Galpha12 and Galpha13 as key regulatory mediator in signal transduction

It is generally thought that Galpha(12) and Galpha(13)-induced responses are exclusively mediated by small G protein Rho. However, Galpha(12) and Galpha(13) elicit divergent cellular responses: phospholipase C-epsilon activation, phospholipase D activation, cytoskeletal change, oncogenic response, apoptosis, MAP kinase activation and Na/H-exchange activation. In addition to Rho activation through RhoGEF, it has been recently demonstrated that Galpha(12) and Galpha(13) interact with several proteins and regulate their activities. However, physiological importance of the interaction of Galpha(12) and Galpha(13) with these proteins has not fully established. I summarize the recent progress of Galpha(12) and Galpha(13)-mediated signaling cascade.     

Drought signal transduction in plants

Water deficit is one of the most common environmental limitations of crop productivity by affecting growth through alterations in metabolism and gene expression. The mechanisms involved in drought perception and signal transduction pathways are poorly understood. The participation of the plant hormone abscisic acid (ABA) has been well established. ABA levels increase when there are changes in the environment that result in cellular dehydration. Different approaches have been taken to understanding the molecular responses to desiccation and how ABA regulates gene expression. Recent efforts have identified particular topics of importance in the dissection of the signal transduction pathway which are summarized as follows: physiological approaches: identification of signalling molecules. Genetic approaches: the use of mutants, and Molecular approaches: promoter analysis.     

Light signal transduction in plants

Light signal-transduction pathways are a central component of the mechanisms that regulate plant development. These pathways provide the means by which information from specific wavelengths of light may be amplified and coordinated, resulting in complex physiological and developmental responses. This review focuses upon recent approaches towards establishing the intermediates that transmit signals from photoreceptors, phytochromes in particular, to target elements in the promoters of light-regulated genes.     

Zinc as a possible mediator of signal transduction in T lymphocytes

Our recent findings indicate that phorbol esters, the specific activators of protein kinase C induce the translocation of heavy metals (mostly: zinc) from the nucleus and mitochondria to the cytosol and microsomes of T lymphocytes. Phorbol ester treatment impairs the action of Ca-ionophores, this effect is mediated by intracellular heavy metal ions (most probably: by zinc). Zinc activates cytosolic protein kinase C, increases its affinity towards phorbol esters and contributes to its binding to plasma membranes. These results suggest that zinc may play a role in the "cross-talk" of second messengers and hence in signal transduction in T lymphocytes.     

Calcium and signal transduction in plants

Environmental and hormonal signals control diverse physiological processes in plants. The mechanisms by which plant cells perceive and transduce these signals are poorly understood. Understanding biochemical and molecular events involved in signal transduction pathways has become one of the most active areas of plant research. Research during the last 15 years has established that Ca2+ acts as a messenger in transducing external signals. The evidence in support of Ca2+ as a messenger is unequivocal and fulfills all the requirements of a messenger. The role of Ca2+ becomes even more important because it is the only messenger known so far in plants. Since our last review on the Ca2+ messenger system in 1987, there has been tremendous progress in elucidating various aspects of Ca(2+) -signaling pathways in plants. These include demonstration of signal-induced changes in cytosolic Ca2+, calmodulin and calmodulin-like proteins, identification of different Ca2+ channels, characterization of Ca(2+) -dependent protein kinases (CDPKs) both at the biochemical and molecular levels, evidence for the presence of calmodulin-dependent protein kinases, and increased evidence in support of the role of inositol phospholipids in the Ca(2+) -signaling system. Despite the progress in Ca2+ research in plants, it is still in its infancy and much more needs to be done to understand the precise mechanisms by which Ca2+ regulates a wide variety of physiological processes. The purpose of this review is to summarize some of these recent developments in Ca2+ research as it relates to signal transduction in plants.     

Wound signal transduction pathways in plants

A significant advancement in our knowledge and understanding of wound-signaling pathways in plants has been made recently. Essential role in the explanation of these processes came from the genetic screens and analysis of mutants which are defective in either jasmonic acid (JA) biosynthesis, JA perception or systemin function. Plants equally react to wound in the tissues directly damaged (local response) as well as in the non-wounded areas (systemic response). Jasmonides and in particular the most studied JA, produced by the octadecanoid pathway, are responsible for the systemic response. Jasmonides functioning as long-distance signal particles transmit the information about wound to distant, non-wounded tissues where defense response is invoked. Peptyd - systemin, identified in some Solanaceous species, acts locally to the wounded area to elicit the production of JA. Jasmonic acid-dependent and -independent wound signal transduction pathways have been identified and partially characterized. JA-dependent wound signaling pathways are responsible for the activation of systemic responses, whereas JA-independent wound signaling pathways, activated close to wound side, have a role in reparation of damaged tissue and in defense against pathogens.     

Engineering key components in a synthetic eukaryotic signal transduction pathway

Signal transduction underlies how living organisms detect and respond to stimuli. A goal of synthetic biology is to rewire natural signal transduction systems. Bacteria, yeast, and plants sense environmental aspects through conserved histidine kinase (HK) signal transduction systems. HK protein components are typically comprised of multiple, relatively modular, and conserved domains. Phosphate transfer between these components may exhibit considerable cross talk between the otherwise apparently linear pathways, thereby establishing networks that integrate multiple signals. We show that sequence conservation and cross talk can extend across kingdoms and can be exploited to produce a synthetic plant signal transduction system. In response to HK cross talk, heterologously expressed bacterial response regulators, PhoB and OmpR, translocate to the nucleus on HK activation. Using this discovery, combined with modification of PhoB (PhoB‐VP64), we produced a key component of a eukaryotic synthetic signal transduction pathway. In response to exogenous cytokinin, PhoB‐VP64 translocates to the nucleus, binds a synthetic PlantPho promoter, and activates gene expression. These results show that conserved‐signaling components can be used across kingdoms and adapted to produce synthetic eukaryotic signal transduction pathways.     

Temperature perception and signal transduction in plants

Plants can show remarkable responses to small changes in temperature, yet one of the great unknowns in plant science is how that temperature signal is perceived. The identity of the early components of the temperature signal transduction pathway also remains a mystery. To understand the consequences of anthropogenic environmental change we will have to learn much more about the basic biology of how plants sense temperature. Recent advances show that many known plant-temperature responses share common signalling components, and suggest ways in which these might be linked to form a plant temperature signalling network.     

植物体内磷脂代谢和信号转导

磷脂不但作为细胞结构的重要组成部分，其代谢产物主料可作为人信号分子，这一推断日益受到人们重视，并为越来越多的实验所证实。本文综述磷脂酶类、磷酸肌醇激酶及其代谢产物参与的植物细胞内的信号转导，阐述它们与植物激素和钙信使系统的关系。     

海藻糖介导的信号转导与植物抗逆性

海藻糖是一种非还原性二糖,它广泛存在于细菌、真菌、酵母、昆虫、无脊椎动物和植物等生物体内。海藻糖不仅作为碳水化合物的储备,而且还是一个多功能分子。海藻糖作为一种信号分子,启动信号转导级联反应,改变基因表达和酶的活性,与激素也有一定的关系。采用基因工程和通过外源施加的方法增加海藻糖在植物体内的积累可以提高植物的抗逆性,这为提高农作物的抗逆性提供了新的策略。     

受体激酶介导的油菜素内酯信号转导途径

油菜素内酯（brassinosteroids,BRs）是一类重要的类固醇激素,参与调控植物生长发育的许多过程。结合应用遗传学、生物化学以及蛋白质组学等研究手段现已基本阐明了BR信号转导的主要过程。BRI1作为受体在细胞表面感知BR,BRI1抑制子BKI1从质膜上解离下来,使BRI1与其共受体BAK1结合。BRI1和BAK1通过顺序磷酸化将BR信号完全激活。活化的BRI1将BSK磷酸化激活,BSK活化BSU1,BSU1将BIN2去磷酸化使其失活,解除BIN2对BES1/BZR1的抑制功能。PP2A可以将BES1/BZR1去磷酸化激活,又可以将受体BRI1去磷酸化促使其降解。BR信号的传递最终使去磷酸化状态的BES1/BZR1在细胞内累积,激活BR信号通路下游的转录调控。     

植物孢子体自交不亲和信号转导功能分子研究进展

孢子体自交不亲和(SSI)是许多植物采取的一种抵制近亲繁殖的重要措施,受S位点复等位基因控制。近年来,参与其信号转导的许多功能分子及它们的编码基因被分离并得到了充分研究：当自花授粉时,SPlI／SCR与SRK特异识别,造成后的Ser／Thr激酶的磷酸化,引发了一系列由SLG、ARC1及水孔蛋白等因子参与的SSI信号转导途径,最终产生自交不亲和的结果。