肉类掺假检测技术研究进展

肉类掺假现象严重威胁公共卫生安全。快速、准确、可靠的动物源性成分检测技术是有效监管与检测肉类掺假的关键。总结了常见的掺假形式,并对物理技术、光谱技术、免疫学技术、DNA分析等检测方法进行了全面的总结归纳和比较分析,尤其是对当前热门的DNA分析方法,详细阐述了常规PCR、实时荧光定量PCR、数字PCR和等温扩增PCR这4种主要分子检测技术的优缺点和应用情况,旨在为未来动物源性检测技术的发展指明方向。     

饲料中狐狸、水貂、貉子和狗源性的五重实时荧光PCR检测方法的建立

为了快速鉴别饲料中的狐狸、水貂、貉子和狗源性成分,根据线粒体16S r DNA种间保守序列,设计合成针对狐狸、水貂、貉子和狗的特异性引物和探针,通过对荧光PCR反应体系和反应条件的优化筛选,建立了多重实时荧光PCR方法,在同一PCR反应体系中可以同时完成4种动物源性成分检测。通过对15种其他物种的源性成分的检测,结果表明所设计的引物和探针具有很好的物种特异性,且灵敏度高,狐狸、水貂、貉子和狗的DNA检出限为0.01ng。对40份样品检测,其中5份检测出貉子、狐狸和水貂源性成分。结果表明,该方法可以有效地鉴别出饲料中狐狸、水貂、貉子和狗源性成分,同时适用于相关动物产品中。     

Taqman多重实时荧光PCR同步定量检测6种动物源性成分方法的建立

旨在建立一种可同时检测猪、牛、羊、鸡、鸭、鹅6种动物源性成分的六重实时荧光定量PCR方法。根据猪、牛、羊、鸡、鸭、鹅细胞核基因组保守序列,参照序列比对结果选择差异位点设计6对特异性引物和6条以不同荧光素标记的Taqman探针。通过对PCR反应体系和反应条件的优化筛选,建立能同步定量检测猪、牛、羊、鸡、鸭、鹅源性成分的六重实时荧光PCR方法。应用此方法分别对18种不同源性动物DNA和200份不同来源样品进行猪、牛、羊、鸡、鸭、鹅源性成分检测,结果表明,所建立的六重实时荧光PCR方法灵敏度高,对六种动物的最低核酸检测量分别为0.049ng、0.048ng、0.085ng、0.13ng、0.162ng、0.074ng(50μl体系);特异性强,对狗、兔、鼠、驴、马、骆驼等其他12种动物无特异性扩增;200份样品的检测结果表明六重qPCR检测方法敏感,同一反应体系下实现一次对6种动物快速定量检测,耗时短、效率高、适用性广,可用于肉品、奶品、皮毛和饲料等动物产品猪、牛、羊、鸡、鸭、鹅源性成分单一或混合物种的鉴别诊断。     

双重实时荧光PCR定量检测动物产品中牛源性成分

旨在建立一种定量检测动物产品中牛源性成分含量的双重实时荧光PCR方法。以牛卫星IV DNA为检测靶基因,以肌肉生长抑制素基因作为内对照合成引物探针,采用基于TaqMan的双重实时荧光PCR技术对已知牛肉添加比例的冻干混合肉粉标准品进行检测并建立线性模型,并应用模拟样品和送检样品进行了验证检测。结果显示,该方法可检出牛源成分含量为0.1%的冻干肉粉,不与其他种动物组织发生交叉反应,重复性试验的相对标准偏差小于5%,方法的扩增效率为93.6%。该方法适用于肉品中牛源性成分的定量检测,可用于测定市场上动物产品中的牛源性成分含量。     

多重实时荧光PCR检测牛、山羊和绵羊源性成分

根据牛、山羊和绵羊线粒体细胞色素b基因序列, 设计特异性引物和以不同荧光素标记的Taqman探针。通过对PCR反应体系和反应条件的优化筛选, 建立能同时鉴别牛、山羊和绵羊源性成分的多重实时荧光PCR方法。采用本文方法与国标GB/T 20190-2006方法分别对17种不同源性动物DNA和200份不同来源样品DNA进行牛羊源性成分检测, 数据显示两者检测结果符合率达100%, 特异性相当。与国标方法相比, 本试验方法不需电泳、酶切和测序, 即可在一个PCR反应中同时鉴别检测牛、山羊和绵羊3种源性成分, 检测效率提高近3倍; 灵敏度更高, 比国标方法灵敏10倍; 适用性更广, 除了饲料, 还适用于肉品、奶品、生皮和动物油脂等动物产品的牛羊源性成分检测。     

四重PCR 反应体系的建立及在牛肉掺假检测中的应用

目的:建立马、牛、猪、鸭肉四重聚合酶链式反应(PCR)反应体系,为牛肉掺假检测提供参考。方法:选取马、牛、猪、鸭肉阳性样本,根据线粒体基因组中细胞色素b(cytochrome b)序列,设计多重PCR引物,同时对马、牛、猪、鸭肉进行PCR及电泳检测,建立四重PCR反应体系,并运用该体系对市场40份牛肉制品进行检测。结果:引物比例为马:牛:猪:鸭=1:1:2:1时,46℃退火温度下反应35个循环,四重PCR效果较好;建立四重PCR反应体系,四重PCR条带清晰且亮度较为一致,几乎没有二聚体产生,扩增灵敏度高。根据样品检测结果,烤牛肉串、牛肉丸的掺假率较高,分别为36.4%、75%,牛排未检出除牛肉外的三种动物源成分,但不排除有其他动物源成分的掺入。结论:四重PCR反应体系可用于牛肉掺假检测。     

肉类及肉制品中动物源性成分鉴别方法研究进展

肉类掺假问题直接影响着人类健康、公共卫生安全以及社会稳定等方面,成为当今食品安全热点话题之一,因此,高效、精确的肉类及肉制品中动物源性成分的检测鉴定势在必行。基于此,主要介绍了对于动物源性成分检测及鉴别的不同研究方法,分析了利弊,并对后续肉类及肉制品中动物源性成分的鉴别方法的研发方向进行了展望,以期为此领域提供资料性参考。     

Taqman多重实时荧光定量PCR检测裸鼠肿瘤转移模型中肿瘤转移率方法的建立

目的:建立基于多重荧光定量PCR技术的动物体内恶性肿瘤转移模型中肿瘤转移率高效检测的方法。方法:以人和小鼠的β2m基因为目标,设计相应的引物和Taqman探针;分别抽提人涎腺腺样囊性癌ACC细胞和小鼠Sp2/0细胞的基因组DNA作为模板,建立两物种双重荧光定量PCR检测方法,且分别以人和鼠定量基因检测为参照考察双重荧光定量PCR方法的特异性、灵敏性和精确性,并与传统转移灶称重计算肿瘤转移率的方法进行比较。结果:双重Taqman实时荧光定量PCR检测方法具有很好的特异性和较高的灵敏度(0.006ng/μl DNA),重复性较好(批间平均CV=0.036),有较强稳定性,比传统称重法更高效,更准确。结论:双重荧光定量PCR能够在同一反应体系下同时对动物组织中人肿瘤转移灶和周围组织进行快速准确的定量检测,计算出肿瘤转移率,具有经济、快速、特异性强等优点,在肿瘤动物模型肿瘤转移率检测方面具有很高的应用价值。     

运用基因芯片技术检测牛、山羊、猪和鸡源性成分

本研究通过对脊椎动物分子标记基因进行序列分析,最终选择线粒体DNA(mtDNA)16S rRNA基因为目标基因,利用一对通用引物,在该引物扩增区间设计了4条特异性基因芯片检测探针及2条质控探针用于对牛、山羊、猪、鸡等4种动物源性成分进行检测。通过对PCR扩增体系及杂交体系的优化,该检测方法能实现对上述4种动物源性成分同时进行快速、准确地检测,具有很好的特异性,灵敏度均达到1pg,最终建立了这4种动物源性基因芯片检测方法。该基因芯片检测技术将为我国进出口饲料中的动物源性成分的鉴别提供新的检测方法和技术支持。     

SYBR Green实时荧光定量PCR快速检测口腔幽门螺杆菌

目的建立一种快速、灵敏、特异的鉴定幽门螺杆菌实时荧光定量PCR方法。方法利用SYBR Green实时荧光定量PCR反应体系对口腔幽门螺杆菌进行检测。鉴定结果与临床常规鉴定方法相比较,评价其敏感度、特异度及重复性。结果通过48例样品的检测,结果显示实时荧光定量PCR法检测标本的鉴定结果与常规PCR鉴定方法的结果对比,特异度为100%,敏感度为100%;最小能检测到102个拷贝数的重组质粒;批内重复试验和批间重复试验结果均与常规鉴定方法结果相符。结论实时荧光定量PCR法鉴定口腔幽门螺杆菌,特异度和敏感度高,重复性好,且快速、简便。该方法有望成为检测口腔幽门螺杆菌感染的一种快速有效的方法。     

普通牛及其近缘种特异性序列筛选及环介导等温扩增检测方法

近年来,肉制品掺假事件频频发生,亟需建立快速、可靠的肉制品动物源性成分检测方法,保障肉类食品安全。与常规PCR等检测方法相比,环介导等温扩增（loop-mediated isothermal amplification,LAMP）方法具有高特异性、高灵敏度、反应快、易操作等优势。基于此,利用生物信息算法筛选普通牛及其近缘种（牦牛、水牛、美洲野牛）的全基因组序列,以获得种间相似性序列,进而建立并优化可用于检测普通牛及其近缘种成分的特异性LAMP方法。最终优化后的LAMP反应体系为：10 μmol·L-1外引物F3和B3各0.25 μL,10 μmol·L-1内引物FIP和BIP各2 μL,2 mmol·L-1 dNTP 2.5 μL,25 mmol·L-1 MgSO4 4 μL,5 mol·L-1 甜菜碱 3.5 μL,8.0 U·μL-1 Bst DNA 聚合酶 1 μL,10×ThermoPol Buffer 2.5 μL,DNA模板2 μL,加双蒸水至25 μL;LAMP反应条件为：65 ℃恒温扩增1 h,80 ℃ 10 min。在扩增产物中加入SYBR GreenⅠ荧光染料后,检测结果可用肉眼直接观察。优化后的LAMP方法在1 h内能特异性地检测出普通牛、牦牛、水牛及美洲野牛成分,检测灵敏度达到0.020 ng·μL-1,且可特异性地检测出市售肉制品中含有牛肉成分的样品。研究所建立的LAMP方法具有高特异性、高灵敏度、反应快速、操作简便和无需精密仪器等特点,可应用于肉制品中普通牛及其近缘种成分的实际检测,为我国肉类食品安全提供了有力保障。     

Antisense PCR: A simple and robust method for performing nested single-tube PCR

To overcome the disadvantages of two-round nested PCR, we developed a simple and robust closed single-tube nested PCR method (antisense PCR). The method uses antisense oligonucleotides that carry a 5′ tag and that can potentially hybridize to the 3′ ends of the outer primers, depending on the annealing temperature. During initial cycles, which are performed at a high annealing temperature, the antisense oligonucleotides do not hybridize and amplification is directed by the outer primers. During later cycles, for which the annealing temperature is decreased, the outer primers hybridize to the antisense oligonucleotides, extend to produce sequences that are mismatched to the amplicon templates, and consequently become inactivated, whereas the inner primers hybridize to the amplicon templates and continue amplification. Antisense quantitative PCR (qPCR) was compared with one-round qPCR for real-time amplification of four PCR targets (BCR, APC, N-RAS, and a rearranged IGH gene). It had equal amplification efficiency but produced much less nonspecific amplification. Antisense PCR enables both endpoint detection and real-time quantification. It can substitute for two-round nested PCRs but may also be applicable to instances of one-round PCR in which nonspecificity is a problem.     

Anchored multiplex amplification on a microelectronic chip array

We have developed a method for anchored amplification on a microchip array that allows amplification and detection of multiple targets in an open format. Electronic anchoring of sets of amplification primers in distinct areas on the microchip permitted primer-primer interactions to be reduced and distinct zones of amplification created, thereby increasing the efficiency of the multiplex amplification reactions. We found strand displacement amplification (SDA) to be ideal for use in our microelectronic chip system because of the isothermal nature of the assay, which provides a rapid amplification system readily compatible with simple instrumentation. Anchored SDA supported multiplex DNA or RNA amplification without decreases in amplification efficiency. This microelectronic chip-based amplification system allows multiplexed amplification and detection to be performed on the same platform, streamlining development of any nucleic acid-based assay.     

基于数字PCR的不同品种鸭组织中线粒体与核DNA拷贝数差异研究

肉和肉制品是人类生活的重要营养来源,但近年来肉制品中发生的掺假使假事件屡见不鲜,使得肉品的质量安全问题已经成为全世界关注的热点话题。以核酸为目标的动物源鉴定是当前普遍使用的方法。在核酸检测中,常用线粒体基因或核基因作为靶标,缺乏统一标准。以绍兴鸭和北京鸭等不同品种及生鲜组织(鸭血、鸭胸肉、鸭肝、鸭皮、鸭心和鸭腿肉)为实验材料,提取DNA后利用微滴式数字PCR开展线粒体和核DNA拷贝数的比较研究,以两者拷贝数及其比值的变异系数为判定依据。结果显示,核DNA的拷贝数在不同品种鸭组织间相对稳定,且变异系数小于线粒体DNA,表明核DNA是开展鸭肉制品掺假定量检测的最适DNA来源。鸭腿肉中线粒体/核DNA拷贝数比值的变异系数最小,表明线粒体DNA作为靶基因的鸭肉掺假比例定量检测时,鸭腿肉来源的肉制品是最佳选择。     

Micro Flow-Through Thermocycler with Simple Meandering Channel with Symmetric Temperature Zones for Disposable PCR-Devices in Microscope Slide Format

Chip-based flow-through PCR implements the PCR as a continuous process for nucleic acid analytics. The sample is transported in a winding channel through temperature zones required for denaturation, annealing and extension. Main fields of application are the monitoring of continuous processes for rapid identification of contaminants and quality control as well as high throughput screening of cells or microorganisms. A modular arrangement with five heating zones for flow-through PCR is discussed and evaluated. The special heater arrangement allows the implementation of up to 40 cycles on the footprint of a microscope slide, which is placed on top ofa 5 zones heating plate. Liquid/liquid two phase flow of PCR reaction mixture and mineral oil have been applied to create a segmented flow process scheme. In that way, the developed system may provide flow-through PCR as a unit operation for the droplet based microfluidics platform. The single use of disposable devices is commonly preferred due to the sensitivity of the PCR process to contaminations. All-glass microfluidic chips and disposable chip devices, made from polycarbonate as a replication with identically geometry, have been fabricated and tested. For the first time, microchannel geometries with nearly circular profile developed by all-glass technology have been transferred to mass fabrication by injection compression molding. Both devices have been successfully applied for the detection of the tumor suppressor gene p53. Although product yield and selectivity of the amplification process do not depend on the chip material, a well defined, reliable segmented flow regime could only be realized in the all-glass chip.     

基于特异性PCR和荧光检测技术快速鉴定艾纳香

为建立快速准确的艾纳香分子鉴定方法。采取筛选艾纳香及其混伪品基因组DNA的提取方法,针对艾纳香特异性位点设计引物,优化PCR扩增条件,荧光检测扩增产物。结果表明碱裂解法更适于艾纳香基因组DNA的提取;叶绿体基因（tDNA）特异引物能特异性扩增艾纳香DNA,其扩增产物荧光检测呈绿色,混伪品无反应发生。试验结果显示该法简化了分子鉴定过程,省时节力,且结果准确可靠,可作为艾纳香植物和药材的鉴定方法。     

Detection of Salmonella enterica serovar Typhi (S. Typhi) by selective amplification of invA, viaB, fliC-d and prt genes by polymerase chain reaction in mutiplex format

AIMS: Development of a PCR assay that can target multiple genes for rapid detection of Salmonella enterica serovar Typhi (S. Typhi) from water and food samples. METHODS AND RESULTS: PCR primers for invasion, O, H and Vi antigen genes, invA, prt, fliC-d and viaB were designed and used for the rapid detection of S. Typhi by multiplex PCR. Internal amplification control, which co-amplified with prt primers, was also included in the assay. The results showed that all cultures of Salmonella were accurately identified by the assay with no nonspecific amplification in other cultures. The assay had 100% detection probability when a cell suspension of 10(4) CFU ml(-1) (500 CFU per reaction) was used. Salmonella Typhi bacteria were artificially inoculated in the water and food (milk and meat rinse) samples and detected by mPCR after overnight pre-enrichment in buffered peptone water. No Salmonella bacteria could be detected from water samples collected from the field by mPCR or standard culture method. CONCLUSIONS: The developed mPCR assay provides specific detection of S. Typhi. SIGNIFICANCE AND IMPACT OF THE STUDY: Rapid methods for detection of S. Typhi from complex environmental matrices are almost nonexistent. The mPCR assay reported in this study can be useful to identify S. Typhi bacteria in field environmental samples.     

Miniature RT–PCR system for diagnosis of RNA-based viruses

This paper presents an innovative portable chip-based RT–PCR system for amplification of specific nucleic acid and detection of RNA-based viruses. The miniature RT–PCR chip is fabricated using MEMS (Micro-electro-mechanical-system) techniques, and comprises a micro temperature control module and a PDMS (polydimethylsiloxane)-based microfluidic control module. The heating and sensing elements of temperature control module are both made of platinum and are located within the reaction chambers in order to generate a rapid and uniform thermal cycling. The microfluidic control module is capable of automating testing process with minimum human intervention. In this paper, the proposed miniature RT–PCR system is used to amplify and detect two RNA-based viruses, namely dengue virus type-2 and enterovirus 71 (EV 71). The experimental data confirm the ability of the system to perform a two-step RT–PCR process. The developed miniature system provides a crucial tool for the diagnosis of RNA-based viruses.     

The use of capillary electrophoresis for DNA polymorphism analysis

Capillary electrophoresis has advanced enormously over the last 10 yr as a tool for DNA sequencing, driven by the human and other major genome projects and by the need for rapid electrophoresis-based DNA diagnostic tests. The common need of these analyses is a platform providing very high throughput, high-quality data, and low process costs. These demands have led to capillary electrophoresis machines with multiple capillaries providing highly parallel analyses, to new electrophoresis matrices, to highly sensitive spectrofluorometers, and to brighter, spectrally distinct fluorescent dyes with which to label DNA. Capillary devices have also been engineered onto microchip formats, on which both the amount of sample required for analysis and the speed of analysis are increased by an order of magnitude. This review examines the advances made in capillary and chip-based microdevices and in the different DNA-based assays developed for mutation detection and genotype analysis using capillary electrophoresis. The automation of attendant processes such as for DNA sample preparation, PCR, and analyte purification are also reviewed. Together, these technological developments provide the throughput demanded by the large genome-sequencing projects.