烟草薄层培养生长素结合蛋白ABP1的定位和ABP1在细胞分化中的变化

以烟草（Nicotiana tabacum L.)盛花期花梗薄层为材料,研究营养芽分化的不同时期生长素结合蛋白（ABP1)在组织与细胞中的分布变化,免疫荧光标记结果表明,烟草花梗中ABP1主要分布于表皮及亚表皮1－2层细胞内。不同分化期ABP1在烟草花梗薄层原生质体中的表达不同,细胞分化旺盛期ABP1的表达最强,分化后期ABP1的表达有所减弱;Western blotting结果表明,ABP1多克隆抗血清与烟草花梗薄层细胞及分化过程中26kD蛋白有免疫交叉反应。     

In vivo evidence for the involvement of phospholipase A and protein kinase in the signal transduction pathway for auxin-induced corn coleoptile elongation

Auxin-induced elongation of com coleoptiles is accompanied by cell wall acidification, which depends upon H⁺-pump activity. We tested the hypothesis that phospholipase A and a protein kinase are involved in the pathway of auxin signal transduction leading to H⁺ secretion, and elongation of corn coleoptiles. Initially, the pH of the bath solution at 50–100 μm from the surface of a coleoptile segment (pH_o) ranged between 4.8 and 6.6 when measured with an H⁺-sensitive microelectrode. Twenty or 50 μM lysophosphatidylcholine, 50 μM linolenic acid or 50 μM arachidonic acid induced a decline in pH_o by 0.3 to 2.1 units. The effect was blocked by 1 mM vanadate, suggesting that lysophosphatidylcholine or linolenic acid induced acidification of the apoplast by activating the H⁺-pump. Lysophosphatidylcholine and linolenic acid also accelerated the elongation rate of the coleoptiles. While linolenic acid and arachidonic acid, highly unsaturated fatty acids, promoted pH_o decrease and coleoptile elongation, linoleic acid, oleic acid, and stearic acid, fatty acids with a lesser extent of unsaturation, had no such effects. The effects of lysophosphatidylcholine, linolenic acid, and arachidonic acid on H⁺ secretion were not additive to that of indoleacetic acid (IAA), suggesting that lysophospholipids, fatty acids and auxin use similar pathways for the activation of the H⁺-pump. The phospholipase A₂ inhibitors, aristolochic acid and manoalide, inhibited the IAA-induced pH_o decrease and coleoptile elongation. The general protein kinase inhibitors, H-7 or staurosporine, blocked the IAA- or lysophosphatidylcholine-induced decrease in pH_o. H-7 also inhibited the coleoptile elongation induced by IAA or lysophosphatidylcholine. These results support the hypothesis that phospholipase A is activated by auxin, and that the products of the enzyme, lysophospholipids and fatty acids, induce acidification of the apoplast by activating the H⁺-pump through a mechanism involving a protein kinase, which in turn promotes com coleoptile elongation.     

Activity of plasma membrane H+-ATPase and expression of PMA1 and PMA2 genes in Saccharomyces cerevisiae cells grown at optimal and low pH

Cells of Saccharomyces cerevisiae grown in media with an initial pH of 2.5–6.0, acidified with a strong acid (HCl), exhibited the highest plasma membrane H⁺-ATPase-specific activity at an initial pH of 6.0. At a lower pH (above pH 2.5) ATPase activity (62–83% of the maximum level) still allowed optimal growth. At pH 2.5, ATPase activity was about 30% of the maximum value and growth was impaired. Quantitative immunoassays showed that the content of ATPase protein in the plasma membrane was similar across the entire pH range tested, although slightly lower at pH 2.5. The decrease of plasma membrane ATPase activity in cells grown at low pH was partially accounted for by its in vitro stability, which decreased sharply at pH below 5.5, although the reduction of activity was far below the values expected from in vitro measurements. Yeast growth under acid stress changed the pattern of gene expression observed at optimal pH. The level of mRNA from the essential plasma-membrane-ATPase-encoding gene PMA1 was reduced by 50% in cells grown at pH 2.5 as compared with cells grown at the optimal pH 5.0, although the content of ATPase in the plasma membrane was only modestly reduced. As observed in response to other kinds of stress, the PMA2 promoter at the optimal pH was up to eightfold more efficient in cells grown at pH 2.5, although it remained several hundred times less efficient than that of the PMA1 gene. Received: 22 April 1996 / Accepted: 6 August 1996     

水稻生长素结合蛋白ABP1的原核表达及纯化

生长素结合蛋白能够与生长素特异性结合,因而有可能直接被用作生长素免疫分析和生物传感测定中的高特异性、高亲和力识别分子.本研究通过RT-PCR获得水稻生长素结合蛋白1(ABP1)cDNA,将其克隆到原核表达载体pET-32a(+)中,成功构建pET-32a-ABP1 重组表达载体.经酶切、PCR及DNA测序鉴定后,将阳性...     

Secondary messengers and phospholipase A2 in auxin signal transduction

Despite recent progress auxin signal transduction remains largely scetchy and enigmatic. A good body of evidence supports the notion that the ABP1 could be a functional receptor or part of a receptor, respectively, but this is not generally accepted. Evidence for other functional receptors is lacking, as is any clearcut evidence for a function of G proteins. Protons may serve as second messengers in guard cells but the existing evidence for a role of calcium remains to be clearified. Phospholipases C and D seem not to have a function in auxin signal transduction whereas the indications for a role of phospholipase A₂ in auxin signal transduction accumulated recently. Mitogen-activated protein kinase (MAPK) is modulated by auxin and the protein kinase PINOID has a role in auxin transport modulation even though their functional linkage to other signalling molecules is ill-defined. It is hypothesized that signal transduction precedes activation of early genes such as IAA genes and that ubiquitination and the proteasome are a mechanism to integrate signal duration and signal strength in plants and act as major regulators of hormone sensitivity.     

The auxin signal for protoplast swelling is perceived by extracellular ABP1

Protoplasts of corn coleoptiles and Arabidopsis hypocotyls respond to the plant hormone auxin with a rapid change in volume. We checked the effect of antibodies directed against epitopes of auxin-binding protein 1 from Arabidopsis thaliana (AtERabp1) and Zea mays (ZmERabp1), respectively. Antibodies raised against the C-terminus of AtERabp1 inhibited the response to auxin, while antibodies raised against a part of box a, the putative auxin-binding domain, induced a swelling response similar to that caused by auxin treatment. Synthetic C-terminal oligopeptides of ZmERabp1 also caused a swelling response. These effects occurred regardless of whether the experiments were carried out with homologous (anti-AtERabp1 antibodies on Arabidopsis protoplasts or anti-ZmERabp1 antibodies in maize protoplasts) or heterologous immunological tools. The results indicate that the auxin signal for protoplast swelling is perceived by extracellular ABP1.     

破坏光敏色素A改变生长素反应因子8的表达谱

拟南芥生长素反应因子8（auxin response factor8,ARF8）受光诱导表达,涉及光信号转导。为阐明光信号通过光受体传递给ARF8的过程和机理,首先利用半定量RT-PCR分析发现,PhyA的突变促进幼苗中ARF8的表达,而PhyB、Cry1和Cry2的突变对ARF8的表达没有明显影响。进而,利用GUS染色以及半定量和定量RT-PCR方法,系统分析PhyA基因的突变对ARF8基因表达的影响。结果表明,在黑暗、白光和远红光条件下,PhyA突变均明显提高拟南芥（Arabidopsis thaliana）幼苗子叶和叶片中ARF8的表达水平,并且明显降低其在幼苗下胚轴、茎尖和根尖中的表达水平。上述结果说明,PhyA基因的突变组成型地改变了ARF8基因的表达谱。然而,ARF8的突变并未明显改变PhyA的表达。说明在远红光信号通路中,ARF8位于PhyA的下游。     

Altered Expression of Auxin-binding Protein 1 Affects Cell Expansion and Auxin Pool Size in Tobacco Cells

Auxin-binding protein 1 (ABP1) has an essential role in auxin-dependent cell expansion, but its mechanisms of action remain unknown. Our previous study showed that ABP1-mediated cell expansion is auxin concentration dependent. However, auxin distribution in plant tissue is heterogeneous, complicating the interpretation of ABP1 function. In this study, we used cells in culture that have altered expression of ABP1 to address the mechanism of ABP1 action at the cellular level, because cells in culture have homogeneous cell types and could potentially circumvent the heterogeneous auxin-distributions inherent in plant tissues. We found that cells overexpressing ABP1 had altered sensitivity to auxin and were larger, with nuclei that have undergone endoreduplication, a finding consistent with other data that support an auxin extracellular receptor role for ABP1. These cells also had a higher free auxin pool size, which cannot be explained by altered auxin transport. In cells lacking detectable ABP1, a higher rate of auxin metabolism was observed. The results suggest that ABP1 has, beyond its proposed role as an auxin extracellular receptor, a role in mediating auxin availability.     

NaCl-induced accumulation of tonoplast and plasma membrane H+-ATPase message in tomato

NaCl-induced changes in the accumulation of message for the 70 kDa subunit of the tonoplast H⁺-ATPase and plasma membrane H⁺-ATPase were studied in hydroponically grown plants of Lycopersicon esculentum Mill. cv. Large Cherry Red. There was increased accumulation of message for the 70 kDa (catalytic) subunit of the tonoplast H⁺-ATPase in expanded leaves of tomato plants 24 h after final NaCl concentrations were attained. This was a tissue-specific response; levels of this message were not elevated in roots or in young, unexpanded leaves. The NaCl-induced accumulation of this message was transient in the expanded leaves and returned to control levels within 7 days. The temporal and spatial patterns of NaCl-induced accumulation of message for the plasma membrane H⁺-ATPase differed from the patterns associated with the 70 kDa subunit of the tonoplast H⁺-ATPase. NaCl-induced accumulation of the plasma membrane H⁺-ATPase message occurred in both roots and expanded leaves. Initially accumulation of the plasma membrane H⁺-ATPase message was greater in root tissue than in expanded leaves, but increased to higher levels in expanded leaves after 7 days. These results suggest that increased expression of the tonoplast H⁺-ATPase is an early response to salinity stress and may be associated with survival mechanisms, rather than with long-term adaptive processes.     

Molecular dynamics simulations of the auxin‐binding protein 1 in complex with indole‐3‐acetic acid and naphthalen‐1‐acetic acid

Auxin‐binding protein 1 (ABP1) is suggested to be an auxin receptor which plays an important role in several processes in green plants. Maize ABP1 was simulated with the natural auxin indole‐3‐acetic acid (IAA) and the synthetic analog naphthalen‐1‐acetic acid (NAA), to elucidate the role of the KDEL sequence and the helix at the C‐terminus. The KDEL sequence weakens the intermolecular interactions between the monomers but stabilizes the C‐terminal helix. Conformational changes at the C‐terminus occur within the KDEL sequence and are influenced by the binding of the simulated ligands. This observation helps to explain experimental findings on ABP1 interactions with antibodies that are modulated by the presence of auxin, and supports the hypothesis that ABP1 acts as an auxin receptor. Stable hydrogen bonds between the monomers are formed between Glu40 and Glu62, Arg10 and Thr97, Lys39, and Glu62 in all simulations. The amino acids Ile22, Leu25, Trp44, Pro55, Ile130, and Phe149 are located in the binding pocket and are involved in hydrophobic interactions with the ring system of the ligand. Trp151 is stably involved in a face to end interaction with the ligand. The calculated free energy of binding using the linear interaction energy approach showed a higher binding affinity for NAA as compared to IAA. Our simulations confirm the asymmetric behavior of the two monomers, the stronger interaction of NAA than IAA and offers insight into the possible mechanism of ABP1 as an auxin receptor. Proteins 2014; 82:2744–2755. © 2014 Wiley Periodicals, Inc.     

Recent advances in molecular recognition and signal transduction of active peptides: Receptors for opioid peptides

Summary 1. Opioid peptides are a family of structurally related neuromodulators which play a major role in the control of nociceptive pathways. These peptides act through membrane receptors of the nervous system, defined as, and and endowed with overlaping but distinct pharmacological, anatomical and functional properties.2. Recent cloning of an opioid receptor gene family has opened the way to the use of recombinant DNA technology at the receptor level.3. This review focuses on the molecular cloning and functional characterization of opioid receptors and provides first insights into molecular aspects of opioid peptide recognition and signal transduction mechanisms, using the cloned receptors as investigation tools.     

Cloning of a novel neuronally expressed orphan G-protein-coupled receptor which is up-regulated by erythropoietin, interacts with microtubule-associated protein 1b and colocalizes with the 5-hydroxytryptamine 2a receptor

G-protein-coupled receptors (GPCRs) are the largest group of cell surface molecules involved in signal transduction and are receptors for a wide variety of stimuli ranging from light, calcium and odourants to biogenic amines and peptides. It is assumed that systematic genomic data-mining has identified the overwhelming majority of all remaining GPCRs in the genome. Here we report the cloning of a novel orphan GPCR which was identified in a search for erythropoietin-induced genes in the brain as a strongly up-regulated gene. This unknown gene coded for a protein which had a seven-transmembrane topology and key features typical of GPCRs of the A family but a low overall identity to all known GPCRs. The protein, coded ee3, has an unusually high evolutionary conservation and is expressed in neurons in diverse areas of the CNS with relation to integrative functions or motor tasks. A yeast two-hybrid screen for interacting proteins revealed binding to the microtubule-associated protein (MAP) 1b. Coupling to MAP1a has been described for another cognate GPCR, the 5-hydroxytryptamine (5HT) 2a receptor. Surprisingly, we found complete colocalization of ee3 and the 5HT2a receptor. The interaction with MAP1b proved to be critical for the stability or folding of ee3 as in mice lacking MAP1b the ee3 protein was undetectable by immunohistochemistry, although messenger RNA levels remained unchanged. We propose that ee3 is a highly interesting new orphan GPCR with potential connections to erythropoietin and 5HT2a receptor signalling.     

Auxin binding protein: curiouser and curiouser

Auxin is implicated in a variety of plant developmental processes, yet the molecular mechanism of auxin response remains largely unknown. Auxin binding protein 1 (ABP1) mediates cell expansion and might be involved in cell cycle control. Structural modeling shows that it is a β-barrel dimer, with the C terminus free to interact with other proteins. We do not know where ABP1 performs its receptor function. Most ABP1 is detected within the endoplasmic reticulum but the evidence indicates that it functions at the plasma membrane. ABP1 is established as a crucial component of auxin signaling, but its precise mechanism remains unclear.     

玉米根尖细胞液泡膜结合的蛋白激酶的存在及其性质

为了解液泡膜蛋白在植物细胞信号途径中的功能,用新型的非放射性同位素方法从玉米根细胞的高纯度液泡膜上鉴定出一种膜内在的蛋白激酶.这种蛋白激酶具有Ca2+依赖、CaM和磷脂酰丝氨酸不依赖等特性,与已在多种植物中报道的含有类似钙调素结构域的蛋白激酶CDPK相似.离体实验表明其活性的最适pH值为6.5,最适Ca2+浓度为10 μmol/L.从最适pH值和去污剂的影响可以推测出其活性位点朝向胞质一侧.Zn2+对其活性没有明显的抑制作用,说明该激酶缺少某些哺乳动物的蛋白激酶常含有的锌指结构.当液泡膜蛋白在Ca2+和ATP存在的条件下被预磷酸化后,液泡膜H+-ATPase的ATP水解和质子转运过程均被激活.激活的活性可以被碱性磷酸酶逆转.以上结果说明玉米根尖细胞的液泡膜中存在一种可能是CDPK的蛋白激酶.由它造成的Ca2+依赖的磷酸化作用激活了液泡膜H+-ATPase的活性.这些结果将有助于深入研究CDPK在植物细胞信号转导中的功能.     

The genes of plant signal transduction

Due to the enormous importance of plants as a source of both food and raw materials, an understanding of the control of their growth and development is imperative. Basic to this understanding is the identification of the genes that enable the plant to adapt to its environment while at the same time adhering to its basic developmental plan. The aims of this review are first to briefly summarize the various approaches that have been used to identify these plant signaling genes and second to give an overview of the genes that have been cloned so far and what these genes may tell us about the nature of signal transduction in plants.

The advent of modern molecular biology and molecular genetics has revolutionized our ability to unravel the complexities of plant signal transduction pathways. A whole battery of techniques are now available to identify the genes that control the plants development and ability to adapt to its environment.⁶⁵ Each technique has its own strengths and weaknesses and must be carefully selected by the researcher according to the question that he or she would like to ask.     

The role of calcium ions in gravity singal perception and transduction

Ca²⁺ is implicated as a messenger in coupling various environmental stimuli, such as gravity and light, to response. In recent years, it has become evident that Ca²⁺ plays a central role in all three phases of gravitropism – perception, transduction and response. The root cap, which is known to contain high amounts of Ca²⁺ and calmoduin, is the primary site of gravity preeception. The possible role of phosphoinositide turnovr and Ca²⁺ and Ca²⁺ calmodulin-dependent enzymes such as Ca²⁺– ATPase and protein kinases in gravitropsim is discussed. A model is proposed to describe the role of Ca²⁺ in both normal and light-dependnt gravity response in roots.