activity were studied further. These transgenic tobacco plants accumulated 25% more solutes than wild-type plants without NaCl stress and 20-32% more Na(+) under salt stress conditions. Although transgenic tobacco lines TL3 and TL5 accumulated more Na(+) in leaf tissues, the malondialdehyde content and cell membrane damage were less than those of the wild type under salt stress conditions. Presumably, compartmentalization of Na(+) in vacuoles reduces its toxic effects on plant cells. This result supports the hypothesis that overexpression of H(+)-PPase causes the accumulation of Na(+) in vacuoles instead of in the cytoplasm and avoids the toxicity of excessive Na(+) in plant cells.     

CIPK6, a CBL-interacting protein kinase is required for development and salt tolerance in plants

Calcineurin B-like proteins (CBL) and CBL-interacting protein kinases (CIPK) mediate plant responses to a variety of external stresses. Here we report that Arabidopsis CIPK6 is also required for the growth and development of plants. Phenotype of tobacco plants ectopically expressing a homologous gene ( CaCIPK6 ) from the leguminous plant chickpea ( Cicer arietinum ) indicated its functional conservation. A lesion in AtCIPK6 significantly reduced shoot-to-root and root basipetal auxin transport, and the plants exhibited developmental defects such as fused cotyledons, swollen hypocotyls and compromised lateral root formation, in conjunction with reduced expression of a number of genes involved in auxin transport and abiotic stress response. The Arabidopsis mutant was more sensitive to salt stress compared to wild-type, while overexpression of a constitutively active mutant of CaCIPK6 promoted salt tolerance in transgenic tobacco. Furthermore, tobacco seedlings expressing the constitutively active mutant of CaCIPK6 showed a developed root system, increased basipetal auxin transport and hypersensitivity to auxin. Our results provide evidence for involvement of a CIPK in auxin transport and consequently in root development, as well as in the salt-stress response, by regulating the expression of genes.     

Phosphorylation of 1-aminocyclopropane-1-carboxylic acid synthase by MPK6, a stress-responsive mitogen-activated protein kinase, induces ethylene biosynthesis in Arabidopsis

Mitogen-activated protein kinases (MAPKs) are implicated in regulating plant growth, development, and response to the environment. However, the underlying mechanisms are unknown because of the lack of information about their substrates. Using a conditional gain-of-function transgenic system, we demonstrated that the activation of SIPK, a tobacco (Nicotiana tabacum) stress-responsive MAPK, induces the biosynthesis of ethylene. Here, we report that MPK6, the Arabidopsis thaliana ortholog of tobacco SIPK, is required for ethylene induction in this transgenic system. Furthermore, we found that selected isoforms of 1-aminocyclopropane-1-carboxylic acid synthase (ACS), the rate-limiting enzyme of ethylene biosynthesis, are substrates of MPK6. Phosphorylation of ACS2 and ACS6 by MPK6 leads to the accumulation of ACS protein and, thus, elevated levels of cellular ACS activity and ethylene production. Expression of ACS6(DDD), a gain-of-function ACS6 mutant that mimics the phosphorylated form of ACS6, confers constitutive ethylene production and ethylene-induced phenotypes. Increasing numbers of stress stimuli have been shown to activate Arabidopsis MPK6 or its orthologs in other plant species. The identification of the first plant MAPK substrate in this report reveals one mechanism by which MPK6/SIPK regulates plant stress responses. Equally important, this study uncovers a signaling pathway that modulates the biosynthesis of ethylene, an important plant hormone, in plants under stress.     

Dominant negative mutants of the Cdc2 kinase uncouple cell division from iterative plant development.

Because plant cells do not move and are surrounded by a rigid cell wall, cell division rates and patterns are believed to be directly responsible for generating new structures throughout development. To study the relationship between cell division and morphogenesis, transgenic tobacco and Arabidopsis plants were constructed expressing dominant mutations in a key regulator of the Arabidopsis cell cycle, the Cdc2a kinase. Plants constitutively overproducing the wild-type Cdc2a or the mutant form predicted to accelerate the cell cycle did not exhibit a significantly altered development. In contrast, a mutation expected to arrest the cell cycle abolished cell division when expressed in Arabidopsis, whereas some tobacco plants constitutively producing this mutant protein were recovered. These plants had a reduced histone H1 kinase activity and contained considerably fewer cells. These cells were, however, much larger and underwent normal differentiation. Morphogenesis, histogenesis and developmental timing were unaffected. The results indicate that, in plants, the developmental controls defining shape can act independently from cell division rates.     

LeCTR2, a CTR1-like protein kinase from tomato, plays a role in ethylene signalling, development and defence

Arabidopsis AtCTR1 is a Raf-like protein kinase that interacts with ETR1 and ERS and negatively regulates ethylene responses. In tomato, several CTR1-like proteins could perform this role. We have characterized LeCTR2, which has similarity to AtCTR1 and also to EDR1, a CTR1-like Arabidopsis protein involved in defence and stress responses. Protein–protein interactions between LeCTR2 and six tomato ethylene receptors indicated that LeCTR2 interacts preferentially with the subfamily I ETR1-type ethylene receptors LeETR1 and LeETR2, but not the NR receptor or the subfamily II receptors LeETR4, LeETR5 and LeETR6. The C-terminus of LeCTR2 possesses serine/threonine kinase activity and is capable of auto-phosphorylation and phosphorylation of myelin basic protein in vitro . Overexpression of the LeCTR2 N-terminus in tomato resulted in altered growth habit, including reduced stature, loss of apical dominance, highly branched inflorescences and fruit trusses, indeterminate shoots in place of determinate flowers, and prolific adventitious shoot development from the rachis or rachillae of the leaves. Expression of the ethylene-responsive genes E4 and chitinase B was upregulated in transgenic plants, but ethylene production and the level of mRNA for the ethylene biosynthetic gene ACO1 was unaffected. The leaves and fruit of transgenic plants also displayed enhanced susceptibility to infection by the fungal pathogen Botrytis cinerea , which was associated with much stronger induction of pathogenesis-related genes such as PR1b1 and chitinase B compared with the wild-type. The results suggest that LeCTR2 plays a role in ethylene signalling, development and defence, probably through its interactions with the ETR1-type ethylene receptors of subfamily I.     

The CCCH-type zinc finger proteins AtSZF1 and AtSZF2 regulate salt stress responses in Arabidopsis

The molecular mechanism governing the response of plants to salinity stress, one of the most significant limiting factors for agriculture worldwide, has just started to be revealed. Here, we report AtSZF1 and AtSZF2, two closely related CCCH-type zinc finger proteins, involved in salt stress responses in Arabidopsis. The expression of AtSZF1 and AtSZF2 is quickly and transiently induced by NaCl treatment. Mutants disrupted in the expression of AtSZF1 or AtSZF2 exhibit increased expression of a group of salt stress-responsive genes in response to high salt. Significantly, the atszf1-1/atszf2-1 double mutant displays more sensitive responses to salt stress than the atszf1-1 or atszf2-1 single mutants and wild-type plants. On the other hand, transgenic plants overexpressing AtSZF1 show reduced induction of salt stress-responsive genes and are more tolerant to salt stress. We also showed that AtSZF1 is localized in the nucleus. Taken together, these results demonstrated that AtSZF1 and AtSZF2 negatively regulate the expression of salt-responsive genes and play important roles in modulating the tolerance of Arabidopsis plants to salt stress.     

烟草乙烯受体研究进展(综述)

对近几年有关烟草乙烯受体基因研究的最新进展作简要介绍,并就今后该领域的研究方向进行探讨。已知烟草乙烯受体家族至少包括NtETR1、NtERS1、NTHK1和NTHK2等4种基因,其中NTHK1和NTHK2同源且有相似结构,两者的激酶活性与细菌双组分调节系统非常相似,激酶活性需要一些二价阳离子的参与。烟草乙烯受体在细胞内的作用位点还缺少研究。     

A lectin receptor-like kinase is required for pollen development in Arabidopsis

Lectin receptor-like kinases (Lectin RLKs) are a large family of receptor-like kinases with an extracellular legume lectin-like domain. There are approximately 45 such receptor kinases in Arabidopsis thaliana. Surprisingly, although receptor-like kinases in general are well investigated in Arabidopsis, relatively little is known about the functions of members of the Lectin RLK family. A number of studies implicated members of this family in various functions, such as disease resistance, stress responses, hormone signaling, and legume-rhizobium symbiosis. Our current work demonstrated that mutation in one Lectin RLK gene led to male sterility in Arabidopsis. The sterility was due to defects in pollen development. Pollen development proceeded normally in the mutant until anther stage 8. After that, all pollen grains deformed and collapsed. Mature pollen grains were much smaller than wild-type pollen grains, glued together, and totally collapsed. Therefore, the mutant was named sgc, standing for small, glued-together, and collapsed pollen mutant. The mutant phenotype appeared to be caused by an unidentified sporophytic defect due to the mutation. As revealed by analysis of the promoter-GUS transgenic plants and the gene expression analysis using RT-PCR, the gene showed an interesting temporal and spatial expression pattern: it had no or a low expression in young flowers (roughly before anther stage 6), reached a maximum level around stages 6-7, and then declined gradually to a very low level in young siliques. No expression was detected in microspores or pollen. Together, our data demonstrated that SGC Lectin RLK plays a critical role in pollen development.     

Requirement of the histidine kinase domain for signal transduction by the ethylene receptor ETR1

In Arabidopsis, ethylene is perceived by a receptor family consisting of five members, one of these being ETR1. The N-terminal half of ETR1 functions as a signal input domain. The C-terminal region of ETR1, consisting of a His kinase domain and a putative receiver domain, is likely to function in signal output. The role of the proposed signal output region in ethylene signaling was examined in planta. For this purpose, the ability of mutant versions of ETR1 to rescue the constitutive ethylene-response phenotype of the etr1-6;etr2-3;ein4-4 triple loss-of-function mutant line was examined. A truncated version of ETR1 that lacks both the His kinase domain and the receiver domain failed to rescue the triple mutant phenotype. A truncated ETR1 receptor that lacks only the receiver domain restored normal growth to the triple mutant in air, but the transgenic seedlings displayed hypersensitivity to low doses of ethylene. A mutation that eliminated His kinase activity had a modest effect upon the ability of the receptor to repress ethylene responses in air. These results demonstrate that the His kinase domain plays a role in the repression of ethylene responses. The potential roles of the receiver domain and His kinase activity in ethylene signaling are discussed.