生长素极性运输研究进展

高等植物的生长发育受激素的广泛调控,其中生长素的作用尤为独特,因为生长素在植物组织内的浓度梯度是由其极性运输维持的,而正是激素在植物组织的相对含量决定了该组织的发育命运。高等植物体内存在可运输的化学信使的概念首先由Ｄａｒｗｉｎ父子提出。通过对金丝鸟木亡草（Ｐｈａｌａｒｉｓｃａ ｎａｒｉｅｎｓｉｓ）幼苗的向光性的研究,他们认为植物的向光性受到一种可运输的物质的调控［1］。后来发现这一物质是生长素,在自然界中主要存在的形式是ＩＡＡ。到本世纪 30年代,禾谷类植物中的生长素的极性运输得到证实,后来发现所有…     

拟南芥根中生长素极性运输的研究进展

生长素极性运输影响植物的生长和发育,在植物器官形态建成、发育等过程中发挥重要的调控作用.生长素极性运输是一个依赖于生长素运输载体来完成的复杂过程.近年来生长素极性运输载体AUX/LAX蛋白、PIN蛋白家族和MDR/PGP蛋白家族在生长素极性运输中作用的研究日益深入,并且在植物激素联系和转运方面取得了重大发现——PILC蛋白.     

生长素的极性运输

生长素的极性运输李春俭（北京农业大学生物学院，北京１０００９４）ＰＯＬＡＲＡＵＸＩＮＴＲＡＮＳＰＯＲＴＬｉｎＣｈｕｎ－ｊｉａｎ（ＣｏｌｅｇｅｏｆＢｉｏｌｏｇｙ，ＢｅｉｊｉｎｇＡｇｒｉｃｕｌｔｕｒａｌＵｎｉｖｅｒｓｉｔｙ，Ｂｅｉｊｉｎｇ１０００９４）...     

PIN蛋白在生长素极性运输中的作用

PIN蛋白是生长素流出栽体,它在细胞中的不对称分布决定细胞间生长素流方向.PIN蛋白网络系统决定生长素的极性运输,为植物体各部位的细胞提供了特异的位置和方向信息.从细胞水平上介绍PIN蛋白在生长素极性运输中的作用及对PIN蛋白功能调节的研究进展.     

植物生长素的极性运输载体研究进展

生长素极性运输在植物生长发育中起重要的调控作用.植物细胞间的生长素极性运输主要通过生长素运输载体进行调控.该文对近年来有关生长素极性运输载体,包括输入载体AUX/LAX、输出载体PIN、尤其是新近发现的兼有输入和输出载体功能的MDR/PGP等蛋白家族,以及生长素极性运输中PIN与MDR/PGP蛋白间相互作用关系进行综述.     

生长素的生物合成、代谢、受体和极性运输

主要介绍生长素的生命合成,代谢,受体,生长素极性运输和生长响应基因等方面的研究近况。     

类黄酮调节生长素的极性运输(综述)

生长素在植物体内是通过极性运输方式输送的,这个运输过程是一个严格调控的过程.目前对其调控机理尚不了解.植物体内广泛存在的类黄酮类物质影响生长素运输,对生长素运输起负调控作用.     

植物生长素极性运输调控机理的研究进展

生长素极性运输特异地调控植物器官发生、发育和向性反应等生理过程。本文综述和分析了生长素极性运输的调控机制。分子遗传和生理学研究证明极性运输这一过程是由生长素输入载体和输出载体活性控制的。小G蛋白ARF附属蛋白GEF和GAP分别调控输出载体（PINI）和输入载体（AUX1）的定位和活性。并影响高尔基体等介导的细胞囊泡运输系统,小G蛋白ROP也参与输出载体PIN2活性的调节。本文基于作者的研究工作提出小G蛋白在调控生长素极性运输中的可能作用模式。     

植物生长素极性运输调控机理的研究进展

生长素极性运输特异地调控植物器官发生、发育和向性反应等生理过程。本文综述和分析了生长素极性运输的调控机制。分子遗传和生理学研究证明极性运输这一过程是由生长素输入载体和输出载体活性控制的。小G蛋白ARF附属蛋白GEF和GAP分别调控输出载体(PIN1)和输入载体(AUX1)的定位和活性, 并影响高尔基体等介导的细胞囊泡运输系统, 小G蛋白ROP也参与输出载体PIN2活性的调节。本 文基于作者的研究工作提出小G蛋白在调控生长素极性运输中的可能作用模式。     

生长素极性运输的调控及其机制

主要介绍了抑制剂、地球引力、矿质元素和光、温条件对生长素极性运输的调控及生长素极性运输调控机制研究的最新进展。     

Kinetics of polar auxin transport

The movement of auxin in the basipetal and acropetal directions is compared for 4 types of tissue. It is observed that the transport may proceed in either a linear or a non-linear manner with time. The polarity of transport through any given type of tissue increases exponentially with increasing lengths of tissue traversed, suggesting that the polarity of transport is developed as a consequence of the repeated passage through cells. Using the mathematical model of Leopold and Hall, the extent of polarity for individual cells is estimated, and a very small polarity of individual cells is found to be capable of accounting for the marked polarity of whole tissues. It is suggested that transport polarity may be functionally a property of the multicellular structure, being amplified from very small differences in activities at the 2 ends of individual cells.     

Mathematical model of polar auxin transport

Polar auxin transport can be simulated by a model which achieves polarity through the preferential secretion of more auxin from the lower end than from the upper end of each cell. Solution of the model using a computer provides a possible explanation of the differences between the polarity expressed by different tissues and the differences between pieces of different lengths, on the basis of small differences in the polarity of auxin secretion from individual cells. A method of estimating the polarity of individual cells is described.     

On polar auxin transport in plant cells

We present here explicit mathematical formulas for calculating the concentration, mass, and velocity of movement of the center of mass of the plant growth regulator auxin during its polar movement through a linear file of cells. The results of numerical computations for two cases, (a) the conservative, in which the mass in the system remains constant and (b) the non-conservative, in which the system acquires mass at one end and loses it at the other, are graphically presented. Our approach differs from that of Mitchison's (Mitchison 1980) in considering both initial effects of loading and end effects of substance leaving the file of cells. We find the velocity varies greatly as mass is entering or leaving the file of cells but remains constant as long as most of the mass is within the cells. This is also the time for which Mitchison's formula for the velocity, which neglects end effects, reflects the true velocity of auxin movement. Finally, the predictions of the model are compared with two sets of experimental data. Movement of a pulse of auxin through corn coleoptiles is well described by the theory. Movement of auxin through zucchini shoots, however, shows the need to take into account immobilization of auxin by this tissue during the course of transport.     

A role for polar auxin transport in rhizogenesis

Internodal shoot sections of the easy-to-root Forsythia×intermedia cv. Lynwood, and the difficult-to-root Syringa vulgaris cv. Madame Lemoine were used in vitro to investigate the role of polar auxin transport (PAT) in rhizogenesis. Syringa internodes required the distal application of indole-3-acetic acid (IAA), indole-3-butyric acid (IBA) or naphthaleneacetic acid to induce rooting, while 2,4-dichlorophenoxyacetic acid was ineffective. In contrast, Forsythia internodes rooted equally well when IBA was applied at either end of the internode. Using [³H]IAA showed transport of exogenous auxin was basipetal, and that despite similar transport velocities, the intensity of auxin transport in Syringa was greater than in Forsythia. Basipetal transport of exogenous auxin was blocked using the PAT inhibitors 2,3,5-triiodobenzoic acid (TIBA) and naringenin (Nar); where Forsythia proved more sensitive to TIBA, but less so to Nar, in comparison with Syringa. In both species, percentage rooting and the number of roots formed were greater in 5-mm-long internodes than in shorter internodes. The results demonstrate the importance of PAT for root initiation in Syringa, whereas Forsythia tissue appears to be more sensitive to the direct application of auxin.     

Narciclasine modulates polar auxin transport in Arabidopsis roots

Plant development displays an exceptional plasticity and adaptability that involves the dynamic, asymmetric distribution of the phytohormone auxin. Polar auxin flow, which requires transport facilitators of the PIN family, largely contributes to the establishment and maintenance of auxin gradients and mediates multiple developmental processes. Here, we report the effects of narciclasine (NCS), an Amaryllidaceae alkaloid isolated from Narcissus tazetta bulbs, on postembryonic development of Arabidopsis roots. Arabidopsis seedlings grown on NCS showed defects in root gravitropism which correlates with a reduction in auxin transport in roots. Expressions of auxin transport genes were affected and the polar localization of PIN2 protein was altered under NCS treatment. Taken together, we propose that NCS modulates auxin transport gene expression and PIN2 localization, and thus affects auxin transport and auxin distribution necessary for postembryonic development of Arabidopsis roots.     

Nature of cell-to-cell transfer of auxin in polar transport

Summary By application of agar blocks (side blocks) against the inner and outer epidermis of maize (Zea mays L.) coleoptiles whose cuticle has been abraded it is found that radioactive auxin in the polar transport stream exchanges rapidly with the tissue's free space and therefore does not move confined within the symplast. Polar transport of IAA is demonstrable in Avena coleoptile segments plasmolyzed in 0.5 and 0.7 M mannitol, in which most of the plasmodesmatal connections between successive cells in the polar transport pathway appear to have been broken. We conclude that during polar transport IAA probably moves from cell to cell by crossing the plasmalemmas and the free space between successive cells, rather than via plasmodesmata. Auxin in the polar transport stream exchanges rapidly with side blocks by a cyanide-and azide-insensitive, presumably passive, process. A similarly passive uptake takes place into the cells from an external donor. NPA almost completely inhibits efflux from the polar transport stream even though it does not inhibit uptake; its inhibition of efflux is completely reversed by azide or cyanide. These findings are compatible either with the traditional model of polar transport as passive uptake combined with an active basal efflux pump for IAA, or with the model of purely passive polar transport driven by pH and/or potential differences across the plasma membrane, provided certain ad hoc assumptions are made about the characteristics of the IAA anion carrier that would be operating in either model.Abbreviations IAA indoleacetic acid - NPA N-1-naphthylphthalamic acid - TIBA 2,3,5-triiodobenzoic acid     

Inhibition of the polar auxin transport by a morphactin

Summary IAA- and gravity-induced curvatures in coleoptiles are altered by the morphactin methyl-2-chloro-9-hydroxyfluorene-(9)-carboxylate (CFM), the length of the curved part of the coleoptile being greatly reduced. A ring of CFM-containing paste blocks the bud-inhibiting effect of IAA when placed between the bud and the site of IAA application. The IAA-transporting capacity of Helianthus hypocotyl sections, as determined by the classical transport method (agar donors and receivers), is greatly reduced by a pretreatment of the sections with CFM.     

GmPIN-dependent polar auxin transport is involved in soybean nodule development

To overcome nitrogen deficiency, legume roots establish symbiotic interactions with nitrogen-fixing rhizobia that are fostered in specialized organs (nodules). Similar to other organs, nodule formation is determined by a local maximum of the phytohormone auxin at the primordium site. However, how auxin regulates nodule development remains poorly understood. Here, we found that in soybean, (Glycine max), dynamic auxin transport driven by PIN-FORMED (PIN) transporter GmPIN1 is involved in nodule primordium formation. GmPIN1 was specifically expressed in nodule primordium cells and GmPIN1 was polarly localized in these cells. Two nodulation regulators, (iso)flavonoids trigger expanded distribution of GmPIN1b to root cortical cells, and cytokinin rearranges GmPIN1b polarity. Gmpin1abc triple mutants generated with CRISPR-Cas9 showed the impaired establishment of auxin maxima in nodule meristems and aberrant divisions in the nodule primordium cells. Moreover, overexpression of GmPIN1 suppressed nodule primordium initiation. GmPIN9d, an ortholog of Arabidopsis thaliana PIN2, acts together with GmPIN1 later in nodule development to acropetally transport auxin in vascular bundles, fine-tuning the auxin supply for nodule enlargement. Our findings reveal how PIN-dependent auxin transport modulates different aspects of soybean nodule development and suggest that the establishment of auxin gradient is a prerequisite for the proper interaction between legumes and rhizobia.

In soybean, nodule primordium formation involves GmPIN1-mediated polar auxin transport within primordium cells, and nodule enlargement involves the collaboration of GmPIN9d and GmPIN1-dependent auxin transport within nodule vasculature.     

Intracellular localization of the active process in polar transport of auxin

Summary The cytoplasm of maize coleoptile cells was displaced to either the apical or basal ends of the cells by centrifuging (1750xg for 10 min) segments in which protoplasmic streaming had been stopped by pretreatment with cytochalasin B. Centrifugation toward the base of the segment promotes the subsequent basipetal transport of indole-3-acetic acid, whereas apical centrifugation dramatically inhibits this transport. Apical centrifugation neither promotes acropetal transport nor reverses the polarity of auxin transport. Experiments in which the amyloplasts were separated from the bulk of the cytoplasm indicate that the basipetal transport is independent of both the position and pressure exerted by the amyloplasts but is strongly dependent on the amount of cytoplasm at the basal end of the cells. These effects of centrifugation on auxin transport lead to the conclusion that the metabolic component of the transport is a polar secretion of auxin localized in the basal plasma membrane of each cell.     

Phenotypic characterization of a tobacco mutant impaired in auxin polar transport

A mutation in tobacco (Nicotiana tabacum L. cv `Xanthi') called lat (low auxin transport) that changes many morphogenic features throughout the life of the plant has been isolated. Abnormalities were observed in seed development, embryogenesis, cotyledon formation, leaf initiation and development, leaf veination pattern, and flower development. Selfed R₂ lat mutant plants set between 60% and 90% fewer seeds than wild-type tobacco, and about 10% of these seeds did not germinate. Non-germinating seeds contained either abnormal embryos or abnormal endosperm tissues. There was no uniformity in the stage at which embryonic development ceased in the aberrant seeds. Seedlings often revealed abnormal and highly varied phenotypes after germination. In some of these cases, cotyledons were heart-shaped, fused, cup-shaped, or cylindrical. Leaf morphology ranged from normal to cup-shaped, and some leaves occasionally produced shoots from the leaf midvein. Flowers ranged from normal to compound with occasional fused floral parts or split petals. Stamens were sometimes petal-like. This unusual assortment of phenotypic changes suggested that the mutation might affect a basic component of plant metabolism. We found that polar transport of indole-3-acetic acid (IAA) was reduced to about 9–19% of the wild-type level in the inflorescence axis of selfed R₂ lat mutants. In addition, supplementation of 1-naphthaleneacetic acid (NAA) to sterile media suppressed some of the abnormalities of the lat mutation so long as the plants grew there. Similarities in the phenotype of embryos, cotyledon and leaf shapes, translocation of labeled IAA, and response to applied NAA indicate that the lat locus of tobacco may be analogous to the pin locus of Arabidopsis, or produce a protein that functions in the same auxin-transport pathway. Received: 18 March 1997 / Revision received: 1 May 1997 / Accepted: 17 June 1997