基于信号放大技术的适体生物传感器研究进展

信号放大技术因其能实现低浓度分子检测,灵敏度高而在多个研究领域发展非常迅速。而适体作为识别分子已成功应用于多种生物传感器平台,在医疗诊断、环境检测、生化分析中显示出良好的应用前景。近年来,以适体为识别元件的生物传感器越来越受到人们的关注。综述了近3年来基于信号放大技术的适体生物传感器研究新发展。     

场效应晶体管生物传感器在生物医学检测中的应用研究进展*

场效应晶体管生物传感器因其灵敏度高、分析速度快、无标记、体积小、操作简单等特点而受到了很多关注,广泛应用于DNA、蛋白质、细胞、离子等生物识别物的检测。近年来,更有纳米材料和微电子技术在传感器设计中提高传感器的传感性能,场效应晶体管生物传感器朝着高灵敏、微型化、快速化以及多功能化的方向以令人惊叹的速度发展。研究场效应晶体管生物传感器工作原理,阐述近年来场效应晶体管生物传感器在生物医学检测领域中最新的研究进展与应用,探讨场效应晶体管生物传感器克服各种缺陷的应对策略,为该传感器在未来生物医学检测中的开发提供参考。     

乙酰胆碱酯酶性质改变与昆虫抗药性的关系

乙酰胆碱酯酶是生物神经传导中的一种关键性酶,同时又是有机磷和氨基甲酸酯杀虫剂的靶标,因此一直是人们研究的热点。就近年来昆虫乙酰胆碱酯酶(AChE)在生化和分子生物学方面的研究进展、昆虫AChE基因结构及表达的变化对动力学参数、昆虫抗药性的影响机制以及害虫与天敌AChE的比较研究进行了简要综述。     

DNA生物传感器在环境污染监测中的应用

基于生物催化和免疫原理的生物传感器在环境领域中获得了广泛应用.近年来,随着分子生物学和生物技术的发展,人们开发了以核酸探针为识别元件,基于核酸相互作用原理的DNA生物传感器.该传感器可用于受感染微生物的核酸序列分析、优先控制污染物的检测以及污染物与DNA之间相互作用的研究,在环境污染监测中具有潜在的巨大应用前景.简要介绍了核酸杂交生物传感器的基本原理及其在环境微生物和优先控制污染物（priority pollutant）检测中的应用研究进展.     

四种蚜虫AChE的活性及其对抑制剂的敏感度

<正> 乙酰胆碱酯酶AChE是有机磷和氨基甲酸酯杀虫剂的靶标酶。测定单个昆虫AChE的活性及其对抑制剂的敏感性,对于种群AChE变构的抗性遗传学的研究以及抗性昆虫个体的生物化学检测都具有重要意义。作者参照     

荧光纳米生物传感器研究进展

荧光纳米生物传感器检测物质具有灵敏度高、响应迅速、抗干扰性强、无需参比电极等特点而被广泛地运用于生物传感技术领域。本文综述了荧光纳米生物传感器种类和特点,介绍了国内外近期在荧光纳米生物传感器及在生物检测方面的一些研究成果及进展,并作了分析比较。着重讨论了纳米粒子荧光生物传感器和光纤纳米荧光生物传感器的特性及其在生物分析中的应用。     

消失波生物传感器及其在DNA与免疫分析中的应用

消失波光纤生物传感器是近年来发展很快的一项的分析技术。它现在已成为分了生物学领域的热门技术。本文叙述消失波生物传感器的识别元件,换能装置以及检测研究系统的研究进展。着重讨论消失波技术在ＤＮＡ检测与免疫检测中的应用。并对这些技术的应用价值做出评价。     

无脊椎动物乙酰胆碱酯酶研究进展

乙酰胆碱酯酶(AChE)是生物体中一种十分重要的神经递质水解酶,也是有机磷和氨基甲酸酯类杀虫剂的作用靶标。AChE在不同生物中的性质显著不同,如编码基因个数、序列保守性、表达分布及生理功能等。作为杀虫剂的主要作用靶标之一,AChE不但可以通过单个点突变引起昆虫抗药性,还能够通过多个点突变联合作用、靶标表达量变化及基因复制等方式引起抗药性并且改变昆虫的适合度代价。本文主要从AChE的基因类型、分子进化、蛋白结构、生理功能、与昆虫的抗药性关系、同一物种中不同AChE的性质等6个方面对昆虫纲、蛛形纲和线虫等无脊椎动物AChE的研究进展作一综述。     

压电免疫传感器的研究进展

生物传感器是近年来发展起来的一种新技术,能实时检测到传感器表面的抗原抗体反应,它可促使免疫诊断方法向定量化、操作自动化方向发展,成为生物医学领域的研究热点之一.本文简要介绍了生物传感器的基本概念与压电晶体免疫传感器的基本原理、设计与构造,并对常见的压电石英晶体免疫传感器生物敏感膜的制备方法进行了综述.     

二硫化钼纳米材料在生物传感器中的应用

近年来纳米材料的不断引入，为生物传感技术提供了新的研究途径，大大提高了生物传感器的性能。其中，二硫化钼(MoS₂)纳米材料由于比表面积大、带隙可调、电子迁移率高等独特性质，在生物传感器中被广泛应用。本文首先介绍了基于MoS₂纳米材料的电化学、场效应晶体管、表面增强拉曼散射、比色、双模式生物传感器的基本原理、研究进展及性能对比，重点分析了MoS₂纳米复合材料的结构、组分等对传感器灵敏度、检测范围、检测限、特异性等性能的影响，总结了MoS₂生物传感器的优势并对其未来发展趋势进行了展望，为MoS₂生物传感器在生物检测领域的进一步应用以及未来研究方向提供了思路。     

Invertebrate acetylcholinesterases: Insights into their evolution and non-classical functions

Acetylcholinesterase (AChE) plays a pivotal role in synaptic transmission by hydrolyzing the neurotransmitter acetylcholine. In addition to the classical function of AChE in synaptic transmission, various non-classical functions have been elucidated. Unlike vertebrates possessing a single AChE gene (ace), invertebrates (nematodes, arachnids, and insects) have multiple ace loci, encoding diverse AChEs with a range of different functions. In the field of toxicology, AChE with synaptic function has long been exploited as the target of organophosphorus and cabarmate pesticides to control invertebrate pests for the past several decades. However, many aspects of the evolution and non-classical roles of invertebrate AChEs are still unclear. Although currently available information on invertebrate AChEs is fragmented, we reviewed the recent findings on their evolutionary status, molecular/biochemical properties, and deduced non-classical (non-neuronal) functions.     

Design of acetylcholinesterases for biosensor applications

In recent years, the use of acetylcholinesterases (AChEs) in biosensor technology has gained enormous attention, in particular with respect to insecticide detection. The principle of biosensors using AChE as a biological recognition element is based on the inhibition of the enzyme's natural catalytic activity by the agent that is to be detected. The advanced understanding of the structure-function-relationship of AChEs serves as the basis for developing enzyme variants, which, compared to the wild type, show an increased inhibition efficiency at low insecticide concentrations and thus a higher sensitivity. This review describes different expression systems that have been used for the production of recombinant AChE. In addition, approaches to purify recombinant AChEs to a degree that is suitable for analytical applications will be elucidated as well as the various attempts that have been undertaken to increase the sensitivity of AChE to specified organophosphates and carbamates using side-directed mutagenesis and employing the enzyme in different assay formats.     

Characterization of trimeric acetylcholinesterase from a legume plant, <Emphasis Type="Italic">Macroptilium atropurpureum</Emphasis> Urb.

We recently identified plant acetylcholinesterases (E.C.3.1.1.7; AChEs) homologous to the AChE purified from a monocotyledon, maize, that are distinct from the animal AChE family. In this study, we purified, cloned and characterized an AChE from a dicotyledon, siratro. The full-length cDNA of siratro AChE is 1,441 nucleotides, encoding a 382-residue protein that includes a signal peptide. This AChE is a disulfide-linked 125-kDa homotrimer consisting of 41–42 kDa subunits, in contrast to the maize AChE, which exists as a mixture of disulfide and non-covalently linked 88-kDa homodimers. The plant AChEs apparently consist of various quaternary structures, depending on the plant species, similar to the animal AChEs. We compared the enzymatic properties of the dimeric maize and trimeric siratro AChEs. Similar to electric eel AChE, both plant AChEs hydrolyzed acetylthiocholine (or acetylcholine) and propionylthiocholine (or propionylcholine), but not butyrylthiocholine (or butyrylcholine), and their specificity constant was highest against acetylcholine. There was no significant difference between the enzymatic properties of trimeric and dimeric AChEs, although two plant AChEs had low substrate turnover numbers compared with electric eel AChE. The two plant AChE activities were not inhibited by excess substrate concentrations. Thus, similar to some plant AChEs, siratro and maize AChEs showed enzymatic properties of both animal AChE and animal BChE. On the other hand, both siratro and maize AChEs exhibited low sensitivity to the AChE-specific inhibitor neostigmine bromide, dissimilar to other plant AChEs. These differences in enzymatic properties of plant AChEs may reflect the phylogenetic evolution of AChEs. Kosuke Yamamoto and Yoshie S. Momonoki contributed equally to this work.     

Comparison of oxime reactivation and aging of nerve agent-inhibited monkey and human acetylcholinesterases

Non-human primates are valuable animal models that are used for the evaluation of nerve agent toxicity as well as antidotes and results from animal experiments are extrapolated to humans. It has been demonstrated that the efficacy of an oxime primarily depends on its ability to reactivate nerve agent-inhibited acetylcholinesterase (AChE). If the in vitro oxime reactivation of nerve agent-inhibited animal AChE is similar to that of human AChE, it is likely that the results of an in vivo animal study will reliably extrapolate to humans. Therefore, the goal of this study was to compare the aging and reactivation of human and different monkey (Rhesus, Cynomolgus, and African Green) AChEs inhibited by GF, GD, and VR. The oximes examined include the traditional oxime 2-PAM, two H-oximes HI-6 and HLo-7, and the new candidate oxime MMB4. Results indicate that oxime reactivation of all three monkey AChEs was very similar to human AChE. The maximum difference in the second-order reactivation rate constant between human and three monkey AChEs or between AChEs from different monkey species was 5-fold. Aging rate constants of GF-, GD-, and VR-inhibited monkey AChEs were very similar to human AChE except for GF-inhibited monkey AChEs, which aged 2-3 times faster than the human enzyme. The results of this study suggest that all three monkey species are suitable animal models for nerve agent antidote evaluation since monkey AChEs possess similar biochemical/pharmacological properties to human AChE.     

Probing gorge dimensions of cholinesterases by freeze-frame click chemistry

Freeze-frame click chemistry is a proven approach for design in situ of high affinity ligands from bioorthogonal, reactive building blocks and macromolecular template targets. We recently described in situ design of femtomolar reversible inhibitors of fish and mammalian acetylcholinesterases (EC 3.1.1.7; AChEs) using several different libraries of acetylene and azide building blocks. Active center gorge geometries of those AChEs are rather similar and identical triazole inhibitors were detected in situ when incubating the same building block libraries in different AChEs. Drosophila melanogaster AChE crystal structure and other insect AChE homology models differ more in their overall 3D structure than other members of the cholinesterase family. The portion of the gorge proximal to the catalytic triad and choline binding site has a approximately 50% reduction in volume, and the gorge entrance at the peripheral anionic site (PAS) is more constricted than in the fish and mammalian AChEs. In this communication we describe rationale for using purified recombinant Drosophila AChE as a template for in situ reaction of tacrine and propidium based libraries of acetylene and azide building blocks. The structures of resulting triazole inhibitors synthesized in situ are expected to differ appreciably from the fish and mammalian AChEs. While the latter AChEs exclusively promote synthesis of syn-substituted triazoles, the best Drosophila AChE triazole inhibitors were always anti-substituted. The anti-regioisomer triazoles were by about one order of magnitude better inhibitors of Drosophila than mammalian and fish AChEs. Moreover, the preferred site of acetylene+azide reaction in insect AChE and the resulting triazole ring formation shifts from near the base of the gorge to closer to its rim due to substantial differences of the gorge geometry in Drosophila AChE. Thus, in addition to synthesizing high affinity, lead inhibitors in situ, freeze-frame, click chemistry has capacity to generate species-specific AChE ligands that conform to the determinants in the gorge.     

Selective and Irreversible Inhibitors of Aphid Acetylcholinesterases: Steps Toward Human-Safe Insecticides

Aphids, among the most destructive insects to world agriculture, are mainly controlled by organophosphate insecticides that disable the catalytic serine residue of acetylcholinesterase (AChE). Because these agents also affect vertebrate AChEs, they are toxic to non-target species including humans and birds. We previously reported that a cysteine residue (Cys), found at the AChE active site in aphids and other insects but not mammals, might serve as a target for insect-selective pesticides. However, aphids have two different AChEs (termed AP and AO), and only AP-AChE carries the unique Cys. The absence of the active-site Cys in AO-AChE might raise concerns about the utility of targeting that residue. Herein we report the development of a methanethiosulfonate-containing small molecule that, at 6.0 µM, irreversibly inhibits 99% of all AChE activity extracted from the greenbug aphid (Schizaphis graminum) without any measurable inhibition of the human AChE. Reactivation studies using β-mercaptoethanol confirm that the irreversible inhibition resulted from the conjugation of the inhibitor to the unique Cys. These results suggest that AO-AChE does not contribute significantly to the overall AChE activity in aphids, thus offering new insight into the relative functional importance of the two insect AChEs. More importantly, by demonstrating that the Cys-targeting inhibitor can abolish AChE activity in aphids, we can conclude that the unique Cys may be a viable target for species-selective agents to control aphids without causing human toxicity and resistance problems.     

Ace2, rather than ace1, is the major acetylcholinesterase in the silkworm, Bombyx mori

Abstract  Two acetylcholinesterase ( ace ) genes have been reported in many insect species. In pests such as Helicoverpa assulta and Plutella xylostellas , ace 1 gene encodes the predominant synaptic enzyme that is the main target of organophosphorus (OP) and carbamate pesticides. It has been reported that pesticide selection has an impact on the ace gene evolution. The domesticated silkworm, Bombyx mori , also has two ace genes. We studied ace gene expression and enzyme activities in silkworm as this has not faced pesticide selection over the past decades. The expression levels of two ace genes, Bm- ace 1 and Bm- ace 2, were estimated by quantitative real-time polymerase chain reaction. Bm- ace 2 was expressed more highly than Bm- ace 1 in all tested samples of different developmental stages or tissues, suggesting ace 2, rather than ace 1, is the major type of acetylcholinesterase (AChE) in Bombyx mori . This is inconsistent with the aforementioned lepidopterons agricultural pests, partly be due to the widespread use of pesticides that may induce high expression of the ace 1 gene in these pests. Besides high expression in the head, Bm- ace 1 also expresses highly in the silk glands and Bm- ace 2 is abundant in the germline, implying both ace genes may have potential non-hydrolytic roles in development. Furthermore, we found that the mRNA levels of two ace genes and their ratios ( ace 2/ ace 1) change day to day in the first and third instars. This challenges the conventional method of estimating enzymatic activity using crude extract as an enzyme solution, as it is a mixture of AChE1 and AChE2. An efficient and simple method for separating different AChEs is necessary for reliable toxicological analyses.     

An in vitro comparative study on the reactivation of nerve agent-inhibited guinea pig and human acetylcholinesterases by oximes

The reactivation of nerve agent-inhibited acetylcholinesterase (AChE) by oxime is the most important step in the treatment of nerve agent poisoning. Since the evaluation of nerve agent antidotes cannot be conducted in humans, results from animal experiments are extrapolated to humans. Guinea pig is one of the animal models that is frequently used for conducting nerve agent antidote evaluations. Several investigations have demonstrated that the efficacy of an oxime primarily depends on its ability to reactivate nerve agent-inhibited AChE. If the in vitro oxime reactivation of nerve agent-inhibited animal AChE is similar to that of human AChE, it is likely that the results of an in vivo animal study will reliably extrapolate to humans. Therefore, the goal of this study was to compare the reactivation of guinea pig and human AChEs inhibited by six different G and V type nerve agents. Reactivation kinetic studies with five mono- and bis-pyridinium oximes showed that oxime reactivation of nerve agent-inhibited human AChE in most cases was faster than guinea pig AChE. The most significant enhancement was observed in the reactivation of human AChE inhibited by nerve agents containing bulky side chains GF, GD, and VR, by H-series oximes HLo-7, HI-6, and ICD-585. In these cases, species-related differences observed between the two AChEs, based on the second-order reactivation rate constants, were 90- to over 400-fold. On the other hand, less than 3-fold differences were observed in the rates of aging of nerve agent-inhibited guinea pig and human AChEs. These results suggest that the remarkable species-related differences observed in the reactivation of nerve agent-inhibited guinea pig and human AChEs were not due to differences in the rates of aging. These results also suggest that guinea pig may not be an appropriate animal model for the in vivo evaluation of oxime therapy.     

Bovine brain acetylcholinesterase primary sequence involved in intersubunit disulfide linkages

Three distinct classes of membrane-bound acetylcholinesterases (AChEs) have been identified. A12 AChE is composed of 12 catalytic subunits that are linked to noncatalytic collagen-like subunits through intersubunit disulfide bonds. G2 AChE is localized in membranes by a glycoinositol phospholipid covalently linked to the C-terminal amino acid. Brain G4 AChE involves two catalytic subunits linked by a direct intersubunit disulfide bond while the other two are disulfide-linked to a membrane-binding 20-kDa noncatalytic subunit. Molecular cloning studies have so far failed to find evidence of more than one AChE gene in any organism although alternative splicing of torpedo AChE mRNA results in different C-terminal sequences for the A12 and G2 AChE forms. Support for a single bovine AChE gene is provided in this report by amino acid sequencing of the N-terminal domains from the G2 erythrocyte, G4 fetal serum, and G4 brain AChE. Comparison of the 38-amino acid sequences reveals virtually complete identity among the three AChE forms. Additional extensive identity between the fetal serum and brain AChEs was demonstrated by sequencing several brain AChE peptides isolated by high performance liquid chromatography after trypsin digestion of nitrocellulose blots of brain AChE catalytic subunits. Cysteines involved in intersubunit disulfide linkages in brain AChE were reduced selectively with dithiothreitol in the absence of denaturants and radioalkylated with iodoacetamide. The observed sequence of the major radiolabeled tryptic peptide was C*SDL, where C* was the radioalkylated cysteine residue. This sequence is precisely the same as that observed at the C terminus of fetal bovine serum AChE and shows close homology to the C-terminal sequence of torpedo A12 AChE. We conclude that the mammalian brain G4 AChEs utilize the same exon splicing pattern as the A12 AChEs and that factors other than the primary sequence of the AChE catalytic subunits dictate assembly with either the collagen-like or the 20-kDa noncatalytic subunits.     

Acetylcholinesterase mobility and stability at the neuromuscular junction of living mice

Acetylcholinesterase (AChE) is an enzyme that terminates acetylcholine neurotransmitter function at the synaptic cleft of cholinergic synapses. However, the mechanism by which AChE number and density are maintained at the synaptic cleft is poorly understood. In this work, we used fluorescence recovery after photobleaching, photo-unbinding, and quantitative fluorescence imaging to investigate the surface mobility and stability of AChE at the adult innervated neuromuscular junction of living mice. In wild-type synapses, we found that nonsynaptic (perisynaptic and extrasynaptic) AChEs are mobile and gradually recruited into synaptic sites and that most of the trapped AChEs come from the perijunctional pool. Selective labeling of a subset of synaptic AChEs within the synapse by using sequential unbinding and relabeling with different colors of streptavidin followed by time-lapse imaging showed that synaptic AChEs are nearly immobile. At neuromuscular junctions of mice deficient in alpha-dystrobrevin, a component of the dystrophin glycoprotein complex, we found that the density and distribution of synaptic AChEs are profoundly altered and that the loss rate of AChE significantly increased. These results demonstrate that nonsynaptic AChEs are mobile, whereas synaptic AChEs are more stable, and that alpha-dystrobrevin is important for controlling the density and stability of AChEs at neuromuscular synapses.