Selection of DNA aptamers using atomic force microscopy

Atomic force microscopy (AFM) can detect the adhesion or affinity force between a sample surface and cantilever, dynamically. This feature is useful as a method for the selection of aptamers that bind to their targets with very high affinity. Therefore, we propose the Systematic Evolution of Ligands by an EXponential enrichment (SELEX) method using AFM to obtain aptamers that have a strong affinity for target molecules. In this study, thrombin was chosen as the target molecule, and an ‘AFM-SELEX’ cycle was performed. As a result, selected cycles were completed with only three rounds, and many of the obtained aptamers had a higher affinity to thrombin than the conventional thrombin aptamer. Moreover, one type of obtained aptamer had a high affinity to thrombin as well as the anti-thrombin antibody. AFM-SELEX is, therefore, considered to be an available method for the selection of DNA aptamers that have a high affinity for their target molecules.     

Selection and characterization of DNA aptamers specific for Listeria species

Single-stranded (ss) DNA aptamers with binding affinity to Listeria spp. were selected using a whole-cell SELEX (Systematic Evolution of Ligands by EXponential enrichment) method. Listeria monocytogenes cells were grown at 37 °C and harvested at mid-log phase or early stationary phase to serve as the targets in SELEX. A total of 10 unique aptamer sequences were identified, six associated with log phase cells and four with stationary phase cells. Binding affinity of the aptamers was determined using flow cytometry and ranged from 10% to 44%. Four candidates having high binding affinity were further studied and found to show genus-specific binding affinity when screened against five different species within the Listeria genus. Using sequential binding assays combined with flow cytometry, it was determined that three of the aptamers (LM6-2, LM12-6, and LM12-13) bound to one apparent cell surface moiety, while a fourth aptamer (LM6-116) appeared to bind to a different cell surface region. This is the first study in which SELEX targeted bacterial cells at different growth phases. When used together, aptamers that bind to different cell surface moieties could increase the analytical sensitivity of future capture and detection assays.     

DNA aptamers as molecular probes for colorectal cancer study

Background

Understanding the molecular features of specific tumors can increase our knowledge about the mechanism(s) underlying disease development and progression. This is particularly significant for colorectal cancer, which is a heterogeneous complex of diseases developed in a sequential manner through a multistep carcinogenic process. As such, it is likely that tumors with similar characteristics might originate in the same manner and have a similar molecular behavior. Therefore, specific mapping of the molecular features can be potentially useful for both tumor classification and the development of appropriate therapeutic regimens. However, this can only be accomplished by developing high-affinity molecular probes with the ability to recognize specific markers associated with different tumors. Aptamers can most easily meet this challenge based on their target diversity, flexible manipulation and ease of development.

Methodology and Results

Using a method known as cell-based Systematic Evolution of Ligands by Exponential enrichment (cell-SELEX) and colorectal cancer cultured cell lines DLD-1 and HCT 116, we selected a panel of target-specific aptamers. Binding studies by flow cytometry and confocal microscopy showed that these aptamers have high affinity and selectivity. Our data further show that these aptamers neither recognize normal colon cells (cultured and fresh), nor do they recognize most other cancer cell lines tested.

Conclusion/Significance

The selected aptamers can identify specific biomarkers associated with colorectal cancers. We believe that these probes could be further developed for early disease detection, as well as prognostic markers, of colorectal cancers.     

Selection of DNA aptamers that bind to four organophosphorus pesticides

Single-stranded DNA (ssDNA) aptamers against four organophosphorus pesticides (phorate, profenofos, isocarbophos and omethoate) were simultaneously isolated from an immobilized random ssDNA library by systematic evolution of ligands by exponential enrichment (SELEX) technique. After 12 rounds of in vitro selection, five ssDNA aptamer candidates were selected and their binding affinities were identified by a novel method using a molecular beacon. Two of the five ssDNA sequences, SS2-55 and SS4-54, demonstrated higher affinities and specificities to the four organophosphorus pesticides. They were defined as broad-spectrum aptamers binding to four different targets and their simulated secondary structures showed highly distinct features with typical stem and loop structures. The dissociation constant of SS2-55 and SS4-54 binding to the four organophosphorus pesticides ranged from 0.8 to 2.5?μM. These aptamers offered application potential in the analysis and/or neutralization of the residues of the four organophosphorus pesticides.     

SELEX法筛选宫颈癌前病变核酸适配子

构建随机ssDNA文库,通过SELEX技术,以正常、炎性宫颈脱落细胞为反筛细胞,以上皮内低级别病变(CIN1)、上皮内高级别病变(CIN2、CIN3)和鳞状细胞癌脱落细胞为正筛细胞,经过12轮筛选特异性适配子高度富集得到宫颈癌前病变适配子库,经特异性、亲和力分析和细胞免疫荧光确立高特异性适配子CIN-Ap4可作为诊断宫颈癌前病变生物标志物,为宫颈癌前病变分子诊断奠定理论基础,提供新思路。利用Prime Premier 5.0设计构建了随机ssDNA文库并根据文库两端固定序列设计引物,对对称PCR和间接不对称PCR中的退火温度、循环数以及上、下游引物浓度比等条件进行优化,分析确定50μL反应体系中对称PCR的最佳反应条件为:最佳退火温度为49.5℃,最佳循环数为15个循环;间接不对称PCR的最佳反应条件为:50μL反应体系中上、下游引物浓度的最佳比例为80∶1,最佳循环数为35个循环。实验结果表明成功构建了寡核苷酸文库,在最适PCR条件下可获得理想的dsDNA和ssDNA,并具有良好的重复性,为顺利筛选适配子提供保证。     

Selection of DNA aptamers against polychlorinated biphenyls as potential biorecognition elements for environmental analysis

Polychlorinated biphenyls (PCBs) have been of major concerns for decades due to their potential toxicity to human health. To trace the PCBs efficiently and sensitively, many detection methods have been developed. Aptamers, a new class of diagnostic tools, are considered to be such additional candidates for detection of pollutants. In the current study, we report the DNA aptamers, isolated by FluMag-SELEX (a modified SELEX [systematic evolution of ligands by exponential enrichment] technology), that recognize PCBs with the dissociation constants (Kd values) down to the micromolar range. Using the selected aptamers, a highly sensitive aptamer-based fluorescent assay for detection of PCBs was established using gold nanoparticles, with a widely linear range from 0.1 to 100 ng/ml. Moreover, our aptamer-based gold nanoprobe displays specificity toward 3,3',4,4'-tetrachlorobiphenyl (PCB77) compared with a few common PCB77 structural analogs. These results open the possibility of using aptamers as biorecognition elements for easy and fast environmental monitoring.     

G-quadruplex DNA aptamers generated for systemin

Ligands specific to bioactive molecules play important roles in biomedical researches and applications, such as biological assay, diagnosis and therapy. Systemin is a peptide hormone firstly identified in plant. In this paper we report the selection of a group of DNA aptamers that can specifically bind to systemin. Through comparing the predicted secondary structures of all the aptamers, a hairpin structure with G-rich loop was determined to be the binding motif of these aptamers. The G-rich loop region of this binding motif was further characterized to fold into an antiparallel G-quadruplex by truncation-mutation assay and CD spectrum. The apparent equilibrium dissociation constant (K(d)) of one strong binding sequence (S-5-1) was measured to be 0.5 μM. The specificity assay shows that S-5-1 strongly bind to whole systemin, weakly bind to truncated or mutated systemin and does not bind to the scrambled peptide with the same amino acid composition as systemin. The high affinity and specificity make S-5-1 hold potentials to serve as a molecular ligand applied in detection, separation and functional investigation of systemin in plants.     

Development of drug-loaded protein nanoparticles displaying enzymatically-conjugated DNA aptamers for cancer cell targeting

Molecular Biology Reports - Modification of protein-based drug carriers with tumor-targeting properties is an important area of research in the field of anticancer drug delivery. To this end, we...     

Selection of DNA aptamers against insulin and construction of an aptameric enzyme subunit for insulin sensing

We selected DNA aptamers against insulin and developed an aptameric enzyme subunit (AES) for insulin sensing. The insulin-binding aptamers were identified from a single-strand DNA library which was expected to form various kinds of G-quartet structures. In vitro selection was carried out by means of aptamer blotting, which visualizes the oligonucleotides binding to the target protein at each round. After the 6th round of selection, insulin-binding aptamers were identified. These identified insulin-binding aptamers had a higher binding ability than the insulin-linked polymorphic region (ILPR) oligonucleotide, which can be called a "natural" insulin-binding DNA aptamer. The circular-dichroism (CD) spectrum measurement of the identified insulin-binding DNA aptamers indicated that the aptamers would fold into a G-quartet structure. We also developed an AES by connecting the best identified insulin-binding aptamer with the thrombin-inhibiting aptamer. Using this AES, we were able to detect insulin by measuring the thrombin enzymatic activity without bound/free separation.     

Selection and evolution of NTP-specific aptamers

ATP occupies a central position in biology, for it is both an elementary building block of RNA and the most widely used cofactor in all living organisms. For this reason, it has been a recurrent target for in vitro molecular evolution techniques. The exploration of ATP-binding motifs constitutes both an important step in investigating the plausibility of the ‘RNA world’ hypothesis and a central starting point for the development of new enzymes. To date, only two RNA motifs that bind ATP have been characterized. The first one is targeted to the adenosine moiety, while the second one recognizes the ‘Hoogsteen’ face of the base. To isolate aptamers that bind ATP in different orientations, we selected RNAs on an affinity resin that presents ATP in three different orientations. We obtained five new motifs that were characterized and subsequently submitted to a secondary selection protocol designed to isolate aptamers specific for cordycepin. Interestingly, all the ATP-binding motifs selected specifically recognize the sugar-phosphate backbone region of the nucleotides. Three of the aptamers show some selectivity for adenine derivatives, while the remainder recognize any of the four nucleotides with similar efficiency. The characteristics of these aptamers are discussed along with implications for in vitro molecular evolution.     

Single-stranded DNA aptamers specific for antibiotics tetracyclines

Tetracyclines (TCs) are a group of antibiotics comprising of a common tetracycline (TET) nucleus with variable X(1) and X(2) positions on 5 and 6 carbon atoms, such as oxytetracycline (OTC) and doxycycline (DOX). In this study, the tetracycline group specific (TGS) ssDNA aptamers were identified by modified SELEX method by employing tosylactivated magnetic beads (TMB) coated with OTC, TET, and DOX, respectively, as targets and counter targets. Twenty TGS-aptamers were selected, of which seven aptamers, designated as T7, T15, T19, T20, T22, T23, and T24, showed high affinity to the basic TET backbone (K(d)=63-483 nM). The specificity of these TGS-aptamers to structural analogues followed the order in which the TCs was employed during SELEX process (OTC>TET>DOX) except aptamer T22, which was highly specific to TET than OTC or DOX. Aptamers that were specific to one target molecule but fail to bind the other structurally related TCs were eliminated during counter selection steps. Three aptamers, T7, T19, and T23 contained palindromic consensus sequence motif GGTGTGG. The remaining TGS-aptamers showed many consensus sequences that are truncated forms of this palindrome forming mirror image or inverted sequences. For example, GTGG or its inverted form, GGTG motif was found in all TGS-aptamers. A consensus sequence motif TGTGCT or its truncated terminal T-residue was found in most TGS-aptamers, which is predicted to be essential for high affinity and group specificity. These TGS-aptamers have potential applications such as target drug delivery, and detection of TCs in pharmaceutical preparations and contaminated food products.     

Selection of DNA aptamers against epidermal growth factor receptor with high affinity and specificity

Epidermal growth factor receptor (EGFR/HER1/c-ErbB1), is overexpressed in many solid cancers, such as epidermoid carcinomas, malignant gliomas, etc. EGFR plays roles in proliferation, invasion, angiogenesis and metastasis of malignant cancer cells and is the ideal antigen for clinical applications in cancer detection, imaging and therapy. Aptamers, the output of the systematic evolution of ligands by exponential enrichment (SELEX), are DNA/RNA oligonucleotides which can bind protein and other substances with specificity. RNA aptamers are undesirable due to their instability and high cost of production. Conversely, DNA aptamers have aroused researcher’s attention because they are easily synthesized, stable, selective, have high binding affinity and are cost-effective to produce. In this study, we have successfully identified DNA aptamers with high binding affinity and selectivity to EGFR. The aptamer named TuTu22 with K_d 56 ± 7.3 nM was chosen from the identified DNA aptamers for further study. Flow cytometry analysis results indicated that the TuTu22 aptamer was able to specifically recognize a variety of cancer cells expressing EGFR but did not bind to the EGFR-negative cells. With all of the aforementioned advantages, the DNA aptamers reported here against cancer biomarker EGFR will facilitate the development of novel targeted cancer detection, imaging and therapy.     

Selection of aptamers for aflatoxin M1 and their characterization

In the present work, aptamers against aflatoxin M1 and aflatoxin B1 were generated and tested for creating proof of principle of recognition of aflatoxin M1 by generated aptamers. The aptamers were selected through the process referred as systematic evolution of ligands by exponential enrichment. A total of 41 different aptamer (36 aptamers for aflatoxin M1 and 5 for aflatoxin B1) sequences were obtained. The determination of dissociation constant (K_d) values revealed that aptamers generated against aflatoxin M1 exhibited K_d values in the range of 35–1515 nM. Selected aptamers were grouped on the basis of the presence of common motifs or G‐quadruplex. We find it interesting that one aptamer with no conserved motif or G‐quadruplex had lowest K_d value (K_d = 35 nM). This structural motif is very distinct from motifs present in other aptamers. The K_d values of selected aptamers for aflatoxin B1 were in the range of 96–221 nM. One aptamer from each group was further tested for its ability to be used in aptasensor. The aptamer recognized aflatoxin M1 as indicated by color change (red to purple or blue) of aptamer‐coated gold nanoparticles in the presence of 250–500 nM aflatoxin M1. The aptamers can be used in developing methods for detection/estimation/separation of aflatoxin or antidote for aflatoxin toxicity. Copyright © 2014 John Wiley & Sons, Ltd.     

Development of DNA aptamers for cytochemical detection of acetylcholine

This report describes a novel approach to the detection of acetylcholine using DNA aptamers. Aptamers were developed by eight rounds of acetylcholine affinity column chromatography and polymerase chain reaction (PCR) amplification. Sequences from rounds 5 and 8 were screened by colorimetric enzyme-based microtiter plate assays and found to bind acetylcholine and related compounds, but not unrelated compounds. One of the highest affinity aptamers, designated ACh 6R, was further tested in aptamer-peroxidase and aptamer-fluorescence staining protocols. Using Neuro-2a murine neuroblastoma cells induced to differentiate in the presence of 1 μM all-trans-retinoic acid for 5–7 d, ACh 6R detected cholinergic cells by both the peroxidase and fluorescence methods. Unrelated DNA aptamers did not stain the cells using either method. Fixation with cold 2% paraformaldehyde was compared to cold alkaline allyl alcohol plus glutaraldehyde for immobilization of acetylcholine in situ and appeared to enable detection of greater numbers of cholinergic cells, although differences in levels of differentiation may have been a factor as well. Acetylcholine generally appeared to be distributed throughout the differentiated Neuro-2a cell bodies. However, in some cells, punctate staining along neurite outgrowths and near the termini of cellular processes suggested detection of acetylcholine in discrete vesicles.     

Isolation and characterization of enantioselective DNA aptamers for ibuprofen

Single stranded DNA aptamers that can bind to ibuprofen, a widely used anti-inflammation drug, were selected from random DNA library of 10¹⁵ nucleotides by FluMag-SELEX process. Five different sequences were selected and their enantioselectivity and affinity were characterized. Three out of five aptamer candidates did not show any affinity to (S)-ibuprofen, but only to racemic form of ibuprofen, suggesting that they are (R)-ibuprofen specific aptamers. Another two aptamer candidates showed affinity to both racemic form and (S)-ibuprofen, which were considered as (S)-ibuprofen specific aptamers. The affinity of five ssDNA aptamers isolated was in a range of 1.5–5.2 μM. In addition, all of these five aptamers did not show any affinity to analogues of ibuprofen in its profen’s group (fenoprofen, flubiprofen, and naproxen) and the antibiotics of oxytetracycline, another control.