甲虫抗冻蛋白热滞活性的二维吸附结合模型

甲虫抗冻蛋白是一种具有规则结构的昆虫抗冻蛋白。在相同浓度条件下,甲虫抗冻蛋白比鱼类抗冻蛋白有更高的热滞活性,目前已成为人们重点研究的一类抗冻蛋白。根据甲虫抗冻蛋白的结构特点及其在冰晶表面的吸附模式,应用二维吸附结合模型计算分析了具有6￣11个β-螺旋(β-helix)结构片段的甲虫抗冻蛋白变体分子,得到了它们的热滞活性随溶液浓度变化的规律,特别是热滞活性与甲虫抗冻蛋白的β-螺旋结构片段数的关系。结果显示,抗冻蛋白在冰晶表面的覆盖度是一个影响其热滞活性的重要因素。     

昆虫抗冻蛋白: 规则结构适应功能

抗冻蛋白在环境温度低于体液熔点时能够结合到生物体内的冰核表面,通过限制冰核生长和抑制冰晶重结晶而保护有机体免受结冰引起的伤害。与其他生物抗冻蛋白比较,昆虫抗冻蛋白有很强的活性,结构上具有显著特征,如一级结构规律重复,超二级结构为β-螺旋,可与冰晶发生相互作用,具有TXT基序等。该文综述了近年来关于昆虫抗冻蛋白的结构以及分子生物学等方面研究的新进展,讨论了其结构与功能的关系。     

昆虫抗冻蛋白的研究进展

抗冻蛋白是一类与冰晶有亲合力,能够与冰晶结合并抑制冰晶生长的蛋白或糖蛋白。自20世纪60年代以来,研究人员已经分别从鱼类、昆虫、植物、真菌和细菌中发现多种抗冻蛋白。其中已知鱼类抗冻蛋白有5种,也是研究最详细的。但是,近几年来发现昆虫抗冻蛋白活性普遍比较高,因此受到研究人员重视,研究取得了较快的发展。主要讨论昆虫抗冻蛋白的结构特点、抗冻活性、作用机制和应用,并分析目前的研究现状提出一些待解决的问题,以期望对昆虫抗冻蛋白的研究进行比较系统化的整理。     

昆虫抗冻蛋白的研究

抗冻蛋白是具有热滞活性,能结合并抑制冰晶生长和抑制冰的重结晶的一类蛋白质。近几年来,昆虫抗冻蛋白的研究取得了较快的发展,本文通过分析昆虫抗冻蛋白的结构特点、抗冻活性、作用机制,并讨论了抗冻蛋白在食品工业、医学、基因工程方面的应用。结果表明,昆虫抗冻蛋白虽然结构呈多样性,但有很多关键的残基具有保守性,对维持抗冻蛋白结构和功能的完整性发挥着重要的作用;抗冻蛋白是由多基因家簇编码的。其作用机制主要是吸附一抑制机制,抗冻蛋白依靠氢键吸附到冰晶格,抑制冰晶生长;昆虫抗冻蛋白的应用具有很广阔的前景。     

昆虫抗冻蛋白基因的克隆与表达研究进展

产生抗冻蛋白(antifreeze protein,AFP)是许多昆虫抵御寒冷的一种重要机制。昆虫抗冻蛋白基因的克隆和表达是研究抗冻蛋白活性和功能的主要途径。文章归纳GenBank所登录的昆虫抗冻蛋白基因及其特点,总结昆虫抗冻蛋白基因的天然表达和基因工程表达方面尚未明确或需要克服的一些问题。目前在GenBank注册的昆虫抗冻蛋白基因约100个,集中于9种昆虫隶属鞘翅目3个科和鳞翅目1个科。昆虫抗冻蛋白基因具有多拷贝和多同种型(isoforms)的特点。昆虫抗冻蛋白的天然表达具有物种间和同种型间的多样性。基因工程表达昆虫抗冻蛋白需要克服表达量低活性不高的问题。对昆虫抗冻蛋白表达规律的研究有助于全面认识其功能。     

差示扫描量热法分析光滑鳖甲抗冻蛋白ApAFP914 TXT基序对抗冻活性的影响

研究光滑鳖甲抗冻蛋白Ap AFP914及其突变体的原核表达及活性,推测TXT基序的突变对昆虫抗冻蛋白抗冻活性的影响。通过定点突变新疆荒漠昆虫光滑鳖甲抗冻蛋白apafp914基因TXT基序的规则位点个数,并亚克隆至p ET32a原核表达载体,转化大肠杆菌,Ni-NTA纯化得到融合蛋白Trx A-Ap AFP914及3种突变体蛋白;利用Swis S-Model服务器预测分析了Ap AFP914蛋白的三维结构;通过差示扫描量热法测定Trx A-Ap AFP914及其突变体的热滞活性。结果显示,4种融合蛋白分子量均在30 k D左右;且突变蛋白Trx A-A19T具有最高的热滞活性,而突变体Trx A-T33F和Trx A-T3345F的热滞活性显著低于未突变的Trx A-914。研究结果表明昆虫抗冻蛋白的TXT基序越规则其具有的热滞活性越高。     

昆虫抗冻蛋白的分离纯化及特性分析

昆虫抗冻蛋白具有很高的热滞活性,可保护机体免受结冰引起的伤害。昆虫抗冻蛋白的分离纯化多采用凝胶过滤层析、离子交换层析及HPLC等技术,已用于鱼类抗冻蛋白纯化的冰亲和纯化(IAP)技术也可考虑应用于昆虫抗冻蛋白的分离提纯。昆虫抗冻蛋白具有高活性,规则的一级结构及类似的冰晶结合表面等特性。     

昆虫抗冻蛋白的研究进展

抗冻蛋白是具有热滞效应,能结合并抑制新的冰晶生长,能抑制冰的重结晶的一类蛋白质。近几年来,昆虫抗冻蛋白的研究取得了较快的发展,本文就昆虫抗冻蛋白的结构,活性的调控,功能与应用做一综述。     

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 ) …     

应用差示扫描量热法检测昆虫总蛋白的热滞活性

产生抗冻蛋白是寒带昆虫抵御低温的重要机制之一, 但检测其活性仍存在一些困难, 尤其对于个体较小的昆虫样品。为了探索差示扫描量热法是否适于检测昆虫总蛋白的热滞活性, 本研究利用差示扫描量热法对黄粉虫Tenebrio molitor幼虫的总蛋白和血淋巴分别进行了热滞活性检测。结果表明： 黄粉虫总蛋白的热滞活性（0.49~0.98℃）要低于血淋巴（2.54~4.34℃）。通过这种方法, 进一步检测了3种在内蒙古大兴安岭林区采集到的越冬昆虫： 稠李巢蛾Yponomeuta evonymallus幼虫、 舞毒蛾Lymantria dispar卵和落叶松八齿小蠹Ips subelongatus成虫。结果发现, 它们都存在热滞活性, 其中稠李巢蛾的热滞活性为0.34~0.43℃, 舞毒蛾的热滞活性为0.35~0.42℃, 落叶松八齿小蠹的热滞活性为0.37~0.40℃, 说明这3种昆虫能以产生抗冻蛋白的方式作为越冬策略之一。本研究表明通过差示扫描量热法检测昆虫总蛋白是否存在热滞活性来判断抗冻蛋白的存在是可行的。     

Antifreeze proteins in higher plants

Overwintering plants produce antifreeze proteins (AFPs) having the ability to adsorb onto the surface of ice crystals and modify their growth. Recently, several AFPs have been isolated and characterized and five full-length AFP cDNAs have been cloned and characterized in higher plants. The derived amino acid sequences have shown low homology for identical residues. Theoretical and experimental models for structure of Lolium perenne AFP have been proposed. In addition, it was found that the hormone ethylene is involved in regulating antifreeze activity in response to cold. In this review, it is seen that the physiological and biochemical roles of AFPs may be important to protect the plant tissues from mechanical stress caused by ice formation.     

Antifreeze protein from freeze-tolerant grass has a beta-roll fold with an irregularly structured ice-binding site

The grass Lolium perenne produces an ice-binding protein (LpIBP) that helps this perennial tolerate freezing by inhibiting the recrystallization of ice. Ice-binding proteins (IBPs) are also produced by freeze-avoiding organisms to halt the growth of ice and are better known as antifreeze proteins (AFPs). To examine the structural basis for the different roles of these two IBP types, we have solved the first crystal structure of a plant IBP. The 118-residue LpIBP folds as a novel left-handed beta-roll with eight 14- or 15-residue coils and is stabilized by a small hydrophobic core and two internal Asn ladders. The ice-binding site (IBS) is formed by a flat beta-sheet on one surface of the beta-roll. We show that LpIBP binds to both the basal and primary-prism planes of ice, which is the hallmark of hyperactive AFPs. However, the antifreeze activity of LpIBP is less than 10% of that measured for those hyperactive AFPs with convergently evolved beta-solenoid structures. Whereas these hyperactive AFPs have two rows of aligned Thr residues on their IBS, the equivalent arrays in LpIBP are populated by a mixture of Thr, Ser and Val with several side-chain conformations. Substitution of Ser or Val for Thr on the IBS of a hyperactive AFP reduced its antifreeze activity. LpIBP may have evolved an IBS that has low antifreeze activity to avoid damage from rapid ice growth that occurs when temperatures exceed the capacity of AFPs to block ice growth while retaining the ability to inhibit ice recrystallization.     

Structure and evolutionary origin of Ca(2+)-dependent herring type II antifreeze protein

In order to survive under extremely cold environments, many organisms produce antifreeze proteins (AFPs). AFPs inhibit the growth of ice crystals and protect organisms from freezing damage. Fish AFPs can be classified into five distinct types based on their structures. Here we report the structure of herring AFP (hAFP), a Ca(2+)-dependent fish type II AFP. It exhibits a fold similar to the C-type (Ca(2+)-dependent) lectins with unique ice-binding features. The 1.7 A crystal structure of hAFP with bound Ca(2+) and site-directed mutagenesis reveal an ice-binding site consisting of Thr96, Thr98 and Ca(2+)-coordinating residues Asp94 and Glu99, which initiate hAFP adsorption onto the [10-10] prism plane of the ice lattice. The hAFP-ice interaction is further strengthened by the bound Ca(2+) through the coordination with a water molecule of the ice lattice. This Ca(2+)-coordinated ice-binding mechanism is distinct from previously proposed mechanisms for other AFPs. However, phylogenetic analysis suggests that all type II AFPs evolved from the common ancestor and developed different ice-binding modes. We clarify the evolutionary relationship of type II AFPs to sugar-binding lectins.     

Positive Darwinian Selection Promotes Heterogeneity Among Members of the Antifreeze Protein Multigene Family

A variety of organisms have independently evolved proteins exhibiting antifreeze activity that allows survival at subfreezing temperatures. The antifreeze proteins (AFPs) bind ice nuclei and depress the freezing point by a noncolligative absorption–inhibition mechanism. Many organisms have a heterogeneous suite of AFPs with variation in primary sequence between paralogous loci. Here, we demonstrate that the diversification of the AFP paralogues is promoted by positive Darwinian selection in two independently evolved AFPs from fish and beetle. First, we demonstrate an elevated rate of nonsynonymous substitutions compared to synonymous substitutions in the mature protein coding region. Second, we perform phylogeny-based tests of selection to demonstrate a subset of codons is subjected to positive selection. When mapped onto the three-dimensional structure of the fish antifreeze type III antifreeze structure, these codons correspond to amino acid positions that surround but do not interrupt the putative ice-binding surface. The selective agent may be related to efficient binding to diverse ice surfaces or some other aspect of AFP function. Received: 27 February 2001 / Accepted: 12 September 2001     

A Ca2+-dependent bacterial antifreeze protein domain has a novel beta-helical ice-binding fold

AFPs (antifreeze proteins) are produced by many organisms that inhabit ice-laden environments. They facilitate survival at sub-zero temperatures by binding to, and inhibiting, the growth of ice crystals in solution. The Antarctic bacterium Marinomonas primoryensis produces an exceptionally large(>1 MDa) hyperactive Ca2+-dependent AFP. We have cloned,expressed and characterized a 322-amino-acid region of the protein where the antifreeze activity is localized that shows similarity to the RTX (repeats-in-toxin) family of proteins. The recombinant protein requires Ca2+ for structure and activity, and it is capable of depressing the freezing point of a solution in excess of 2 degrees C at a concentration of 0.5 mg/ml, therefore classifying it as a hyperactive AFP. We have developed a homology-guided model of the antifreeze region based partly on the Ca2+-bound beta-roll from alkaline protease. The model has identified both a novel beta-helical fold and an ice-binding site. The interior of the beta-helix contains a single row of bound Ca2+ ions down one side of the structure and a hydrophobic core down the opposite side. The ice binding surface consists of parallel repetitive arrays of threonine and aspartic acid/asparagine residues located down the Ca2+-bound side of the structure. The model was tested and validated by site-directed mutagenesis. It explains the Ca2+-dependency of the region, as well its hyperactive antifreeze activity. This is the first bacterial AFP to be structurally characterized and is one of only five hyperactive AFPs identified to date.AFPS     

Solution structure of a recombinant type I sculpin antifreeze protein

We have determined the solution structure of rSS3, a recombinant form of the type I shorthorn sculpin antifreeze protein (AFP), at 278 and 268 K. This AFP contains an unusual sequence of N-terminal residues, together with two of the 11-residue repeats that are characteristic of the type I winter flounder AFP. The solution conformation of the N-terminal region of the sculpin AFP has been assumed to be the critical factor that results in recognition of different ice planes by the sculpin and flounder AFPs. At 278 K, the two repeats units (residues 11-20 and 21-32) in rSS3 form a continuous alpha-helix, with the residues 30-33 in the second repeat somewhat less well defined. Within the N-terminal region, residues 2-6 are well defined and helical and linked to the main helix by a more flexible region comprising residues A7-T11. At 268 K the AFP is overall more helical but retains the apparent hinge region. The helical conformation of the two repeats units is almost identical to the corresponding repeats in the type I winter flounder AFP. We also show that while tetracetylated rSS3 has antifreeze activity comparable to the natural AFP, its overall structure is the same as that of the unacetylated peptide. These data provide some insight into the structural determinants of antifreeze activity and should assist in the development of models that explain the recognition of different ice interfaces by the sculpin and flounder type I AFPs.     

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.     

Structure-function relationship in the globular type III antifreeze protein: identification of a cluster of surface residues required for binding to ice.

Antifreeze proteins (AFPs) depress the freezing point of aqueous solutions by binding to and inhibiting the growth of ice. Whereas the ice-binding surface of some fish AFPs is suggested by their linear, repetitive, hydrogen bonding motifs, the 66-amino-acid-long Type III AFP has a compact, globular fold without any obvious periodicity. In the structure, 9 beta-strands are paired to form 2 triple-stranded antiparallel sheets and 1 double-stranded antiparallel sheet, with the 2 triple sheets arranged as an orthogonal beta-sandwich (Sönnichsen FD, Sykes BD, Chao H, Davies PL, 1993, Science 259:1154-1157). Based on its structure and an alignment of Type III AFP isoform sequences, a cluster of conserved, polar, surface-accessible amino acids (N14, T18, Q44, and N46) was noted on and around the triple-stranded sheet near the C-terminus. At 3 of these sites, mutations that switched amide and hydroxyl groups caused a large decrease in antifreeze activity, but amide to carboxylic acid changes produced AFPs that were fully active at pH 3 and pH 6. This is consistent with the observation that Type III AFP is optimally active from pH 2 to pH 11. At a concentration of 1 mg/mL, Q44T, N14S, and T18N had 50%, 25%, and 10% of the activity of wild-type antifreeze, respectively. The effects of the mutations were cumulative, such that the double mutant N14S/Q44T had 10% of the wild-type activity and the triple mutant N14S/T18N/Q44T had no activity. All mutants with reduced activity were shown to be correctly folded by NMR spectroscopy. Moreover, a complete characterization of the triple mutant by 2-dimensional NMR spectroscopy indicated that the individual and combined mutations did not significantly alter the structure of these proteins. These results suggest that the C-terminal beta-sheet of Type III AFP is primarily responsible for antifreeze activity, and they identify N14, T18, and Q44 as key residues for the AFP-ice interaction.     

Solution Structures,Dynamics, and Ice Growth Inhibitory Activity of Peptide Fragments Derived from an Antarctic Yeast Protein

Exotic functions of antifreeze proteins (AFP) and antifreeze glycopeptides (AFGP) have recently been attracted with much interest to develop them as commercial products. AFPs and AFGPs inhibit ice crystal growth by lowering the water freezing point without changing the water melting point. Our group isolated the Antarctic yeast Glaciozyma antarctica that expresses antifreeze protein to assist it in its survival mechanism at sub-zero temperatures. The protein is unique and novel, indicated by its low sequence homology compared to those of other AFPs. We explore the structure-function relationship of G. antarctica AFP using various approaches ranging from protein structure prediction, peptide design and antifreeze activity assays, nuclear magnetic resonance (NMR) studies and molecular dynamics simulation. The predicted secondary structure of G. antarctica AFP shows several α-helices, assumed to be responsible for its antifreeze activity. We designed several peptide fragments derived from the amino acid sequences of α-helical regions of the parent AFP and they also showed substantial antifreeze activities, below that of the original AFP. The relationship between peptide structure and activity was explored by NMR spectroscopy and molecular dynamics simulation. NMR results show that the antifreeze activity of the peptides correlates with their helicity and geometrical straightforwardness. Furthermore, molecular dynamics simulation also suggests that the activity of the designed peptides can be explained in terms of the structural rigidity/flexibility, i.e., the most active peptide demonstrates higher structural stability, lower flexibility than that of the other peptides with lower activities, and of lower rigidity. This report represents the first detailed report of downsizing a yeast AFP into its peptide fragments with measurable antifreeze activities.