植物抗冻蛋白研究进展(综述)

植物抗冻蛋白(AFPs)的研究起步较晚.本文综述植物AFPs的发现过程、理化性质、在植物抗冻生理中的作用及其机制、结构模型及相关的植物基因工程.     

昆虫抗冻蛋白的研究进展

热滞效应(Tberm Hysteresis Action)最早在昆虫研究中发现,后来研究表明,它是抗冻蛋白(Antifreeze Proteins,AFPs)的一种基本性质。和鱼类,植物AFPs相比,昆虫AFPs具有更高 的热滞活性和独特的化学结构特征。昆虫AFPs在昆虫抗冻生理过程中起着相当重要的作用,表现在以下三个方面：①抑制一些冰晶形成;②提高冰冻耐受性;③可能参与水分平衡过程。光周期,气温和湿度是调控AFPs生物合成与降解的三种外部因子,而体内激素的变化可能是直接调节脂肪体合成AFPs的内部因子。     

抗冻蛋白特征、作用机理与预测新进展

抗冻蛋白（antifreezeproteins,AFPs）可以通过抑制冰晶生长保护生物体免受低温冻害,具有重要的生物学意义和应用价值。现在在鱼类、节肢动物、植物及微生物中均发现有AFPs的存在。基于对已有研究文献和相关网络数据的系统调查统计,详细描述了AFPs数据的类别特征,并对其作用机理的研究历史和最新取得的突破性进展作了较为系统的阐述,并对AFPs预测所取得的成果作了介绍,还对AFPs研究的现状和未来研究方向作了讨论和展望。     

抗冻蛋白抗冻活性评价方法的研究进展

抗冻蛋白(AFPs)因其独特的结构和功能特性受到日益广泛的关注。抗冻活性的评价是AFPs研究的关键步骤之一,评价结果的准确性、精确性和可比性直接影响AFPs的后续研究。本文综述了AFPs抗冻活性评价方法的基本原理、分析、比较了不同评价方法之间的优势、不足。未来AFP抗冻活性评价方法发展的重点在于评价方法的标准化,精确性和重现性方面,以期能够推动AFPs研究的发展。     

抗冻蛋白及其在果蔬保鲜中的应用前景

本文介绍抗冻蛋白(Antifreeze Proteins,AFPs)的特性、分类、生理功能及在果蔬保鲜中应用前景。     

新疆沙冬青抗冻蛋白的提取分离及其热滞活性测定

抗冻蛋白被发现于低温环境下生存的生物体中,它能够吸附在冰晶表面并改变冰晶的生长形态,对于增加植物的抗低温胁迫能力有重要作用。用纤维素DE-52离子柱层析提取分离出了冬季新疆沙冬青(Ammopiptanthus nanus)叶片中的抗冻蛋白(AFPs)。差示扫描量热法(DSC)测定结果表明,当蛋白浓度为20mg/ml时,抗冻蛋白的热滞活性(THA)为0·46℃。经SDS-PAGE电泳分析,此抗冻蛋白的分子量为119·24kDa。     

抗冻蛋白研究进展

南北两极的鱼类生活在低于 0℃ (约- 1 .9℃ )的海水中 ,适应于这种环境 ,其体液内有抗冻物质———抗冻蛋白 (ＡＦＰ)或抗冻糖蛋白 (ＡＦＧＰ) ,以防止体液内冰核的形成与生长。在越冬昆虫体内 ,有活性更高的抗冻蛋白。近年来在耐寒植物中也陆续发现了抗冻蛋白。本文将介绍各类抗冻蛋白的结构和生化性质、功能特性、抗冻作用机制、有关抗冻蛋白基因工程研究及抗冻蛋白的应用研究。1 .抗冻蛋白分子结构及生化特性1 .1　ＡＦＧＰ　　ＡＦＧＰ肽链是由Ａｌａ Ａｌａ Ｔｈｒ三肽单位重复组成 ,苏氨酸残基上接双糖基团 [3 Ｏ ( β Ｄ 半乳糖 ) …     

昆虫抗冻蛋白的结构与生物学特性研究

抗冻蛋白(antifreeze proteins AFPs)是一类抑制冰晶生长的蛋白质,它能以非依数性形式降低溶液的冰点而对其熔点影响甚微,因而也被称作热滞蛋白。近几年来对于昆虫抗冻蛋白的研究取得了较快的发展,已有20多种昆虫抗冻蛋白被分离纯化。就昆虫抗冻蛋白的结构特征、生物学特性以及在农业、医学和食品工业等方面的应用进行介绍。     

抗冻蛋白及其在食品中应用的研究进展

抗冻蛋白(AFPs)是具有热滞活性、且能抑制冰晶重结晶的一类蛋白质。由于其特殊的结构和功能,可作为有效的抗冻添加剂应用于冷冻冷藏食品的加工、运输及贮藏过程,以提高食品的质量。本文对近年来有关抗冻蛋白的来源、作用机制以及在食品工业中的应用等方面的研究进展进行了综述。     

抗冻蛋白结构与抗冻机制

抗冻蛋白(amifreeze proteins,AFPs)是20世纪60年代从极地鱼血淋巴中分离的一种大分子抗冻剂,迄今为止科学工作者已从陆地昆虫、植物、细菌和真菌等各类生物中分离到多种抗冻蛋白,并测得了它们的基因序列及一些晶体结构,近些年的工作主要集中在该类蛋白质抗冻机制的研究上。抗冻蛋白具有广泛的应用前景,它不但可以应用于食物的冷鲜贮存及移植器官的低温保存,还可通过转基因提高经济作物的抗冻能力。     

植物抗冻蛋白及抗冻性分子改良

概述了植物抗冻蛋白及其相关基因的研究现状,主要包括植物低温诱导蛋白、具有热滞活性的植物抗冻蛋白及其相关基因的分离、鉴定与表达调控,以及植物抗冻性基因工程研究动态.在此基础上,讨论了该领域研究中的主要问题、发展趋势及近期研究热点.     

The basis for hyperactivity of antifreeze proteins

Antifreeze proteins (AFPs) bind to the surface of ice crystals and lower the non-equilibrium freezing temperature of the icy solution below its melting point. We have recently reported the discovery of three novel hyperactive AFPs from a bacterium, a primitive insect and a fish, which, like two hyperactive AFPs previously recognized in beetles and moths, are considerably better at depressing the freezing point than most fish AFPs. When cooled below the non-equilibrium freezing temperature, ice crystals formed in the presence of any of five distinct, moderately active fish AFPs grow suddenly along the c-axis. Ice crystals formed in the presence of any of the five evolutionarily and structurally distinct hyperactive AFPs remain stable to lower temperatures, and then grow explosively in a direction normal to the c-axis when cooled below the freezing temperature. We argue that this one consistent distinction in the behaviour of these two classes of AFPs is the key to hyperactivity. Whereas both AFP classes bind irreversibly to ice, the hyperactive AFPs are better at preventing ice growth out of the basal planes.     

鱼类抗冻蛋白的研究进展

抗冻蛋白 (AFP)可非依数性地降低溶液冰点 ,对冷冻细胞和胚胎具有高效的保护作用。目前的研究表明 ,不同的鱼类抗冻蛋白尽管都具有降低冰点的活性 ,但在结构和组成上又存在有较大的差异。根据其结构和化学组成 ,一般将它们分为 4大类 :AFP I、AFP II、AFP III和AFP IV。抗冻蛋白的编码基因为基因组中多拷贝基因家族的成员 ,其基因表达在很大程度上要受到季节变化的影响。目前 ,普遍使用吸附抑制假说来解释AFP非依数性降低溶液冰点的分子机制 ,但不同类抗冻蛋白在降低溶液冰点时的作用模式却不尽相同。现就鱼类的 4类抗冻蛋白的结构组成、基因性质、抗冻机制及其在细胞和胚胎冻存中的作用等领域的研究进展进行概括性综述     

抗冻蛋白与植物低温胁迫反应

植物抗冻蛋白是从许多抗冻植物中分离的、参与植物抵御冻害反应的一类新型蛋白.这类抗冻蛋白具有多个亲水性缚冰域,能直接作用于冰晶,阻止冰晶在细胞间隙形成和再结晶.一些植物抗冻蛋白与致病相关蛋白有序列同源性,具有抗冻和抗病双重活性.植物抗冻蛋白的表达和积累,既受控于发育及转录因子调节,又受到低温、短日照、脱水及乙烯等因素的影响.异源超表达抗冻蛋白基因能赋予敏感宿主植物抗冻能力.文中论述了有关植物抗冻蛋白特性和鉴定,抗冻机制和表达调控,以及遗传转化等方面的研究进展.     

Antifreeze proteins in Alaskan insects and spiders

Prior to this study, antifreeze proteins (AFPs) had not been identified in terrestrial arthropods from the Arctic or anywhere in Alaska. The hemolymph of 75 species of insects and six spiders from interior and arctic Alaska were screened for thermal hysteresis (a difference between the freezing and melting points), characteristic of the presence of AFPs. Eighteen species of insects and three spiders were shown to have AFPs. Ten of the insects with AFPs were beetles including the first species from the families Chrysomelidae, Pythidae, Silphidae and Carabidae. In addition, the first Neuropteran to have AFPs was identified, the lacewing Hemerobius simulans together with the second and third Diptera (the first Tipulids) and the second and third Hemiptera, the stinkbug Elasmostethus interstinctus (the first Pentatomid), and the water strider Limnoporus dissortis (the first Gerrid). Prior to this study, 33 species of insects and three spiders had been reported to have AFPs. Most AFP-producing terrestrial arthropods are freeze avoiding, and the AFPs function to prevent freezing. However, some of the AFP- producing insects identified in this study are known to be freeze tolerant (able to survive freezing) to very low temperatures (-40 to -70 degrees C).     

Perturbation of bacterial ice nucleation activity by a grass antifreeze protein

Certain plant-associating bacteria produce ice nucleation proteins (INPs) which allow the crystallization of water at high subzero temperatures. Many of these microbes are considered plant pathogens since the formed ice can damage tissues, allowing access to nutrients. Intriguingly, certain plants that host these bacteria synthesize antifreeze proteins (AFPs). Once freezing has occurred, plant AFPs likely function to inhibit the growth of large damaging ice crystals. However, we postulated that such AFPs might also serve as defensive mechanisms against bacterial-mediated ice nucleation. Recombinant AFP derived from the perennial ryegrass Lolium perenne (LpAFP) was combined with INP preparations originating from the grass epiphyte, Pseudomonas syringae. The presence of INPs had no effect on AFP activity, including thermal hysteresis and ice recrystallization inhibition. Strikingly, the ice nucleation point of the INP was depressed up to 1.9 °C in the presence of LpAFP, but a recombinant fish AFP did not lower the INP-imposed freezing point. Assays with mutant LpAFPs and the visualization of bacterially-displayed fluorescent plant AFP suggest that INP and LpAFP can interact. Thus, we postulate that in addition to controlling ice growth, plant AFPs may also function as a defensive strategy against the damaging effects of ice-nucleating bacteria.     

Partitioning of fish and insect antifreeze proteins into ice suggests they bind with comparable affinity

Antifreeze proteins (AFPs) inhibit the growth of ice by binding to the surface of ice crystals, preventing the addition of water molecules to cause a local depression of the freezing point. AFPs from insects are much more effective at depressing the freezing point than fish AFPs. Here, we have investigated the possibility that insect AFPs bind more avidly to ice than fish AFPs. Because it is not possible to directly measure the affinity of an AFP for ice, we have assessed binding indirectly by examining the partitioning of proteins into a slowly growing ice hemisphere. AFP molecules adsorbed to the surface and became incorporated into the ice as they were overgrown. Solutes, including non-AFPs, were very efficiently excluded from ice, whereas AFPs became incorporated into ice at a concentration roughly equal to that of the original solution, and this was independent of the AFP concentration in the range (submillimolar) tested. Despite their >10-fold difference in antifreeze activity, fish and insect AFPs partitioned into ice to a similar degree, suggesting that insect AFPs do not bind to ice with appreciably higher affinity. Additionally, we have demonstrated that steric mutations on the ice binding surface that decrease the antifreeze activity of an AFP also reduce its inclusion into ice, supporting the validity of using partitioning measurements to assess a protein's affinity for ice.     

Short Communication: Increased gene dosage augments antifreeze protein levels in transgenic Drosophila melanogaster

One of the principal environmental adaptations of certain fishes inhabiting polar and northern coastal waters is the synthesis of antifreeze proteins (AFPs). AFPs bind to and prevent the growth of nascent ice crystals, thus depressing the serum freezing point. The transgenic expression of AFP holds great promise for conferring freeze resistance to commercially important plant and animal species. Since fish at the greatest risk of freezing have multiple AFP gene copies in order to synthesize higher levels of this protein, we have evaluated this evolutionary strategy as a way to maximize AFP expression in a model transgenic host, the fruit fly Drosophila melanogaster. A construct in which AFP genes of the Atlantic wolffish are fused to the Drosophila yolk protein 1,2 promoter/enhancer region was transferred to flies through P-element mediated transformation. Several independent transgenic fly lines were used in genetic crosses to obtain multi-insert lines. Haemolymph freezing point depression (thermal hysteresis) was greater in homozygotes relative to heterozygotes for a given insert. Similarly, multi-insert lines consistently displayed greater haemolymph AFP activity than the single insert lines from which they were derived. The thermal hysteresis value obtained with a fly line harboring 8 AFP gene copies, 0.43 °C, represents the highest such value to date recorded in a transgenic host, and is even higher than the levels found in some AFP-producing fish.     

A hyperactive, Ca2+-dependent antifreeze protein in an Antarctic bacterium

In cold climates, some plants and bacteria that cannot avoid freezing use antifreeze proteins (AFPs) to lessen the destructive effects of ice recrystallization. These AFPs have weak freezing point depression activity, perhaps to avoid sudden, uncontrolled growth of ice. Here, we report on an uncharacteristically powerful bacterial AFP found in an Antarctic strain of the bacterium, Marinomonas primoryensis. It is Ca(2+)-dependent, shows evidence of cooperativity, and can produce over 2 degrees C of freezing point depression. Unlike most AFPs, it does not produce obvious crystal faceting during thermal hysteresis. This AFP might be capable of imparting freezing avoidance to M. primoryensis in ice-covered Antarctic lakes. A hyperactive bacterial AFP has not previously been reported.