35种石斛兰观赏价值评价

对35种石斛兰的花期长短、花色、花香、花朵数量及花形态、叶形态和植株形态等观赏性状进行描述和数据采集。根据观赏性状可将其按花期长短、香气浓淡、花朵数量多少、花形态大小等进行归类,并综合评价得出各方面表现较佳的6种观花型石斛兰资源。     

植物ABCB亚家族生物学功能研究进展

ABC转运蛋白超家族结构和功能复杂多样, 包含ABCA-ABCH八个亚家族。ABCB是ABC转运蛋白的一个亚家族, 多数定位于质膜, 少数定位于线粒体膜或叶绿体膜。ABCB与其它生长素转运蛋白(AUX1/LAX、PIN)共同参与调控植物生长素的极性运输, 在植物生长发育的各个阶段发挥作用。此外, ABCB转运蛋白还调控植物的向性运动和重金属抗性等过程。近年来, 随着越来越多植物全基因组测序的完成, ABCB亚家族在禾谷类单子叶植物水稻(Oryza sativa)、玉米(Zea mays)和高粱(Sorghum bicolor)中的生物学功能开始有少量报道, 然而多数ABCB转运蛋白的功能尚未得到阐释。该文对拟南芥(Arabidopsis thaliana)和禾谷类作物ABCB转运蛋白的研究进展进行综述, 以期为全面揭示ABCB亚家族生物学功能提供线索。     

植物ABCB亚家族生物学功能研究进展

ABC转运蛋白超家族结构和功能复杂多样, 包含ABCA-ABCH八个亚家族。ABCB是ABC转运蛋白的一个亚家族, 多数定位于质膜, 少数定位于线粒体膜或叶绿体膜。ABCB与其它生长素转运蛋白(AUX1/LAX、PIN)共同参与调控植物生长素的极性运输, 在植物生长发育的各个阶段发挥作用。此外, ABCB转运蛋白还调控植物的向性运动和重金属抗性等过程。近年来, 随着越来越多植物全基因组测序的完成, ABCB亚家族在禾谷类单子叶植物水稻(Oryza sativa)、玉米(Zea mays)和高粱(Sorghum bicolor)中的生物学功能开始有少量报道, 然而多数ABCB转运蛋白的功能尚未得到阐释。该文对拟南芥(Arabidopsis thaliana)和禾谷类作物ABCB转运蛋白的研究进展进行综述, 以期为全面揭示ABCB亚家族生物学功能提供线索。     

植物ABC转运蛋白及其在Al胁迫下的功能研究进展

ABC(ATP-Binding Cassette)转运蛋白家族是目前已知最大、功能最广泛的蛋自家族,能利用水解ATP的能量来参与生物体内多种物质的转运,这一基因家族成员在哺乳动物和微生物中已广泛鉴定,在植物中的研究是一个相对较新的研究领域.铝是酸性土壤作物生产的一个主要的限制因素,ABC转运蛋白在植物铝耐受性方面有重要作用.该文主要对ABC转运蛋白的特点、生物学功能及植物ABC转运蛋白在Al胁迫下的作用进行了综述,并分析其存在的问题,展望今后可能开展的研究方向.     

拟南芥ABC转运类蛋白家族的分子进化、表达模式和蛋白功能网络预测分析

ABC转运蛋白又称腺苷三磷酸结合盒转运蛋白(ATP-binding cassette transporters),该基因家族是目前已知最大、最古老的蛋白家族之一,在植物中ABC转运蛋白种类繁多、结构复杂、功能多样,涉及植物一切的生命活动过程。本研究系统介绍了拟南芥中131个ABC转运蛋白的亚家族分类、系统命名、蛋白大小以及蛋白亚细胞定位等基因信息,在此基础上,分析了ABC转运蛋白基因在染色体分布以及进化过程中发生的复制事件;其次在47个组织器官或发育阶段中聚类分析了ABC转运蛋白的表达模式和各个亚家族分布规律,结果表明ABC转运蛋白基因的表达具有明显的组织特异性和时空特异性,说明在进化过程中该类蛋白功能也进一步发生分化;我们以花药发育过程为例,说明ABC转运蛋白在花药发育过程中具有较高的协调性,在时空和组织上表达受到严格的调控;最后我们分析了ABC转运蛋白亚家族内部和各个亚家族之间可能存在的蛋白相互作用关系,推测ABC半分子转运蛋白形成同源或异源二聚体发挥功能的可能性,进一步说明ABC转运蛋白在蛋白互作水平上也存在功能多样性和严格的调控关系。     

植物高亲和钾离子转运蛋白HAK功能研究进展

钾(Potassium,K)是植物生长发育重要的营养元素,素有"抗逆元素"和"品质元素"之称。在低钾环境下植物主要利用高亲和的转运蛋白进行钾离子的吸收和转运,KUP/HAK/KT作为植物体内钾离子高亲和转运蛋白家族中最大,成员最多的家族,在植物高亲和转运钾离子过程中发挥关键作用。系统阐述了植物KUP/HAK/KT家族的基本情况及其分类、高亲和钾离子转运蛋白HAK的系统发育分析、HAK转运蛋白在提高植物钾吸收,影响植物生长发育,增强植物抵抗生物胁迫和非生物胁迫能力等方面的功能研究,最后展望了钾离子转运蛋白HAK后续有待解决的问题。深入了解HAK钾转运蛋白在植物体内的作用机制对于有效提高钾肥的利用效率,提升作物产量与品质,促进农业发展等方面具有重要的现实意义。     

节肢动物ABC转运蛋白及其介导的杀虫剂抗性

腺苷三磷酸结合盒转运蛋白（ATP-binding cassette transporter),简称ABC转运蛋白（ABC transporter）,是继细胞色素P450单加氧酶、羧酸酯酶、谷胱甘肽S-转移酶之后又一类参与解毒作用的重要蛋白家族,因其在杀虫剂解毒等方面起着非常重要的作用,近年来逐渐受到广泛关注。ABC转运蛋白是一大类跨膜蛋白,其核心结构通常由4个结构域组成,包括2个高度疏水的跨膜结构域（transmembrane domains , TMD）和2个核苷酸结合域（nucleotide binding domains, NBD）。根据序列相似性和保守结构域,可以把ABC转运蛋白家族分为8个亚家族,每个亚家族的成员数及功能不同。这类蛋白在各种生物体内均有分布,其主要功能包括转运物质、信号传导、细胞表面受体及参与细胞内DNA修复,转录及调节基因的表达过程等。此外,近年来的研究表明,ABC转运蛋白的突变或过表达不仅与节肢动物对化学农药的抗药性密切相关,而且在抗Bt毒素方面也起着非常重要的作用,对转Bt作物造成严重威胁。本文综述了节肢动物ABC转运蛋白的结构,ATP水解介导的作用机制,亚家族的分类、结构及生理功能,以及由ABC转运蛋白介导的抗药性研究进展,旨在深入了解ABC转运蛋白的研究现状及其在节肢动物抗药性方面的作用,为阐明节肢动物抗药性机制提供新的理论依据,对改进农业害虫的抗性监测和治理策略也具有一定的指导意义。     

植物PDR型ABC转运蛋白的结构及功能

ATP-结合盒(ATP-binding cassette,ABC)转运蛋白是目前已知最大、功能最广泛的蛋白质家族。多向耐药性(pleiotropic drug resistance,PDR)蛋白是该家族中仅存于植物和真菌中的一个亚族,结构域与其他亚族相反,即核苷酸结合域(nucleotide-binding domain,NBD)位于跨膜结构域(trans-membrane domain,TMD)的N端。目前已发现PDR型转运蛋白具有转运次生代谢产物和参与胁迫反应等方面的功能。植物PDR基因分为5个亚族:I族基因涉及多种生物和非生物胁迫反应,II￣V族基因功能研究甚少。植物PDR基因在器官水平、化学及环境因素影响下具有特异性较好的表达谱。本文系统阐述了植物PDR型转运蛋白基因的进化、结构及其功能,为理解植物PDR型转运蛋白在生物分子转运和复杂生理功能方面提供一个基础框架。     

水稻蔗糖转运载体蛋白(OsSUT2)非跨膜区域特征性序列的融合表达及其抗体制备

植物光合作用产生的蔗糖是植物生长发育的主要碳源物质,还是诱导植物生长发育过程中诸多相关基因表达的特异信号分子[1].蔗糖分子在植物器官及组织间的生理分配维持着整个植物体的正常生长发育[2].植物蔗糖转运载体(sucrosetransporter,SUT)是一类担负着蔗糖分子在细胞间的转运及信号转导的功能性蛋白家族,它在蔗糖的韧皮部装载、沿韧皮部的再吸收、韧皮部卸载和向库器官的转运等跨膜运输以及蔗糖特异信号感应过程中发挥着重要的生理功能[3～5].植物蔗糖转运载体蛋白分布于植物细胞质膜上,该转运载体蛋白含有12个疏水性跨膜结构域,在其氨…     

植物ABCB转运蛋白研究进展

ABC转运蛋白家族是一类通过结合并水解ATP释放能量实现底物的跨膜运输的转运蛋白,它们参与了植物众多的生理代谢过程,根据保守区的进化关系将ABC转运蛋白家族分成8个亚族,其中ABCB转运蛋白为第二大亚族。ABCB 转运蛋白具保守的NBDs结构域,由6个跨膜α-螺旋的疏水跨膜结构域组成了TMDs结构域,形成溶质跨膜的通道,但是其结构、长度与序列则变化多样。按分子大小不同将植物ABCB转运蛋白分为全分子转运蛋白、半分子转运蛋白两类,通过测序发现在拟南芥、水稻和番茄等植物上均有一定比列的ABCB转运蛋白,且行使多种功能。有研究表明,ABCB转运蛋白基因介导镉、铅和铝等重金属离子的转运,提高植物重金属耐性;它直接参与植物体内生长素的运输,从而调控植物高度;它还可能将苹果酸从质体转运到保卫细胞中调节气孔的开合。近年来,越来越多的ABCB转运蛋白被鉴定,但是ABCB亚家族庞大,底物特异性强,转运机制复杂,多数转运蛋白的功能尚未确定。因此,了解ABCB转运蛋白在生命活动过程中的重要性,以及基因表达调控的机制,解析ABCB转运蛋白在响应逆境胁迫过程中的重要作用,以期为植物抗逆性育种提供思路。     

基于主成分分析法的墨兰品种观赏价值评价

以福州地区栽培多年的30个墨兰品种为材料,对其植株高、花色、瓣型等20个观赏性状进行测定和观察,分析墨兰品种观赏性状的变异范围、性状间的相关性以及主成分因子,并利用主成分分析法对30个墨兰品种的观赏价值进行评价。结果表明,不同品种间的16个数量性状均存在不同程度的变异,花部形态存在较大差异,叶片形态和数量变异小;4个质量性状中,花色和叶艺的遗传多样性较高。叶部形态和花部形态的观赏性状间存在显著相关性。20个观赏性状指标可以分为7个主成分因子,分别为株高因子、瓣型因子、花色因子、叶片数因子、花径因子、叶宽因子和叶艺因子,7个主成分因子的方差贡献率累计达全部性状信息的87.35%。通过计算30个品种的重要主成分值并对其进行排序,筛选出4个观赏性状优良的品种,分别为‘白墨’、‘宝山爪’、‘龙梅’和‘金华山’。     

Fungal transporters involved in efflux of natural toxic compounds and fungicides

Survival of microorganisms in natural environments is favored by the capacity to produce compounds toxic to competing organisms and the ability to resist the effects of such toxic compounds. Both factors contribute to a competitive advantage of organisms in ecosystems. All organisms have evolved active transport mechanisms by which endogenous and exogenous toxicants can be secreted. Two major classes of transporter proteins are the ATP-binding cassette (ABC) and the major facilitator superfamily (MFS) transporters. Members of both classes can have broad and overlapping substrate specificities for natural toxic compounds and can be regarded as a "first-line defense barrier" in survival mechanisms. In plant pathogens, these transporters can play an essential role in protection against plant defense compounds during pathogenesis. Also, some transporters actively secrete host-specific and non-host-specific toxins. Remarkably, ABC and MFS transporters can also play a major role in fungicide sensitivity and resistance. Their role in multidrug resistance of Aspergillus nidulans, Candida albicans, and Saccharomyces cerevisiae to azoles and other fungitoxic compounds is well established. Knowledge of ABC and MFS transporters opens possibilities of developing novel strategies for controlling plant diseases, either by modulation of transporter activity or by transgenic expression of transporter genes in plants.     

Altered profile of secondary metabolites in the root exudates of Arabidopsis ATP-binding cassette transporter mutants

Following recent indirect evidence suggesting a role for ATP-binding cassette (ABC) transporters in root exudation of phytochemicals, we identified 25 ABC transporter genes highly expressed in the root cells most likely to be involved in secretion processes. Of these 25 genes, we also selected six full-length ABC transporters and a half-size transporter for in-depth molecular and biochemical analyses. We compared the exuded root phytochemical profiles of these seven ABC transporter mutants to those of the wild type. There were three nonpolar phytochemicals missing in various ABC transporter mutants compared to the wild type when the samples were analyzed by high-performance liquid chromatography-mass spectrometry. These data suggest that more than one ABC transporter can be involved in the secretion of a given phytochemical and that a transporter can be involved in the secretion of more than one secondary metabolite. The primary and secondary metabolites present in the root exudates of the mutants were also analyzed by gas chromatography-mass spectrometry, which allowed for the identification of groups of compounds differentially found in some of the mutants compared to the wild type. For instance, the mutant Atpdr6 secreted a lower level of organic acids and Atmrp2 secreted a higher level of amino acids as compared to the wild type. We conclude that the release of phytochemicals by roots is partially controlled by ABC transporters.     

The diversity of ABC transporter genes across the Phylum Nematoda

It is estimated that one billion people globally are infected by parasitic nematodes, with children, pregnant women, and the elderly particularly susceptible to morbidity from infection. Control methods are limited to de-worming, which is hampered by rapid re-infection and the inevitable development of anthelmintic resistance. One family of proteins that has been implicated in nematode anthelmintic resistance are the ATP binding cassette (ABC) transporters. ABC transporters are characterized by a highly conserved ATP-binding domain and variable transmembrane regions. A growing number of studies have associated ABC transporters in anthelmintic resistance through a protective mechanism of drug efflux. Genetic deletion of P glycoprotein type ABC transporters in Caenorhabditis elegans demonstrated increased sensitivity to anthelmintics, while in the livestock parasite, Haemonchus contortus, anthelmintic use has been shown to increase the expression of ATP transporter genes. These studies as well as others, provide evidence for a potential role of ABC transporters in drug resistance in nematodes. In order to understand more about the family of ABC transporters, we used hidden Markov models to predict ABC transporter proteins from 108 species across the phylum Nematoda and use these data to analyze patterns of diversification and loss in diverse nematode species. We also examined temporal patterns of expression for the ABC transporter family within the filarial nematode Brugia malayi and identify cases of differential expression across diverse life-cycle stages. Taken together, our data provide a comprehensive overview of ABC transporters in diverse nematode species and identify examples of gene loss and diversification in nematodes based on lifestyle and taxonomy.     

The ABC maltose transporter

Bacterial ATP-binding cassette (ABC) transporters and their homologues in eukaryotic cells form one of the largest superfamilies known today. They function as primary pumps that couple substrate translocation across the cytoplasmic membrane to ATP hydrolysis. Although ABC transporters have been studied for more than three decades, the structure of these multicomponent systems is unknown, and the mechanism of transport is not understood. This article reviews one of the most widely studied ABC systems, the maltose transporter of Escherichia coli . A first structural model of the transport channel allows discussion of possible mechanisms of transport. In addition, recent experimental evidence suggests that regulation of gene expression and transport activity is far more complex than expected.     

Availability and applications of <Emphasis Type="Italic">A</Emphasis>TP-binding <Emphasis Type="Italic">c</Emphasis>assette (ABC) transporter blockers

ATP-binding cassette (ABC) transporters encompass membrane transport proteins that couple the energy derived from ATP hydrolysis to the translocation of solutes across biological membranes. The functions of these proteins include ancient and conserved mechanisms related to nutrition and pathogenesis in bacteria, spore formation in fungi, and signal transduction, protein secretion and antigen presentation in eukaryotes. Furthermore, one of the major causes of drug resistance and chemotherapeutic failure in both cancer and anti-infective therapies is the active movement of compounds across membranes carried out by ABC transporters. Thus, the clinical relevance of ABC transporters is enormous, and the membrane transporters related to chemoresistance are among the best-studied members of the ABC transporter superfamily. As ABC transporter blockers can be used in combination with current drugs to increase their efficacy, the (possible) impact of efflux pump inhibitors is of great clinical interest. The present review summarizes the progress made in recent years in the identification, design, availability, and applicability of ABC transporter blockers in experimental scenarios oriented towards improving the treatment of infectious diseases caused by microorganisms including parasites.