新型乙烯受体抑制剂—1—甲基环丙烯在采后园艺作物中的应用

近年来,随着1－甲苯环丙烯（1－methylcyclopropene,1-MCP)作为乙烯受体抑制剂的发现,为控制乙烯敏感型的采后果实后熟和采后蔬菜,切花衰老提供了亲的技术手段,文章从1－MCP的作用机理和特点对其在采后园艺作物中的应用前景作了简述。     

1—甲基环丙烯对红富士苹果酶促褐变的影响（简报）

红富士苹果经1－MCP处理后褐变与多酶氧化酶和脂氧合酶的活性密切相关。1－MCP推迟苹果呼吸高峰的出现,阻止硬度下降和褐变。     

低温对梨(Pyrus communis L.)果实后熟过程中乙烯合成和反应的影响(英文)

Passe Crassane梨果实采后需经过 6 0～ 80d的低温处理才能正常后熟。为了明确低温促进果实成熟的机理 ,对果实进行了低温和低温结合 1 MCP(1 甲基环丙烯 ,乙烯作用抑制剂 )和丙烯 (乙烯类似物 )处理。研究发现 :果实经低温处理后 ,乙烯合成前体———ACC含量大幅度升高 ,而未经低温处理的果实 ,无论贮藏在空气中或用丙烯 1 0 0 0μl/L处理 ,果实中ACC、M ACC含量均保持较低水平。但冷藏前用 1 MCP处理可抑制冷藏果实或冷藏后升温的果实ACC含量的增高。这说明果实的后熟过程与低温和依赖乙烯的ACC合成酶的活性和基因的表达密切相关。未经冷藏的果实于 2 0℃下用丙烯处理 ,果实不能自发合成乙烯 ,但当果实经过冷藏后再用丙烯处理 ,则果实对丙烯的反应能力随冷藏时间延长而增强。为了进一步了解低温诱导的乙烯反应过程。我们对乙烯受体基因进行了研究。定量PCR分析结果表明 ,与拟南芥ETR1同源的基因的表达不受低温的调节。但冷藏后升温 ,或在升温后用丙烯处理时 ,mRNA含量降低。这些结果说明 ,低温可能是通过影响乙烯信号转导途径下游的其它因子而调节依赖乙烯的ETR1基因和ACC合成酶基因的表达 ,从而影响果实的成熟过程     

欧洲云杉胚性愈伤组织培养中乙烯的释放及其作用

在欧洲云杉胚性愈伤组织诱导培养中,有乙烯不断释放。以3μmol·L-1氨氧乙基乙烯基甘氨酸（AVG）、30μmol·L－1AgNO3处理时,乙烯的释放量分别减少88．2％和32．9％;以30μmol·L－1乙烯丰处理,乙烯释放增加70．4％。乙烯释放量的变化对胚性愈伤组织的诱导率无显著的抑制或促进效果。乙烯的变化对胚性细胞的显微形态无显著影响。     

趋化因子与T细胞的分化、迁移及活化

趋化因子在T细胞的分化,迁移和活化中担任重要角,SDF－1,ELC,SLC,TECK,MDC等在T细胞,胸腺中分化的不同阶段发挥着不同的趋化作用。而SLC,ELC共同肩负着T细胞在二级淋巴器官内的分布。此外,许多趋化因子SDF－1,MIP－1,MCP－1,RANTES等亦在DC与T细胞的相互作用,T细胞的激活,极化,效应中起着重要的调节作用。     

甲基化受体蛋白MCP2923在睾丸酮丛毛单胞菌CNB-1趋化过程中的作用

【目的】MCP2923是睾丸酮丛毛单胞菌(Comamonas testosteroni)CNB-1的一种甲基化趋化受体蛋白,本研究旨在阐明其在CNB-1菌株趋化过程中的作用。【方法】利用游动平板法(swimming plate)检测了CNB-1及其MCP突变菌株CNB-1?20、CNB-1?MCP2923、CNB-1?20/p DSK519-MCP2923、CNB-1?20/p BBR1MCS-2-MCP2923和CNB-1?20/p BBR1MCS-2-MCP2923?LBD对35种芳香族化合物以及9种小分子有机酸的趋化性;进一步利用Agarose-in-plug法表征了MCP2923介导的对芳香族化合物的趋化表型;结合生物信息学分析,对MCP2923配体结合结构域(MCP2923LBD)进行了克隆、表达和纯化,利用等温滴定量热法(ITC)检测了MCP2923LBD与原儿茶酸等11种化合物的相互作用。【结果】CNB-1对原儿茶酸、4-羟基苯甲酸等12种芳香族化合物以及顺乌头酸等9种TCA循环中间代谢产物具有强、中强和弱3个层次的趋化表型;敲除MCP2923基因减弱了菌株对上述趋化诱导物的表型;将MCP2923基因回补到CNB-1?20菌株中可回补菌株对15种趋化效应物的表型,敲除MCP2923基因的配体结合区丧失了对15种趋化物的表型回补能力。虽然Agarose-in-plug法检测到了菌株对原儿茶酸和4-羟基苯甲酸的趋化表型,但ITC未能检测到原儿茶酸和4-羟基苯甲酸等11种化合物与MCP2923LBD直接的相互作用。【结论】MCP2923可引发CNB-1菌株对多种芳香族化合物以及小分子有机酸的趋化表型,且MCP2923LBD在这个过程中起关键作用;由于ITC的结果不能证明MCP2923LBD与芳香化合物和小分子有机酸等效应物的直接结合,推测MCP2923引发CNB-1趋化作用的机制不同于已报道的MCP2201和MCP2901的作用方式,其确切机制还有待于进一步深入研究。     

三种苦瓜多糖的体外发酵特性比较研究

采用体外发酵技术评价分段醇沉提取的3种苦瓜多糖(MCP1、MCP2和MCP3,乙醇终浓度分别为45%、60%和75%)对三元猪盲肠食糜的发酵特性和发酵产物的影响。于不同发酵时间点记录产气量,48 h后检测发酵液pH值、NH3和短链脂肪酸(SCFA)含量。结果表明,MCP1和MCP2发酵动力学参数最优,显著优于葡萄糖和空白对照组(P0.05);MCP2和葡萄糖组pH值最低,MCP1和葡萄糖组的NH3含量最低;葡萄糖组的丙酸、异丁酸和SCFA总量显著高于其它各组(P0.05);MCP2的乙酸、异丁酸和SCFA总量显著高于其它多糖组(P0.05)。结果提示,MCP1和MCP2是2种理想的可被盲肠微生物利用的碳源,并可改变微生物发酵产生的SCFA含量与组成。     

趋化细胞因子及其受体——结构与功能的进展

趋化细胞因子（chemokine）之分子一级结构、cDNA克隆及其基因结构研究确立了其在功能上具选择特异性的α和β亚家族。LPS、IL－1、TNF、IL－4和INF等对其基因的表达起调节作用。α亚家族的代表IL－8基因5’－旁侧区中－94和－71碱基对之间的核苷酸元件为其基因转录激活所必需。IL－8分子N－端的ELR基序为其受体识别所必备。编码IL－8RA和RB、MIP－1αR、MCP－1RA和RB之cDNA已分离获得。G－CSF和LPS可调节IL－8受体基因的表达。     

乙烯消减盐渍胁迫对苜蓿种子萌发的抑制作用

在无盐条件下,外源乙烯对苜蓿种子萌发有促进作用,但对最终发芽率无影响。盐渍严重抑制苜蓿种子萌发,加入１～５０μｌ／Ｌ（ｖ／ｖ）外源乙烯或０．１～５．０ｍｍｏｌ／Ｌ１－氨基环丙烷－１－羧酸（ＡＣＣ）或５～１００ｍｇ／Ｌ（ｗ／ｖ）乙烯利（ＥＴＨ）均能极显著地减轻ＮａＣｌ对苜蓿种子萌发的抑制作用。激动素（ＫＴ）也有类似作用,并能促进萌发种子的乙烯产生,它与ＡＣＣ一起使用,则对种子萌发和乙烯产生均显示加成作用。在ＮａＣｌ胁迫下,应用乙烯和乙烯利虽有利萌发,但幼芽鲜重和下胚轴长度明显低于无盐对照。     

苦瓜多糖的提取、分离纯化及组成性质

正交实验确定提取工艺后,用热水提取法得到苦瓜多糖(MCP).对MCP进行DEAE-32离子交换层析分离,得到3个多糖组分MCP1、MCP2和MCP3. 进一步采用Sephacryl S-400凝胶层析进行分离,经凝胶层析和高效液相色谱检测表明,MCP1、MCP2为均一性多糖组分.通过高效液相凝胶色谱法测定了两者的相对分子质量分别为1.16×106和7.45×105.用PMP衍生化法测定其单糖,结果表明: MCP1系由Man、Rham、GlcUA、GalUA、Glu、Gal、Xyl、Ara等单糖组成的杂多糖,摩尔比为1.03:2.93:1.00:14.95:2.16:30.70:2.85:4.50.MCP2系由Rham、GalUA、Gal、Xyl、Ara等单糖组成的杂多糖,对应的摩尔比为1.63:21.88:4.66:1.00:1.29.紫外光谱表明该多糖不含蛋白质和核酸.     

Possible modulation of Arabidopsis ETR1 N-terminal signaling by CTR1

The mitogen-activated protein kinase kinase kinase (MAPKKK) Constitutive Triple-Response1 (CTR1) plays a key role in mediating ethylene receptor signaling via its N-terminal interaction with the ethylene receptor C-terminal histidine kinase (HK) domain. Loss-of-function mutations of CTR1 prevent ethylene receptor signaling, and corresponding ctr1 mutants show a constitutive ethylene response phenotype. We recently reported in Plant Physiology that expression of the truncated ethylene receptor Ethylene Response1 (ETR1) isoforms etr11-349 and dominant ethylene-insensitive etr1-11-349, lacking the C-terminal HK and receiver domains, both suppressed the ctr1 mutant phenotype. Therefore, the ETR1 N terminus is capable of receptor signaling independent of CTR1. The constitutive ethylene response phenotype is stronger for ctr1-1 than ctr1-1 lines expressing the etr11-349 transgene, so N-terminal signaling by the full-length but not truncated ETR1 is inhibited by ctr1-1. We address possible modulations of ETR1 N-terminal signaling with docking of CTR1 on the ETR1 HK domain.     

Ethylene-promoted formation of aerenchyma in seedling roots of Zea mays L. under aerated and non-aerated conditions

The role of ethylene in the formation of lysigenous cortical cavities (aerenchyma) in seedling roots of Zea mays L. cv. Capella, has been studied under aerated and non-aerated conditions. Passing roots from air to aerated water or from an aerated nutrient solution to a non-aerated solution, promoted cavity formation and was accompanied by an increase of the endogenous ethylene concentration. When the endogenous ethylene concentration of roots in aerated nutrient solutions, which otherwise would not produce much cavities, was enhanced by applying ethylene gas (0.1 and 1.0 μl 1^-1 in air) or the ethylene precursor 1-aminocyclopropane-1-car-boxylic acid, cavity formation was promoted. When, on the contrary, the endogenous ethylene concentration of the roots was reduced by adding the inhibitors of ethylene biosynthesis, cobalt ions and aminooxyacetic acid, or when the ethylene action was prevented by silver ions, cavity formation was prevented. It is concluded that endogenous ethylene controls the induction of cavity formation in the roots.     

Control of ethylene activity in various plant systems by structural analogues of 1-methylcyclopropene

Two structural analogues of 1-methylcyclopropene (1-MCP), 1-ethylcyclopropene (1-ECP) and 1-propylcyclopropene (1-PCP) were found to inhibit ethylene action and thereby the responses to ethylene in various plant systems. When applied prior to exposure to ethylene, the analogues considerably delayed ethylene-induced ripening of avocado and tomato fruits, delayed citrus leaf explants abscission and reversed ethylene-induced swelling and inhibition of elongation in etiolated pea plants. The analogues exerted their effect in a concentration-depended manner, at a range of several parts per million. Of the two analogues, 1-ECP was found in all cases more potent than 1-PCP but less potent then the mother compound 1-MCP. It is proposed that the analogues inhibit ethylene action by competing for the sites of binding on the ethylene receptor, similar to the mode of action suggested for 1-MCP. Findings revealed in this study imply that the competition of ethylene and the analogues for the ethylene site of binding is of a non-competitive nature. The analogues effectively inhibited ethylene action only if applied before the plant material was exposed to ethylene, or in the case of fruits shortly after harvest. Simultaneous application of the analogues and ethylene reduced the inhibitory effect of the analogues. Application of the analogues after exposure to ethylene or after fruit ripening had nullified the inhibitory effect of the analogues. Ripening of fruits, treated with the analogues, was inhibited for a finite period of time after which the fruits ripened normally. This resumption of ripening ability is attributed to presence of free binding sites on the ethylene receptor at the point of recovery from the inhibition. As the analogues are volatile, non-corrosive, non-toxic, odorless compounds and effective at minute concentrations, they can be considered promising candidates for practical use.     

Rapid induction of ethylene biosynthesis in cultured parsley cells by fungal elicitor and its relationship to the induction of phenylalanine ammonia-lyase

The biosynthesis of ethylene was examined in suspension-cultured cells of parsley (Petroselinum hortense) treated with an elicitor from cell walls of Phytophthora megasperma. Untreated cells contained 50 nmol g^-1 of the ethylene precursor, 1-aminocyclopropane-1-carboxylic acid (ACC), and produced ethylene at a rate of about 0.5 nmol g^-1 h^-1. Within 2 h after addition of elicitor to the culture medium, the cells started to produce more ethylene and accumulated more ACC. Exogenously added ACC did not increase the rate of ethylene production in control or elicitor-treated cells, indicating that the enzyme converting ACC to ethylene was limiting in both cases. The first enzyme in ethylene biosynthesis, ACC synthase, was very rapidly and transiently induced by the elicitor treatment. Its activity increased more than tenfold within 60 min. Density labelling with ²H₂O showed that this increase was caused by the denovo synthesis of the enzyme protein. Cordycepin and actinomycin D did not affect the induction of ACC synthase, indicating that the synthesis of new mRNA was not required. The peak of ACC-synthase activity preceded the maximal phenylalanine ammonia-lyase (PAL) activity by several hours. Exogenously supplied ethylene or ACC did not induce PAL. However, aminoethoxyvinylglycine, an inhibitor of ACC synthase, suppressed the rise in ethylene production in elicitor-treated cells and partially inhibited the induction of PAL. Exogenously supplied ACC reversed this inhibition. It is concluded that induction of the ethylene biosynthetic pathway is a very early symptom of elicitor action. Although ethylene alone is not a sufficient signal for PAL induction, the enhanced activity of ACC synthase and the ethylene biosynthetic pathway may be important for the subsequent induction of PAL.Abbreviations ACC 1-aminocyclopropane-1-carboxylic acid - AVG aminoethoxyvinylglycine - PAL phenylalanine ammonia-lyase     

GhXB38D represses cotton fibre elongation through ubiquitination of ethylene biosynthesis enzymes GhACS4 and GhACO1

Ethylene plays an essential role in the development of cotton fibres. Ethylene biosynthesis in plants is elaborately regulated by the activities of key enzymes, 1-aminocyclopropane-1-carboxylate oxidase (ACO) and 1-aminocyclopropane-1-carboxylate synthase (ACS); however, the potential mechanism of post-translational modification of ACO and ACS to control ethylene synthesis in cotton fibres remains unclear. Here, we identify an E3 ubiquitin ligase, GhXB38D, that regulates ethylene biosynthesis during fibre elongation in cotton. GhXB38D gene is highly expressed in cotton fibres during the rapid elongation stage. Suppressing GhXB38D expression in cotton significantly enhanced fibre elongation and length, accompanied by the up-regulation of genes associated with ethylene signalling and fibre elongation. We demonstrated that GhXB38D interacts with the ethylene biosynthesis enzymes GhACS4 and GhACO1 in elongating fibres and specifically mediates their ubiquitination and degradation. The inhibition of GhXB38D gene expression increased the stability of GhACS4 and GhACO1 proteins in cotton fibres and ovules, resulting in an elevated concentration of ethylene. Our findings highlight the role of GhXB38D as a regulator of ethylene synthesis by ubiquitinating ACS4 and ACO1 proteins and modulating their stability. GhXB38D acts as a negative regulator of fibre elongation and serves as a potential target for enhancing cotton fibre yield and quality through gene editing strategy.     

Accumulation of 1-(malonylamino)cyclopropane-1-carboxylic acid in ethylene-synthesizing tobacco leaves

During the hypersensitive reaction of Samsun NN tobacco to tobacco mosaic virus (TMV) the inoculated leaves synthesize large quantities of ethylene. At the same time, 1-(malonylamino)cyclopropane-1-carboxylic acid (MACC), a conjugate of the ethylene precursor 1-aminocyclopropane-1-carboxylic acid (ACC) accumulates. Smaller amounts of MACC are formed concomitant with ethylene synthesis during the normal development of tobacco leaves. The conjugate appears neither to be hydrolysed to liberate ACC, nor to be transported to other plant parts. Its accumulation thus reflects the history of the operation of the pathway of ethylene synthesis in the leaf. In floating leaf discs exogenously applied ACC was converted only slowly to both ethylene and MACC. More ethylene and less MACC were produced in darkness than in light, suggesting that environmental conditions may influence the ratio at which ACC in converted to either ethylene or MACC.     

Involvement of RTE1 in conformational changes promoting ETR1 ethylene receptor signaling in Arabidopsis

Ethylene is an important regulator of plant growth, development and responses to environmental stresses. Arabidopsis perceives ethylene through five homologous receptors that negatively regulate ethylene responses. RTE1, a novel gene conserved in plants, animals and some protists, was recently identified as a positive regulator of the ETR1 ethylene receptor. Here, we genetically analyze the dependence of ETR1 on RTE1 in order to obtain further insight into RTE1 function. The function of RTE1 was found to be independent and distinct from that of RAN1, which encodes a copper transporter required for ethylene receptor function. We tested the ability of an rte1 loss-of-function mutation to suppress 11 etr1 ethylene-binding domain mis-sense mutations, all of which result in dominant ethylene insensitivity due to constitutive signaling. This suppression test uncovered two classes of etr1 mutations -RTE1-dependent and RTE1-independent. The nature of these mutations suggests that the ethylene-binding domain is a possible target of RTE1 action. Based on these findings, we propose that RTE1 promotes ETR1 signaling through a conformational effect on the ethylene-binding domain.