Rapid and efficient selection of yeast displaying a target protein using thermo-responsive magnetic nanoparticles

Magnetic separation provides a relatively quick and easy-to-use method for cell isolation and protein purification. We have developed a rapid and efficient procedure to isolate yeast cells displaying a target polypeptide, namely, the Staphylococcus aureus ZZ domain, which serves as s model for protein interactions and can bind immunoglobulin G (IgG). We optimized selection of ZZ-displaying yeast cells using thermoresponsive magnetic nanoparticles. A model library was prepared by mixing various proportions of target yeast displaying the ZZ domain with control cells. Target cells in the model library that bound to the ZZ-specific binding partner, biotinylated IgG, were selected with biotinylated thermoresponsive magnetic nanoparticles using the biotin-avidin sandwich system. We determined ZZ expression levels and optimized the concentrations of both magnetic nanoparticles and avidin for efficient selection of target cells. After optimization, we successfully enriched the target cell population 4700-fold in a single round of selection. Moreover, only two rounds of selection were required to enrich the target cell population from 0.001% to nearly 100%. Our results suggest that magnetic separation will be useful for efficient exploration of novel protein-protein interactions and rapid isolation of biomolecules with novel functions.     

Carboxyl-coated magnetic nanoparticles for mRNA isolation and extraction of supercoiled plasmid DNA

Carboxyl-coated magnetic nanoparticles (MNPs) were used to demonstrate dual functionality: isolation of messenger RNA (mRNA) from mammalian cells and extraction of the supercoiled (sc) form of plasmid DNA (pDNA) from agarose gel. These MNPs were attached with 5′-NH₂-tagged oligo-(dT)₂₅ primer and were used to isolate mRNA from breast cancer cells. The isolated mRNA was used for amplification of β-actin to confirm the compatibility. These MNPs were also used to extract the sc form of pDNA from agarose gel. The compatibility of the pDNA was demonstrated by restriction digestion. Both of these methodologies are simple, inexpensive (compared with existing kits), and efficient.     

Efficacy of magnetic capture in comparison with conventional DNA isolation in a survey of Toxoplasma gondii in wild house mice

Toxoplasma gondii is a zoonotic parasite with a world-wide distribution. House mice (Mus musculus) play an important role as a reservoir host in the parasite life cycle. However, their detection in mouse brain is limited because the host potentially harbours only a few tissue cysts. In order to improve the diagnosis, we tested a novel protocol for T. gondii detection in mice and compared this technique to a standard PCR-based protocol using a commercial kit for DNA isolation. Efficacy of magnetic capture for isolation of T. gondii DNA from whole host brains was tested in brain samples of laboratory mice spiked with 1 up to 10⁴ tachyzoites. Real-time PCR revealed that even 1–5 tachyzoites can be detected after magnetic capture. Also this method is suitable to quantify parasite numbers in mouse brains with more than 10 tachyzoite equivalents. To assess the two techniques in wild mice, we employed a dataset consisting of 243 individuals. The prevalence of T. gondii detected by magnetic capture and qPCR and by commercial isolation and PCR was 1.2% and 0%, respectively. The magnetic capture and quantitative PCR seems to be a highly sensitive and specific diagnostic method for both laboratory research and wild population surveys.     

A simple process for the isolation of epithelial cells from bacteria-contaminated samples using anchoring molecules

A simple and efficient tool to isolate epithelial cells from bacteria-contaminated samples has been developed using two different microparticles functionalized with chemical molecules. The epithelial cells could be captured simply by biocompatible anchors for membranes (BAM), consisting of poly(ethylene glycol) functionalized with oleyl-chain-conjugated NHS (N-hydroxysuccinimide) on glass microparticles, whereas bacteria were adsorbed on 3-aminopropyltrimethoxysilane (ATPS)-functionalized magnetic microparticles. In the case of samples highly contaminated with bacteria, epithelial cells were not isolated successfully by both of the single BAM- and antibody-functionalized microparticles. Therefore, serial isolation steps of these two different chemical functionalized microparticles were introduced. The concentration of bacteria was decreased dramatically by using APTS-functionalized magnetic particles prior to the isolation of epithelial cells by BAM microparticles. With these serial processes, successful isolation of epithelial cells was achieved from bacteria-contaminated epithelial samples. The applicability of this method was verified with bacteria-contaminated intestinal samples biopsied from a BALB/C mouse for primary cell cultivation.     

Detecting minimal traces of DNA using DNA covalently attached to superparamagnetic nanoparticles and direct PCR-ELISA

A single bond covalent immobilization of aminated DNA probes on magnetic particles suitable for selective molecular hybridization of traces of DNA samples has been developed. Commercial superparamagnetic nanoparticles containing amino groups were activated by coating with a hetero-functional polymer (aldehyde-aspartic-dextran). This new immobilization procedure provides many practical advantages: (a) DNA probes are immobilized far from the support surface preventing steric hindrances; (b) the surface of the nanoparticles cannot adsorb DNA ionically; (c) DNA probes are bound via a very strong covalent bond (a secondary amine) providing very stable immobilized probes (at 100 degrees C, or in 70% formamide, or 0.1N NaOH). Due to the extreme sensitivity of this purification procedure based on DNA hybridization, the detection of hybridized products could be coupled to a PCR-ELISA direct amplification of the DNA bond to the magnetic nanoparticles. As a model system, an aminated DNA probe specific for detecting Hepatitis C Virus cDNA was immobilized according to the optimised procedure described herein. Superparamagnetic nanoparticles containing the immobilized HCV probe were able to give a positive result after PCR-ELISA detection when hybridized with 1 mL of solution containing 10(-18) g/mL of HCV cDNA (two molecules of HCV cDNA). In addition, the detection of HCV cDNA was not impaired by the addition to the sample solution of 2.5 million-fold excess of non-complementary DNA. The experimental data supports the use of magnetic nanoparticles containing DNA probes immobilized by the procedure here described as a convenient and extremely sensitive procedure for purification/detection DNA/RNA from biological samples. The concentration/purification potential of the magnetic nanoparticles, its stability under a wide range of conditions, coupled to the possibility of using the particles directly in amplification by PCR greatly reinforces this methodology as a molecular diagnostic tool.     

Development of a multilayered polymeric DNA biosensor using radio frequency technology with gold and magnetic nanoparticles

This study utilized the radio frequency (RF) technology to develop a multilayered polymeric DNA sensor with the help of gold and magnetic nanoparticles. The flexible polymeric materials, poly (p-xylylene) (Parylene) and polyethylene naphtholate (PEN), were used as substrates to replace the conventional rigid substrates such as glass and silicon wafers. The multilayered polymeric RF biosensor, including the two polymer layers and two copper transmission structure layers, was developed to reduce the total sensor size and further enhance the sensitivity of the biochip in the RF DNA detection. Thioglycolic acid (TGA) was used on the surface of the proposed biochip to form a thiolate-modified sensing surface for DNA hybridization. Gold nanoparticles (AuNPs) and magnetic nanoparticles (MNPs) were used to immobilize on the surface of the biosensor to enhance overall detection sensitivity. In addition to gold nanoparticles, the magnetic nanoparticles has been demonstrated the applicability for RF DNA detection. The performance of the proposed biosensor was evaluated by the shift of the center frequency of the RF biosensor because the electromagnetic characteristic of the biosensors can be altered by the immobilized multilayer nanoparticles on the biosensor. The experimental results show that the detection limit of the DNA concentration can reach as low as 10 pM, and the largest shift of the center frequency with triple-layer AuNPs and MNPs can approach 0.9 and 0.7 GHz, respectively. Such the achievement implies that the developed biosensor can offer an alternative inexpensive, disposable, and highly sensitive option for application in biomedicine diagnostic systems because the price and size of each biochip can be effectively reduced by using fully polymeric materials and multilayer-detecting structures.     

Bacteria capture, lysate clearance, and plasmid DNA extraction using pH-sensitive multifunctional magnetic nanoparticles

A multifunctional magnetic nanoparticle (MNP)-assisted bioseparation method was developed to isolate plasmid DNA (pDNA) from Escherichia coli culture. Using the pH-sensitive carboxyl-modified magnetic nanoparticles, both cell capture and the subsequent removal of genomic DNA/protein complex after lysis can be achieved simply by magnetic separation. Furthermore, the yield and purity of pDNA extracted by MNPs are comparable to those obtained using organic solvents or commercial kits. This time- and cost-effective protocol does not require centrifugation or precipitation steps and has the potential for automated DNA extraction, especially within miniaturized lab chip applications.     

Methods for Detection of Anticarsia gemmatalis Nucleopolyhedrovirus DNA in Soil

Two methods, phenol-ether and magnetic capture-hybridization (MCH), were developed and compared with regard to their sensitivities and abilities to extract the DNA of the insect baculovirus Anticarsia gemmatalis nucleopolyhedrovirus (AgMNPV) from soil and to produce DNA amplifiable by PCR. Laboratory experiments were performed with 0.25 g of autoclaved soil inoculated with different viral concentrations to optimize both methods of baculovirus DNA extraction and to determine their sensitivities. Both procedures produced amplifiable DNA; however, the MCH method was 100-fold more sensitive than the phenol-ether procedure. The removal of PCR inhibitors from the soil appeared to be complete when MCH was used as the viral DNA isolation method, because undiluted aliquots of the DNA preparations could be amplified by PCR. The phenol-ether procedure probably did not completely remove PCR inhibitors from the soil, since PCR products were observed only when the AgMNPV DNA preparations were diluted 10- or 100-fold. AgMNPV DNA was detected in field-collected soil samples from 15 to 180 days after virus application when the MCH procedure to isolate DNA was coupled with PCR amplification of the polyhedrin region.     

Methods for detection of Anticarsia gemmatalis nucleopolyhedrovirus DNA in soil.

Two methods, phenol-ether and magnetic capture-hybridization (MCH), were developed and compared with regard to their sensitivities and abilities to extract the DNA of the insect baculovirus Anticarsia gemmatalis nucleopolyhedrovirus (AgMNPV) from soil and to produce DNA amplifiable by PCR. Laboratory experiments were performed with 0. 25 g of autoclaved soil inoculated with different viral concentrations to optimize both methods of baculovirus DNA extraction and to determine their sensitivities. Both procedures produced amplifiable DNA; however, the MCH method was 100-fold more sensitive than the phenol-ether procedure. The removal of PCR inhibitors from the soil appeared to be complete when MCH was used as the viral DNA isolation method, because undiluted aliquots of the DNA preparations could be amplified by PCR. The phenol-ether procedure probably did not completely remove PCR inhibitors from the soil, since PCR products were observed only when the AgMNPV DNA preparations were diluted 10- or 100-fold. AgMNPV DNA was detected in field-collected soil samples from 15 to 180 days after virus application when the MCH procedure to isolate DNA was coupled with PCR amplification of the polyhedrin region.     

Establishment of a semi-automated pathogen DNA isolation from whole blood and comparison with commercially available kits

Molecular methods for bacterial pathogen identification are gaining increased importance in routine clinical diagnostic laboratories. Achieving reliable results using DNA based technologies is strongly dependent on pre-analytical processes including isolation of target cells and their DNA of high quality and purity. In this study a fast and semi-automated method was established for bacterial DNA isolation from whole blood samples and compared to different commercially available kits: Looxster, MolYsis kit, SeptiFast DNA isolation method and standard EasyMAG protocol. The newly established, semi-automated method utilises the EasyMAG device combined with pre-processing steps comprising human cell lysis, centrifugation and bacterial pellet resuspension. Quality of DNA was assessed by a universal PCR targeting the 16S rRNA gene and subsequent microarray hybridisation. The DNA extractions were amplified using two different PCR-mastermixes, to allow comparison of a commercial mastermix with a guaranteed bacterial DNA free PCR mastermix. The modified semi-automated EasyMAG protocol and the Looxster kit gave the most sensitive results. After hybridisation a detection limit of 10¹ to 10² bacterial cells per mL whole blood was achieved depending on the isolation method and microbial species lysed. Human DNA present in the isolated DNA suspension did not interfere with PCR and did not lead to non-specific hybridisation events.     

Multiplex single nucleotide polymorphisms genotyping using solid-phase single base extension on magnetic nanoparticles

To fulfill the increasing need for large-scale genetic research, we have developed a new solid-phase single base extension (SBE) protocol on magnetic nanoparticles (MNPs) for multiplex SNP detection using adapter polymerase chain reaction (PCR) products as templates. Extension primers were covalently immobilized on the MNPs, and allele-specific extension took place along the stretch of target DNA for one-color ddNTP incorporation. The MNPs with fluorophores were spotted on a glass slide to fabricate a “bead array” to discriminate their genotypes. Eight SNP loci of three DNA samples were interrogated, and the experiment demonstrated that it is an efficient method for large-scale SNP genotyping.     

A novel strategy for analysis of gene homologues and segmental genome duplications

Transformation-associated recombination (TAR) cloning allows selective isolation of a desired chromosomal region or gene from complex genomes. The method exploits a high level of recombination between homologous DNA sequences during transformation in the yeast Saccharomyces cerevisiae. We investigated the effect of nonhomology on the efficiency of gene capture and found that up to 15% DNA divergence did not prevent efficient gene isolation. Such tolerance to DNA divergence greatly expands the potential applications of TAR cloning for comparative genomics. In this study, we were able to use the technique to isolate nonidentical chromosomal duplications and gene homologues.     

Real-time PCR to study the sequence specific magnetic purification of DNA

The performance of various molecular techniques using complex biological samples greatly depends on the efficient separation and purification of DNA targets. In recent years, magnetic separation technology making use of small magnetic beads, has gained immense popularity. Most of these methods rely on the non-specific adsorption of DNA/RNA. However, as presented here, when functionalizing the beads with complementary DNA probes, the target of interest can selectively be isolated. Such sequence specific purification was evaluated for short DNA targets by means of simple fluorescent measurements, resulting in purification efficiencies around 80%. Besides standard fluorescent techniques, a real-time PCR (qPCR) method was applied for monitoring the purification of longer DNA targets. This qPCR method was specifically optimized for directly quantifying the purification efficiency of low concentrated DNA targets bound to magnetic beads. Additionally, parameters possibly affecting the magnetic isolation, including the length of the used capture probe or the hybridization location, were investigated. Using optimized conditions in combination with qPCR, purification efficiencies between 60% and 80% were observed and this over a large concentration window. These data also show the power of a direct qPCR approach to monitor the magnetic isolation of DNA at very low concentrations.     

The efficient and specific isolation of the antibodies from human serum by thiophilic paramagnetic polymer nanospheres

A rapid and effective method to specifically isolate the antibodies from human serum was presented based on the fast magnetic separation and specific adsorption of the novel thiophilic magnetic polymer nanospheres, which were synthesized by using miniemulsion copolymerization. After the thiophilic heterocyclic ligands of 2‐mercaptonicotinic acid were first activated via divinyl sulfone, they were immobilized on the surface of these magnetic nanospheres, through which the strong specificity to immunoglobulin G was evidently expressed in the isolation of antibodies from human serum. The mild conditions used in the process, including the physiological pH range, low temperature, and low ion strength, were so favorable for keeping the biological activity of antibodies, which resulted in their bioactivity purity to exceed 99%. The efficient isolation, simplicity process, mild conditions, and the conventional equipments required make this technology so attractive to purify antibodies from human serum. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

A Magnetic Nanoparticle-Based Multiple-Gene Delivery System for Transfection of Porcine Kidney Cells

Superparamagnetic nanoparticles are promising candidates for gene delivery into mammalian somatic cells and may be useful for reproductive cloning using the somatic cell nuclear transfer technique. However, limited investigations of their potential applications in animal genetics and breeding, particularly multiple-gene delivery by magnetofection, have been performed. Here, we developed a stable, targetable and convenient system for delivering multiple genes into the nuclei of porcine somatic cells using magnetic Fe₃O₄ nanoparticles as gene carriers. After surface modification by polyethylenimine, the spherical magnetic Fe₃O₄ nanoparticles showed strong binding affinity for DNA plasmids expressing the genes encoding a green (DNA_GFP) or red (DNA_DsRed) fluorescent protein. At weight ratios of DNA_GFP or DNA_DsRed to magnetic nanoparticles lower than or equal to 10∶1 or 5∶1, respectively, the DNA molecules were completely bound by the magnetic nanoparticles. Atomic force microscopy analyses confirmed binding of the spherical magnetic nanoparticles to stretched DNA strands up to several hundred nanometers in length. As a result, stable and efficient co-expression of GFP and DsRed in porcine kidney PK-15 cells was achieved by magnetofection. The results presented here demonstrate the potential application of magnetic nanoparticles as an attractive delivery system for animal genetics and breeding studies.     

富集培养及高质量DNA提取有利于从土壤宏基因组中获取新卤醇脱卤酶基因

目的:宏基因组技术作为一种不依赖于微生物纯培养的新方法,在挖掘新基因方面具有极大的潜力。本研究旨在建立一种从土壤中高效获取卤醇脱卤酶新基因的策略。方法:通过对现有DNA提取方法进行改进,同时结合富集培养途径以提高土壤宏基因组DNA质量和特异性;在此基础上,应用T-Coffee及CDEHOP程序设计特异引物并对目的基因进行扩增,同时采用正交法设计优化扩增条件,以提高获得卤醇脱卤酶基因的效率。结果:应用改进法提取的DNA质量较改进前有大幅度提高,其D260nm/D280nm及D260nm/D230nm值均大于1.8,且可以不经纯化直接用于PCR和相关酶切实验;PCR扩增目标基因的特异性增强,其中用经富集培养后所得DNA为模板扩增目标基因的特异性最强,TA克隆测序阳性结果比例最高。结论:富集培养和高质量DNA的获得有助于基于宏基因组途径获取新基因。     

Enhancement of the efficiency of non-viral gene delivery by application of pulsed magnetic field

New approaches to increase the efficiency of non-viral gene delivery are still required. Here we report a simple approach that enhances gene delivery using permanent and pulsating magnetic fields. DNA plasmids and novel DNA fragments (PCR products) containing sequence encoding for green fluorescent protein were coupled to polyethylenimine coated superparamagnetic nanoparticles (SPIONs). The complexes were added to cells that were subsequently exposed to permanent and pulsating magnetic fields. Presence of these magnetic fields significantly increased the transfection efficiency 40 times more than in cells not exposed to the magnetic field. The transfection efficiency was highest when the nanoparticles were sedimented on the permanent magnet before the application of the pulsating field, both for small (50 nm) and large (200–250 nm) nanoparticles. The highly efficient gene transfer already within 5 min shows that this technique is a powerful tool for future in vivo studies, where rapid gene delivery is required before systemic clearance or filtration of the gene vectors occurs.     

Isolation of Myeloid Dendritic Cells and Epithelial Cells from Human Thymus

In this protocol we provide a method to isolate dendritic cells (DC) and epithelial cells (TEC) from the human thymus. DC and TEC are the major antigen presenting cell (APC) types found in a normal thymus and it is well established that they play distinct roles during thymic selection. These cells are localized in distinct microenvironments in the thymus and each APC type makes up only a minor population of cells. To further understand the biology of these cell types, characterization of these cell populations is highly desirable but due to their low frequency, isolation of any of these cell types requires an efficient and reproducible procedure. This protocol details a method to obtain cells suitable for characterization of diverse cellular properties. Thymic tissue is mechanically disrupted and after different steps of enzymatic digestion, the resulting cell suspension is enriched using a Percoll density centrifugation step. For isolation of myeloid DC (CD11c⁺), cells from the low-density fraction (LDF) are immunoselected by magnetic cell sorting. Enrichment of TEC populations (mTEC, cTEC) is achieved by depletion of hematopoietic (CD45^hi) cells from the low-density Percoll cell fraction allowing their subsequent isolation via fluorescence activated cell sorting (FACS) using specific cell markers. The isolated cells can be used for different downstream applications.     

Mice Genotyping Using Buccal Swab Samples: An Improved Method

Routine methods used to genotype mice involve isolation of DNA from partially amputated neonate’s tail, toe, or ear. The inevitable drawbacks of such techniques are the animal’s pain response and the increased time and funds required for DNA purification. In order to implement a noninvasive and simple protocol for mouse DNA isolation, we have improved the method based on samples collected by swabbing of the inner cheek. Combining alkaline and temperature lysis, it was possible to isolate a DNA solution ready for PCR in less than an hour. Testing the method on three different mouse lines showed that it is highly efficient, the volume of the PCR samples could be reduced to 25 μl, and fragments up to 800 bp were successfully amplified. This protocol reduces animal discomfort, shortens the time for DNA isolation, and enables amplification of larger DNA fragments with optimal success rate, thus considerably facilitating large-scale genotyping of different mouse lines.     

用普通琼脂糖代替低熔点胶回收DNA片段

为了建立一种直接从普通琼脂糖凝胶中回收DNA片段的简便实用的方法,采用聚合酶链式反应扩增人P53基因外显子7、8和其间的内含子7序列,用普通琼脂糖凝胶电泳,直接从凝胶中切下产物带,用加热熔化法回收DNA;紫外比色法测定回收率;用测序法鉴定回收产物质量。并用QIAquick Spin纯化柱对照。结果表明,本法回收的产物质量明显优于用QIAquick Spin柱回收,本法回收的产物用于测序效果极佳,回收率达80％,用QIAquick Spin柱回收率不到20％,差异非常显著（P<0.01）。证明这种方法回收PCR产物质量可靠,能代替低熔点胶回收DNA,有较大的实用价值。 Abstract： In order to find a simple and efficient method to isolate single or double?strand DNA fragment amplified by polymerase chain reaction (PCR),we used PCR method to amplify exon 7,exon 8 and intron 7 of human P53 gene, electrophoresis to identify products,fusion and phenol-chlorofom extraction (FPC) to isolate specific DNA from agarose gel,ultraviolet colorimetry to deteminate collected rate,and direct sequencing to identify the quality of recollected DNA. A control test was also made by using QIAquick Spin Colum．The results showed that the quality of PCR products recollected by using FPC method was very good．When the recollected DNA was used in sequencing,no matter what was single or double-strand DNA,the sequence data was clear and even,with low noise．The recollected rate of using FPC,which was over 80 per cent, was higher than that of using colum (lessthan 20 per cent), there were statistical significances (P<0.01).In the control test, it had a little non-specific DNA in the collected products,and the sequencing experiment of using double-strand products was failure．All above mentioned suggested that general agarose gelis efficient in place of low melting-temperature for isolating DNA fragment．