Characterization of an ethylene receptor homolog gene from rice

Ethylene is a gaseous hormone and plays important roles in plant growth and development, including seed germination, root hair development, flowering, pollination, abscission, and fruit ripening[1]. It is also involved in plant responses to biotic stress such as pathogen attack, and abiotic stresses such as wounding, drought and freezing[1]. Mutational and genetic analysis of Arabidopsis has led to the identification of five ethylene receptor genes, i.e. ETR1, ERS1, ETR2, EIN4 and ERS2. …     

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.     

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.     

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.     

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。     

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.     

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.     

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。     

Ethylene receptor expression is regulated during fruit ripening, flower senescence and abscission

Using theArabidopsis ethylene receptorETR1 as a probe, we have isolated a tomato homologue (tETR) from a ripening cDNA library. The predicted amino acid sequence is 70% identical toETR1 and homologous to a variety of bacterial two component response regulators over the histidine kinase domain. Sequencing of four separate cDNAs indicates that tETR lacks the carboxyl terminal response domain and is identical to that encoded by the tomatoNever ripe gene. Ribonuclease protection showed tETR mRNA was undetectable in unripe fruit or pre-senescent flowers, increased in abundance during the early stages of ripening, flower senescence, and in abscission zones, and was greatly reduced in fruit of ripening mutants deficient in ethylene synthesis or response. These results suggest that changes in ethylene sensitivity are mediated by modulation of receptor levels during development.     

Cloning and characterization of the histidine kinase gene<Emphasis Type="Italic"> Dic1</Emphasis> from<Emphasis Type="Italic"> Cochliobolus heterostrophus</Emphasis> that confers dicarboximide resistance and osmotic adaptation

A gene for a putative two-component histidine kinase, which is homologous to os-1 from Neurospora crassa, was cloned and sequenced from the plant-pathogenic fungus Cochliobolus heterostrophus. The predicted protein possessed the conserved histidine kinase domain, the response regulator domain, and six tandem repeats of 92-amino-acids at the N-terminal end that are found in histidine kinases from other filamentous fungi. Introduction of the histidine kinase gene complemented the deficiency of the C. heterostrophus dic1 mutant, suggesting that the Dic1 gene product is a histidine kinase. Dic1 mutants are resistant to dicarboximide and phenylpyrrole fungicides, and they are sensitive to osmotic stress. We previously classified dic1 alleles into three types, based on their phenotypes. To explain the phenotypic differences among the dic1 mutant alleles, we cloned and sequenced the mutant dic1 genes and compared their sequences with that of the wild-type strain. Null mutants for Dic1, and mutants with a deletion or point mutation in the N-terminal repeat region, were highly sensitive to osmotic stress and highly resistant to both fungicides. A single amino acid change within the kinase domain or the regulator domain altered the sensitivity to osmotic stress and conferred moderate resistance to the fungicides. These results suggest that this predicted protein, especially its repeat region, has an important function in osmotic adaptation and fungicide resistance.Communicated by C. A. M. J. J. van den Hondel     

Ethylene receptor ETHYLENE RECEPTOR1 domain requirements for ethylene responses in Arabidopsis seedlings

Ethylene influences many processes in Arabidopsis (Arabidopsis thaliana) through the action of five receptor isoforms. We used high-resolution, time-lapse imaging of dark-grown Arabidopsis seedlings to better understand the roles of each isoform in the regulation of growth in air, ethylene-stimulated nutations, and growth recovery after ethylene removal. We found that ETHYLENE RECEPTOR1 (ETR1) is both necessary and sufficient for nutations. Transgene constructs in which the ETR1 promoter was used to drive expression of cDNAs for each of the five receptor isoforms were transferred into etr1-6;etr2-3;ein4-4 triple loss-of-function mutants that have constitutive growth inhibition in air, fail to nutate in ethylene, and take longer to recover a normal growth rate when ethylene is removed. The patterns of rescue show that ETR1, ETR2, and ETHYLENE INSENSITIVE4 (EIN4) have the prominent roles in rapid growth recovery after removal of ethylene whereas ETR1 was the sole isoform that rescued nutations. ETR1 histidine kinase activity and phosphotransfer through the receiver domain are not required to rescue nutations. However, REVERSION TO SENSITIVITY1 modulates ethylene-stimulated nutations but does not modulate the rate of growth recovery after ethylene removal. Several chimeric receptor transgene constructs where domains of EIN4 were swapped into ETR1 were also introduced into the triple mutant. The pattern of phenotype rescue by the chimeric receptors used in this study supports a model where a receptor with a receiver domain is required for normal growth recovery and that nutations specifically require the full-length ETR1 receptor.     

The Ethylene Receptor ETR2 Delays Floral Transition and Affects Starch Accumulation in Rice

Ethylene regulates multiple aspects of plant growth and development in dicotyledonous plants; however, its roles in monocotyledonous plants are poorly known. Here, we characterized a subfamily II ethylene receptor, ETHYLENE RESPONSE2 (ETR2), in rice (Oryza sativa). The ETR2 receptor with a diverged His kinase domain is a Ser/Thr kinase, but not a His kinase, and can phosphorylate its receiver domain. Mutation of the N box of the kinase domain abolished the kinase activity of ETR2. Overexpression of ETR2 in transgenic rice plants reduced ethylene sensitivity and delayed floral transition. Conversely, RNA interference (RNAi) plants exhibited early flowering and the ETR2 T-DNA insertion mutant etr2 showed enhanced ethylene sensitivity and early flowering. The effective panicles and seed-setting rate were reduced in the ETR2-overexpressing plants, while thousand-seed weight was substantially enhanced in both the ETR2-RNAi plants and the etr2 mutant compared with controls. Starch granules accumulated in the internodes of the ETR2-overexpressing plants, but not in the etr2 mutant. The GIGANTEA and TERMINAL FLOWER1/CENTRORADIALIS homolog (RCN1) that cause delayed flowering were upregulated in ETR2-overexpressing plants but downregulated in the etr2 mutant. Conversely, the α-amylase gene RAmy3D was suppressed in ETR2-overexpressing plants but enhanced in the etr2 mutant. Thus, ETR2 may delay flowering and cause starch accumulation in stems by regulating downstream genes.     

A two-component gene (NTHK1) encoding a putative ethylene-receptor homolog is both developmentally and stress regulated in tobacco

The full-length of a two-component gene NTHK1 (Nicotiana tabacum histidine kinase-l) was isolated from tobacco (N. tabacum var. Xanthi) using a previously obtained NTHK1 cDNA fragment as a probe. Sequence analysis revealed that NTHK1 shared high homology with LeETR4 from tomato and encoded an ethylene- receptor homolog. The predicted NTHK1 protein had a putative signal peptide, three transmembrane domains, a histidine kinase domain and a receiver domain. The putative autophosphorylation site at His378 and the phosphate receiver site at Asp689 were also identified. By using the in situ hybridization technique, NTHK1 mRNA was detected during flower organ development. It is also highly expressed in the processes of pollen formation and embryo development. The expression of NTHK1 in response to wounding and other stresses was investigated using competitive RT-PCR. The results demonstrated that NTHK1 was inducible upon wounding (cutting). Floating of the cut leaf pieces in 0.5× MS, with shaking, led to a relatively rapid and strong expression. This phenomenon was confirmed by the in situ hybridization results. In addition to the up-regulation by wounding, NTHK1 expression was also induced following NaCl and PEG treatment, indicating a possible role for NTHK1 in multiple stress responses. Received: 28 June 2000 / Accepted: 1 August 2000     

Genetic and transformation studies reveal negative regulation of ERS1 ethylene receptor signaling in Arabidopsis

Background  

Ethylene receptor single mutants of Arabidopsis do not display a visibly prominent phenotype, but mutants defective in multiple ethylene receptors exhibit a constitutive ethylene response phenotype. It is inferred that ethylene responses in Arabidopsis are negatively regulated by five functionally redundant ethylene receptors. However, genetic redundancy limits further study of individual receptors and possible receptor interactions. Here, we examined the ethylene response phenotype in two quadruple receptor knockout mutants, (ETR1) ers1 etr2 ein4 ers2 and (ERS1) etr1 etr2 ein4 ers2, to unravel the functions of ETR1 and ERS1. Their functions were also reciprocally inferred from phenotypes of mutants lacking ETR1 or ERS1. Receptor protein levels are correlated with receptor gene expression. Expression levels of the remaining wild-type receptor genes were examined to estimate the receptor amount in each receptor mutant, and to evaluate if effects of ers1 mutations on the ethylene response phenotype were due to receptor functional compensation. As ers1 and ers2 are in the Wassilewskija (Ws) ecotype and etr1, etr2, and ein4 are in the Columbia (Col-0) ecotype, possible effects of ecotype mixture on ethylene responses were also investigated.     

MAP kinase cascades in elicitor signal transduction

 Protein kinases play important roles in elicitor signal transduction. In this article, I describe the current view of the role of mitogen-activated protein kinase (MAPK) cascades in elicitor signal transduction of plant cells based on our own research and recent developments in this field. In the past several years, it has become apparent that MAPK cascades play important roles in elicitor signal transduction in plants. Our early studies demonstrated the identification of p47 MAPK in tobacco as an elicitor-responsive protein kinase and possible involvement of p47 MAPK in elicitor signal transduction to induce defense responses, including defense gene expression and hypersensitive cell death. However, the molecular identity of p47 MAPK is still unclear. Recent important studies suggest that tobacco MAPK cascades that include SIPK, and/or WIPK, and NtMEK2, an upstream kinase for both SIPK and WIPK, have a crucial function in induction of defense responses and hypersensitive cell death. The orthologs of these protein kinases in Arabidopsis and alfalfa are also suggested to have similar functions. Furthermore, the identification of loss-of-function mutation in Arabidopsis reveals a negative regulatory role for putative MAPK cascades in plant defense mechanisms. Received: February 7, 2002 / Accepted: February 25, 2002     

Interaction of the maize and Arabidopsis kinase interaction domains with a subset of receptor-like protein kinases: implications for transmembrane signaling in plants

The kinase interaction (KI) domain of kinase-associated protein phosphatase (KAPP) interacts with the phosphorylated form of an Arabidopsis thaliana receptor-like protein kinase (RLK). The KI domain may recruit KAPP into an RLK-initiated signaling complex. To examine additional roles that this domain may play in plant signal transduction, a search was conducted for other KI domain-containing proteins. One gene was isolated which encodes a KI domain, the maize homolog of KAPP. To test whether the maize KI domain associates with other maize proteins, it was used as a probe in a protein–protein interaction cloning strategy. A new maize RLK, K I domain i nteracting k inase 1 (KIK1), was identified by its interaction with the maize KI domain. The maize KI domain and the KIK1 kinase domain association required phosphorylation of the kinase. This work establishes that the KI domain phosphorylation-dependent signaling mechanism is present in both monocots and dicots. Additionally, it was determined that both the maize and Arabidopsis KI domains interact with several but not all of the active RLKs assayed. These multiple associations imply that KAPP may function in a number of RLK-initiated signaling pathways.     

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.     

植物乙烯信号转导研究进展

过去10年,对模式植物拟南芥的分子遗传学研究建立了植物乙烯信号转导线性模型.乙烯结合到受体上,经一条MAPK级联反应和转录级联途径将信号转导而产生乙烯反应.拟南芥乙烯受体家族由5个成员构成,ETR1、ERS1、ETR2、ERS2和EIN4.乙烯受体包括三个结构域:乙烯结合结构域、组氨酸激酶结构域和反应调控结构域.乙烯受体定位于内质网,与CTR1协同负调控乙烯反应.ENI2、EIN3/EIL、ERF1依次位于CTR1下游,正调控乙烯反应.EIN3属于转录激活因子调控蛋白家族,受转录后调控.乙烯稳定EIN3结构,EBF1/EBF2促进EIN3分解.ERF1是转录调控因子家族成员之一,是EIN3/EIL的直接作用目标.     

Unusual Membrane-Associated Protein Kinases in Higher Plants

Plant genomes encode a variety of protein kinases, and while some are functional homologues of animal and fungal kinases, others have a novel structure. This review focuses on three groups of unusual membrane-associated plant protein kinases: receptor-like protein kinases (RLKs), calcium-dependent protein kinases (CDPKs), and histidine protein kinases. Animal RLKs have a putative extracellular domain, a single transmembrane domain, and a protein kinase domain. In plants, all of the RLKs identified thus far have serine/threonine signature sequences, rather than the tyrosine-specific signature sequences common to animals. Recent genetic experiments reveal that some of these plant kinases function in development and pathogen resistance. The CDPKs of plants and protozoans are composed of a single polypeptide with a protein kinase domain fused to a C-terminal calmodulin-like domain containing four calcium-binding EF hands. No functional plant homologues of protein kinase C or Ca²⁺/calmodulin-dependent protein kinase have been identified, and no animal or fungal CDPK homologues have been identified. Recently, histidine kinases have been shown to participate in signaling pathways in plants and fungi. ETR1, an Arabidopsis histidine kinase homologue with three transmembrane domains, functions as a receptor for the plant hormone ethylene. G-protein-coupled receptors, which often serve as hormone receptors in animal systems, have not yet been identified in plants. Received: 18 August 1997/Revised: 23 December 1997